Considering Environmental Impact of Material Choices

Considering Environmental Impact of Material Choices

Importance of Proper Alignment During Installation

When considering the environmental impact of material choices for garage doors, it is essential to delve into the characteristics and implications of commonly used materials such as steel, wood, aluminum, and fiberglass. Each of these materials offers distinct advantages and challenges in terms of sustainability, energy efficiency, and ecological footprint.


Steel is a popular choice for garage doors due to its durability and strength. It is highly recyclable, which can mitigate some environmental concerns associated with its production. The process of manufacturing steel involves significant energy consumption and greenhouse gas emissions. However, modern advancements in recycling techniques have made it possible to produce steel with a reduced carbon footprint. Opting for recycled steel can further enhance its environmental credentials by minimizing natural resource depletion and waste.


Track alignment is crucial for smooth door operation same day garage door repair Sears.

Wooden garage doors are often revered for their aesthetic appeal and natural insulation properties. When sourced responsibly from sustainably managed forests or reclaimed sources, wood can be an environmentally friendly option. It is biodegradable at the end of its life cycle, reducing landfill impact compared to non-biodegradable materials. Nevertheless, the environmental impact of wooden doors heavily depends on forest management practices; unsustainable logging can lead to deforestation and biodiversity loss. Consumers aiming for greener choices should seek certifications like FSC (Forest Stewardship Council) ensuring that wood products come from responsibly managed forests.


Aluminum garage doors are lightweight yet robust, making them a favored choice where weight considerations are crucial. Like steel, aluminum boasts a high recyclability rate-approximately 75% of all aluminum ever produced is still in use today due to effective recycling processes. This attribute significantly lowers the material's long-term environmental impact by conserving resources and energy spent on new production. The initial extraction process of bauxite ore required for aluminum production does pose substantial ecological challenges including habitat destruction; therefore, prioritizing recycled aluminum is pivotal for minimizing harm.


Fiberglass garage doors provide excellent durability while being resistant to dents and corrosion-a valuable trait in regions with harsh weather conditions. Although fiberglass itself is not biodegradable, advances in manufacturing processes aim at reducing emissions during production stages. Fiberglass' thermal properties offer good insulation capabilities which contribute positively towards energy efficiency goals by reducing heating or cooling demands inside garages.


In conclusion, selecting environmentally responsible materials for garage doors necessitates a comprehensive understanding of each option's lifecycle impacts-from raw material extraction through manufacturing to end-of-life disposal or recycling potentialities. By choosing recycled metals like steel or aluminum when feasible alongside sustainably sourced wood options-and remaining aware of technological improvements within fiberglass industry-consumers can make informed decisions that align both functional needs with ecological responsibilities thereby contributing positively towards sustainable living environments overall.

Role of Quality Materials in Preventing Malfunctions —

In our modern era, the pressing need to curtail environmental degradation has thrust the spotlight onto material choices in construction and manufacturing. The selection of materials such as steel and aluminum for doors, while often dictated by factors like durability, cost, and aesthetic appeal, must also be critically evaluated for their environmental impact. As we delve into assessing the ecological footprint of these materials, it becomes clear that both have distinct advantages and challenges.


Steel doors are renowned for their strength and longevity. From a lifecycle perspective, steel is highly recyclable; in fact, it is one of the most recycled materials globally. This recyclability significantly mitigates its environmental impact because reusing existing steel reduces the need for virgin material extraction-a process notorious for its high energy consumption and carbon emissions. However, steel production remains energy-intensive due to processes such as smelting and refining iron ore. Additionally, the mining activities required can lead to habitat destruction and pollution.


On the other hand, aluminum doors offer a different set of considerations. Aluminum is lightweight yet strong, which makes it an attractive choice for many architectural applications. Like steel, aluminum boasts impressive recyclability rates; nearly 75% of all aluminum ever produced is still in use today thanks to recycling efforts. Recycling aluminum saves approximately 95% of the energy required to produce new aluminum from bauxite ore. Nevertheless, primary aluminum production has substantial environmental downsides due to its reliance on electricity-often generated from fossil fuels-and the release of greenhouse gases during processing.


Both steel and aluminum come with inherent trade-offs concerning their environmental footprints. A key factor in minimizing negative impacts lies in enhancing recycling systems and investing in cleaner production technologies. For instance, using renewable energy sources in manufacturing processes could substantially cut down CO2 emissions associated with both materials.


In addition to considering raw material extraction and production phases, it's crucial to evaluate transportation impacts since both materials are often shipped over long distances before reaching their final destination as doors. Optimizing supply chains through local sourcing where possible can further reduce carbon footprints.


Moreover, examining end-of-life scenarios reveals opportunities for improving sustainability practices: designing doors with disassembly in mind can facilitate easier recycling or repurposing at product life's end.


Ultimately, selecting between steel and aluminum should involve a comprehensive analysis that balances performance requirements with sustainable practices across each stage of a door's life cycle-from resource extraction through manufacturing to eventual disposal or recycling. By prioritizing eco-friendly innovations within these industries while making informed choices aligned with sustainability goals, we can move closer toward building environments that respect our planet's finite resources without compromising on quality or functionality.


In conclusion, while neither material may present a perfect solution from an environmental standpoint alone-when viewed holistically-they provide viable pathways towards more responsible construction practices when coupled with concerted efforts towards reducing emissions throughout their respective lifecycles.

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Impact of Incorrect Tension Settings on Garage Door Performance

In recent years, the importance of making environmentally conscious decisions has permeated every aspect of our lives, including the materials we choose for home improvement projects. One such decision is selecting the right type of garage door. Wooden garage doors, celebrated for their aesthetic appeal and traditional charm, are increasingly scrutinized for their sustainability and carbon footprint. It becomes imperative to evaluate these aspects to ensure that our material choices align with broader environmental objectives.


Wooden garage doors offer several environmental benefits due to wood's status as a renewable resource. Trees absorb carbon dioxide as they grow, storing carbon within the wood itself. When sustainably sourced from well-managed forests, wooden products like garage doors can contribute positively by promoting forest regeneration and biodiversity conservation. Additionally, at the end of their lifecycle, wooden doors are biodegradable or recyclable, reducing waste in landfills compared to non-renewable alternatives like steel or aluminum.


However, evaluating sustainability goes beyond recognizing wood as a renewable resource; it involves understanding the entire lifecycle of the product from extraction through manufacturing to disposal. Harvesting practices play a crucial role here-unsustainable logging can lead to deforestation and habitat destruction. Therefore, choosing certified sustainable sources such as those approved by organizations like the Forest Stewardship Council (FSC) is vital in minimizing adverse environmental impacts.


The carbon footprint of wooden garage doors hinges on several factors: transportation distance from forest to manufacturer and then to consumers; energy consumed during production; and finishes applied for durability against weather elements. Locally sourced wood can significantly reduce transportation emissions compared to imported materials. Production processes that employ clean energy also help lower emissions associated with manufacturing.


Moreover, finishes used on wooden garage doors often contain volatile organic compounds (VOCs), which contribute to air pollution and climate change. Opting for low-VOC or water-based finishes can mitigate this issue while maintaining door longevity and performance under various weather conditions.


Ultimately, evaluating the sustainability and carbon footprint of wooden garage doors requires a holistic view that considers sourcing practices, production processes, transportation logistics, and lifecycle management. Homeowners should prioritize sustainably certified woods while advocating for industry practices that minimize ecological impact throughout the product's life span.


By making informed choices about materials such as wooden garage doors within home improvement projects, individuals not only enhance their living spaces but also contribute towards an eco-friendlier future-where beauty does not come at the cost of our planet's health. As awareness grows around these considerations in material selection, we collectively move closer toward achieving sustainable living goals without sacrificing quality or aesthetics in design choices.

Impact of Incorrect Tension Settings on Garage Door Performance

Common Electrical Issues Arising from Faulty Installations

In our modern world, where energy efficiency and environmental conservation are of paramount importance, the role of insulation materials stands out as a critical factor in building design and construction. Insulation serves as a barrier to heat flow and is essential for maintaining comfortable indoor temperatures while reducing energy consumption. As we consider the environmental impact of material choices, it becomes clear that selecting the right insulation is not just about immediate energy savings but also about long-term ecological sustainability.


The primary function of insulation materials is to minimize heat transfer between the inside and outside of a building. This characteristic contributes significantly to energy efficiency by reducing the need for heating and cooling systems, which are major consumers of energy in residential and commercial buildings. By lowering energy demand, effective insulation directly reduces greenhouse gas emissions associated with electricity generation from fossil fuels.


However, not all insulation materials are created equal when it comes to their environmental impact. Traditional options like fiberglass and foam board have been widely used due to their insulating properties and relatively low cost. Yet, they often come with downsides such as high embodied energy-the total energy consumed during production-and potential health risks related to off-gassing or fiber release.


In recent years, there has been a growing interest in more sustainable alternatives that offer similar thermal performance with less environmental burden. Materials such as cellulose, which is made from recycled paper products, provide excellent insulation while boasting a much lower carbon footprint compared to conventional options. Sheep's wool and hemp-based insulations are other natural alternatives gaining traction; they not only offer effective thermal resistance but also contribute positively by being biodegradable at the end of their life cycle.


Moreover, advancements in technology have led to innovations like aerogels-a highly efficient insulating material that requires minimal thickness yet provides superior thermal protection. Although currently more expensive than traditional options, ongoing research aims to make these advanced materials more accessible for widespread use.


When considering the environmental impact of insulation choices, it's important also to evaluate factors beyond mere thermal performance. The entire lifecycle of the material-production, installation, longevity, and disposal-should be taken into account. A holistic approach ensures that we do not inadvertently shift burdens from operational energy savings to other forms of environmental degradation.


In conclusion, insulation materials play an indispensable role in enhancing energy efficiency within buildings while simultaneously influencing their overall environmental impact. By making informed decisions about which materials we choose based on both performance metrics and ecological considerations, we can significantly contribute toward sustainable development goals. Moving forward, integrating innovative solutions alongside traditional methods will be key in achieving buildings that are both energy-efficient and environmentally responsible-a crucial step towards addressing climate change challenges globally.

Influence of Environmental Factors on Installed Garage Doors

In recent years, the growing awareness of environmental issues has prompted a significant shift in consumer behavior and industrial practices. One area that is garnering increased attention is the selection of materials for home construction and renovation projects, particularly garage doors. Exploring eco-friendly alternatives and recycled materials for garage doors has become an essential part of considering the environmental impact of material choices.


Traditionally, garage doors have been constructed from metals like steel or aluminum, or from wood sourced without much regard for sustainability. While these materials offer durability and aesthetic appeal, they often come with considerable environmental drawbacks. For instance, the production of steel and aluminum is energy-intensive and contributes significantly to greenhouse gas emissions. Meanwhile, unsustainably harvested wood can lead to deforestation and biodiversity loss.


Recognizing these issues, many manufacturers are now turning towards more sustainable options. Recycled steel is one such alternative that offers a similar level of strength and durability as new steel but with a substantially reduced carbon footprint. By using recycled materials, we not only conserve natural resources but also minimize waste sent to landfills.


Another promising option is composite materials made from recycled wood fibers mixed with plastic resins. These composites mimic the appearance of natural wood while offering enhanced resistance to weathering and decay. Importantly, they make use of post-consumer waste products that would otherwise contribute to landfill overflow.


Bamboo is also emerging as a popular eco-friendly choice due to its rapid growth rate and minimal need for pesticides or fertilizers. As a material for garage doors, bamboo provides a unique aesthetic while contributing positively to environmental conservation efforts.


Additionally, reclaimed wood presents another viable solution for those seeking sustainable garage door options. Sourced from old buildings or discarded furniture, reclaimed wood not only reduces demand on forests but also adds character through its history-laden textures and finishes.


Moreover, incorporating insulating materials into garage door design can play a crucial role in enhancing energy efficiency within homes. Insulated doors help maintain stable temperatures inside garages, reducing reliance on heating or cooling systems and thus lowering overall energy consumption.


While selecting environmentally friendly materials is crucial, it's equally important to consider the lifecycle impact of these choices - from production through usage to eventual disposal or recycling possibilities. This holistic approach ensures that every step taken aligns with sustainability goals.


Homeowners today have unparalleled opportunities to express their commitment towards environmental stewardship through their material choices. By opting for eco-friendly alternatives when installing or replacing garage doors-whether it be recycled metals, composites made from forest-certified timber products or innovative plant-based solutions-they actively participate in preserving our planet's future health while enjoying modern functionality combined with timeless style.


As we continue advancing technologically alongside burgeoning ecological consciousness worldwide-it remains imperative that both industry leaders & consumers remain committed towards exploring further innovations around this vital subject matter: fostering greater responsibility across all sectors involved within residential architecture & beyond!

Routine Maintenance Tips for Newly Installed Garage Doors

When we consider the environmental impact of material choices, it becomes increasingly clear that the selection of durable and low-maintenance materials offers significant long-term benefits. As society grows more aware of sustainability and environmental stewardship, the construction and manufacturing industries are turning their focus toward materials that not only fulfill immediate needs but also contribute positively to the environment over time.


Durable materials, by their very nature, have a longer lifespan. This longevity means they need to be replaced less frequently, reducing the demand for new raw materials and minimizing waste generation. For instance, think about building materials like concrete or steel when compared to less durable options; these robust materials can withstand harsh conditions and heavy usage without significant degradation. In infrastructure projects, this translates into fewer repairs or replacements over decades, which conserves resources and reduces emissions associated with production and transportation.


Low-maintenance materials further compound these benefits by requiring fewer resources for upkeep. Traditional maintenance operations often involve the use of chemicals or energy-intensive processes that can negatively affect our environment. By choosing materials that resist corrosion, weathering, or wear-and-tear naturally, we lessen our dependence on such environmentally taxing practices. For example, using composite decking instead of wood avoids the need for regular staining or sealing while offering resistance to insects and rot.


The ripple effect of these choices is profound. Reduced resource extraction lowers habitat destruction and biodiversity loss associated with mining or deforestation activities. Furthermore, if we consider the energy savings from reduced manufacturing demands-less frequent production cycles mean lower energy consumption-it's clear how substantial these long-term advantages become in cutting down greenhouse gas emissions.


Additionally, embracing durable and low-maintenance materials aligns with economic goals by lowering lifecycle costs. While initial investments may be higher than traditional alternatives because quality often comes at a price premium, overall savings accrue through decreased maintenance expenses and extended service life.


In conclusion, prioritizing durable and low-maintenance materials provides a pathway to achieving sustainable development goals while supporting ecological balance. It encourages us to re-evaluate our consumption patterns and make decisions that align with both immediate needs and future well-being. As more industries adopt this mindset shift toward long-term thinking in material selection, the cumulative positive impacts on our planet will undoubtedly become increasingly evident.

 

A remote control for a keyless entry system built into an ignition key: pressing a button on the key unlocks the car doors, while another button locks the car and activates its alarm system

A remote keyless system (RKS), also known as remote keyless entry (RKE) or remote central locking, is an electronic lock that controls access to a building or vehicle by using an electronic remote control (activated by a handheld device or automatically by proximity).[1] RKS largely and quickly superseded keyless entry, a budding technology that restrictively bound locking and unlocking functions to vehicle-mounted keypads.

Widely used in automobiles, an RKS performs the functions of a standard car key without physical contact. When within a few yards of the car, pressing a button on the remote can lock or unlock the doors, and may perform other functions.

A remote keyless system can include both remote keyless entry (RKE), which unlocks the doors, and remote keyless ignition (RKI), which starts the engine.

History

[edit]

Remote keyless entry was patented in 1981 by Paul Lipschutz, who worked for Nieman (a supplier of security components to the car industry) and had developed a number of automotive security devices. His electrically actuated lock system could be controlled by using a handheld fob to stream infrared data. Patented in 1981 after successful submission in 1979, it worked using a "coded pulse signal generator and battery-powered infra-red radiation emitter." In some geographic areas, the system is called a PLIP system, or Plipper, after Lipschutz. Infrared technology was superseded in 1995 when a European frequency was standardised.[2][3]

The remote keyless systems using a handheld transmitter first appeared on the French made Renault Fuego in 1982,[4] and as an option on several American Motors vehicles in 1983, including the Renault Alliance. The feature gained its first widespread availability in the U.S. on several General Motors vehicles in 1989.[citation needed]

Prior to Remote Keyless Entry, a number of systems were introduced featuring Keyless Entry (i.e., not remote), including Ford's 1980 system introduced on the Ford Thunderbird, Mercury Cougar, Lincoln Continental Mark VI, and Lincoln Town Car, which Ford called Keyless Entry System (later marketed SecuriCode). The system used a five-button keypad on the driver-side with that could unlock the driver's door when the code was entered, with subsequent code entries to unlock all doors or trunk — or lock the vehicle from the outside.

The sixth generation Buick Electra (1985-1991) featured a sill-mounted keypad for model years 1985-1988, superseded in 1989 by a remote keyless entry system.

Nissan offered the same door keypad technology on the 1984 Maxima, Fairlady, Gloria and Cedric, essentially using the same approach as Ford, with the addition of being able to roll the windows down and open the optional moonroof from outside the vehicle on the door handle installed keypad on both the driver's and front passengers door as well as roll the windows up, close the optional sunroof and lock the vehicle.

As of 2024, Ford continued to offer a fob-operated remote keyless system or completely keyless system, augmented by its Securicode five-button keypad.[5] The combination enabled tiered or time-restricted permissions, i.e., the code giving access to the vehicle but not its operation — and the code being easily changed to prevent subsequent vehicle access.

Function

[edit]

Keyless remotes contain a short-range radio transmitter, and must be within a certain range, usually 5–20 meters, of the car to work. When a button is pushed, it sends a coded signal by radio waves to a receiver unit in the car, which locks or unlocks the door. Most RKEs operate at a frequency of 315 MHz for North America-made cars and at 433.92 MHz for European, Japanese and Asian cars. Modern systems since the mid-1990s implement encryption as well as rotating entry codes to prevent car thieves from intercepting and spoofing the signal.[6] Earlier systems used infrared instead of radio signals to unlock the vehicle, such as systems found on Mercedes-Benz,[7] BMW[8] and other manufacturers.

The system signals that it has either locked or unlocked the car usually through some fairly discreet combination of flashing vehicle lamps, a distinctive sound other than the horn, or some usage of the horn itself. A typical setup on cars is to have the horn or other sound chirp twice to signify that the car has been unlocked, and chirp once to indicate the car has been locked. For example, Toyota, Scion, and Lexus use a chirp system to signify the car being locked/unlocked. While two beeps means that driver's door is unlocked, four beeps means all doors are unlocked. One long beep is for the trunk or power tailgate. One short beep signifies that the car is locked and alarm is set.

The functions of a remote keyless entry system are contained on a key fob or built into the ignition key handle itself. Buttons are dedicated to locking or unlocking the doors and opening the trunk or tailgate. On some minivans, the power sliding doors can be opened/closed remotely. Some cars will also close any open windows and roof when remotely locking the car. Some remote keyless fobs also feature a red panic button which activates the car alarm as a standard feature. Further adding to the convenience, some cars' engines with remote keyless ignition systems can be started by the push of a button on the key fob (useful in cold weather), and convertible tops can be raised and lowered from outside the vehicle while it's parked.

On cars where the trunk release is electronically operated, it can be triggered to open by a button on the remote. Conventionally, the trunk springs open with the help of hydraulic struts or torsion springs, and thereafter must be lowered manually. Premium models, such as SUVs and estates with tailgates, may have a motorized assist that can both open and close the tailgate for easy access and remote operation.

For offices, or residences, the system can also be coupled with the security system, garage door opener or remotely activated lighting devices.

Programming

[edit]

Remote keyless entry fobs emit a radio frequency with a designated, distinct digital identity code. Inasmuch as "programming" fobs is a proprietary technical process, it is typically performed by the automobile manufacturer. In general, the procedure is to put the car computer in 'programming mode'. This usually entails engaging the power in the car several times while holding a button or lever. It may also include opening doors, or removing fuses. The procedure varies amongst various makes, models, and years. Once in 'programming mode' one or more of the fob buttons is depressed to send the digital identity code to the car's onboard computer. The computer saves the code and the car is then taken out of programming mode.

As RKS fobs have become more prevalent in the automobile industry a secondary market of unprogrammed devices has sprung up. Some websites sell steps to program fobs for individual models of cars as well as accessory kits to remotely activate other car devices.

On early (1998–2012) keyless entry remotes, the remotes can be individually programmed by the user, by pressing a button on the remote, and starting the vehicle. However, newer (2013+) keyless entry remotes require dealership or locksmith programming via a computer with special software . The Infrared keyless entry systems offered user programming, though radio frequency keyless entry systems mostly require dealer programming.

Passive systems

[edit]

Some cars feature a passive keyless entry system. Their primary distinction is the ability to lock/unlock (and later iterations allow starting) the vehicle without any input from the user.

General Motors pioneered this technology with the Passive Keyless Entry (PKE) system in the 1993 Chevrolet Corvette. It featured passive locking/unlocking, but traditional keyed starting of the vehicle.

Today, passive systems are commonly found on a variety of vehicles, and although the exact method of operation differs between makes and models, their operation is generally similar: a vehicle can be unlocked without the driver needing to physically push a button on the key fob to lock or unlock the car. Additionally, some are able to start or stop the vehicle without physically having to insert a key.

Security

[edit]

Keyless ignition does not by default provide better security. In October 2014, it was found that some insurers in the United Kingdom would not insure certain vehicles with keyless ignition unless there were additional mechanical locks in place due to weaknesses in the keyless system.[9]

A security concern with any remote entry system is a spoofing technique called a replay attack, in which a thief records the signal sent by the key fob using a specialized receiver called a code grabber, and later replays it to open the door. To prevent this, the key fob does not use the same unlock code each time but a rolling code system; it contains a pseudorandom number generator which transmits a different code each use.[10] The car's receiver has another pseudorandom number generator synchronized to the fob to recognise the code. To prevent a thief from simulating the pseudorandom number generator the fob encrypts the code.

News media have reported cases where it is suspected that criminals managed to open cars by using radio repeaters to trick vehicles into thinking that their keyless entry fobs were close by even when they were far away (relay attack),[11] though they have not reported that any such devices have been found. The articles speculate that keeping fobs in aluminum foil or a freezer when not in use can prevent criminals from exploiting this vulnerability.[12]

In 2015, it was reported that Samy Kamkar had built an inexpensive electronic device about the size of a wallet that could be concealed on or near a locked vehicle to capture a single keyless entry code to be used at a later time to unlock the vehicle. The device transmits a jamming signal to block the vehicle's reception of rolling code signals from the owner's fob, while recording these signals from both of his two attempts needed to unlock the vehicle. The recorded first code is sent to the vehicle only when the owner makes the second attempt, while the recorded second code is retained for future use. Kamkar stated that this vulnerability had been widely known for years to be present in many vehicle types but was previously undemonstrated.[13] A demonstration was done during DEF CON 23.[14]

Actual thefts targeting luxury cars based on the above exploit have been reported when the key fob is near the front of the home. Several workaround can prevent such exploits, including placing the key fob in a tin box.[15][16] A criminal ring stole about 100 vehicles using this technique in Southern and Eastern Ontario.[17]

See also

[edit]
  • Near field communication
  • Ignition switch
  • Transponder car key

References

[edit]
  1. ^ Job, Ann. "Driving Without Car Keys". MSN Autos. Archived from the original on 9 May 2012. Retrieved 27 February 2012.
  2. ^ Mills, James (8 November 2014). "Keyless wonder: how did we end up with 'smart' wireless keys for our cars?". Sunday Times.
  3. ^ Torchinsky, Jason (23 February 2021). "I Had No Idea The Renault Fuego Was The Car With This Huge Automotive First". Jalopnik.
  4. ^ "1980–1985 RENAULT Fuego Turbo". Octane. Archived from the original on 27 October 2012. Retrieved 27 February 2012.
  5. ^ Ryan McManus (2 December 2004). "The Persistence of SecuriCode:". Medium.com.
  6. ^ Lake, Matt (7 June 2001). "HOW IT WORKS; Remote Keyless Entry: Staying a Step Ahead of Car Thieves". The New York Times. ISSN 0362-4331. Retrieved 10 February 2017.
  7. ^ infrared-keyless-entry, benzworld.org.
  8. ^ "Archived copy of post to BMW forum". Archived from the original on 9 November 2013. Retrieved 29 June 2012.
  9. ^ "Thieves target luxury Range Rovers with keyless locking systems". TheGuardian.com. 27 October 2014.
  10. ^ Brain, Marshall (15 August 2001). "How remote entry works". How Stuff Works website. Retrieved 19 August 2022.
  11. ^ "CCTV video shows suspects using electronic method to steal cars in northeast Toronto – CityNews Toronto".
  12. ^ Steinberg, Joseph (12 May 2015). "Vulnerability In Car Keyless Entry Systems Allows Anyone To Open And Steal Your Vehicle". Forbes.
  13. ^ Thompson, Cadie (6 August 2015). "A hacker made a $30 gadget that can unlock many cars that have keyless entry". Tech Insider. Retrieved 11 August 2015.
  14. ^ Kamkar, Samy (7 August 2015). "Drive It Like You Hacked It: New Attacks and Tools to Wirelessly Steal Cars". DEF CON 23. Retrieved 11 August 2015.
  15. ^ "3 solutions to electronic car theft, a continuing threat to high-end Toronto automobiles". CBC.
  16. ^ "Toyota, Lexus owners warned about thefts that use 'relay attacks'". CBC.
  17. ^ "20 charged in high-end vehicle thefts in Ontario". CBC.
[edit]
Wikimedia Commons has media related to Plips.
  • Article about how keyless entry remote systems on automobiles work
  • Requirements of Remote Keyless Entry (RKE) Systems
  • False warning about RKE code thieves at Snopes.com

 

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Reviews for Overhead Door Company of Joliet

Overhead Door Company of Joliet

Andrea Nitsche

(4)

Scheduling was easy, job was done quickly. Little disappointed that they gave me a quote over email (which they confirmed was for labor and materials), but when they finished it was just over $30 more. Not a huge deal, but when I asked why, I was told they gave me an approx cost and it depends on what is needed. I get that in general, however, they installed the door and I gave them my address and pics of the existing prior to getting a quote. I feel like they could have been more upfront with pricing. And just a heads up, it was pricey... Had them change the weather stripping, from ringing my doorbell to pulling out my driveway when done was literally 20 mins, cost was just over $260 😬

Overhead Door Company of Joliet

Kelley Jansa

(5)

We used Middleton Door to upgrade our garage door. We had three different companies come out to quote the job and across the board Middleton was better. They were professional, had plenty of different options and priced appropriately. The door we ordered came with a small dent and they handled getting a new panel ordered and reinstalled very quickly.

Overhead Door Company of Joliet

Hector Melero

(5)

Had a really great experience with Middleton Overhead Doors. My door started to bow and after several attempts on me fixing it I just couldn’t get it. I didn’t want to pay on something I knew I could fix. Well, I gave up and they came out and made it look easy. I know what they are doing not to mention they called me before hand to confirm my appointment and they showed up at there scheduled appointment. I highly recommend Middleton Overhead Doors on any work that needs to be done

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Frequently Asked Questions

The most environmentally friendly materials for garage doors include sustainably sourced wood, recycled steel, and aluminum. These materials have a lower carbon footprint and can often be recycled at the end of their lifespan.
Insulated garage doors help maintain temperature stability inside the garage, reducing energy consumption by lessening the need for heating or cooling adjacent spaces. This leads to lower energy bills and minimizes environmental impact.
Yes, look for certifications like ENERGY STAR for energy efficiency, FSC (Forest Stewardship Council) certification for sustainable wood sourcing, and Cradle to Cradle certification indicating a product’s lifecycle sustainability.
Yes, choosing materials such as recycled metal or reclaimed wood reduces resource extraction impacts. Additionally, opting for locally sourced materials can decrease transportation emissions associated with long-distance shipping.