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Draught excluder
Draught excluder
Draught excluder
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A draught excluder in the shape of a cat

A draught excluder or draft guard is a device used to prevent cold air from entering a building through gaps around entry points such as doors, windows and fireplaces.

Types

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Door

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A door draught excluder is placed at the bottom of a door to cover the gap located at the threshold.[1][2] In the Victorian era these draught excluders would be sausage-shaped and made from fabric stuffed with sawdust.[3]

Tubular sand-filled fabric draught excluders are commonly referred to as "door snakes" in Australia.[4][5] Jenny Agutter told The Guardian that the hotel in the Outback where they stayed while making Walkabout used them to keep venomous snakes out of the guests' rooms.[6]

Window

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Draught excluders can come in the form of a self-adhesive roll of rubber or other flexible material. The material can be applied over fixed gaps in window frames.[7]

Letter box

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Letter box covers usually take the form of a brush-like cover fitted to the inside of the door. Other types include spring-loaded flaps also fitted to the inside.

Key hole

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Key holes can be draught proofed with a simple proprietary key hole cover that is fitted to the inside of the door.

Chimneys and fireplaces

[edit]

Unused or infrequently used chimney flues can be draught proofed with balloon or fabric type excluders that are fitted in the lower section of the flue. Fireplaces can also be draught proofed using a cover over the opening.

References

[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

Draught excluder

View on Grokipedia
from Grokipedia
A draught excluder, also known as a draft excluder or draft guard, is a device used to seal gaps around doors, windows, chimneys, and other building openings to prevent cold air infiltration, thereby maintaining indoor warmth and reducing heat loss. These barriers typically consist of strips, cushions, or fitted seals made from materials such as rubber, , , brushes, or insulating fabric, and they address common sources of unwanted in homes and buildings. Draught excluders date back to at least the , with early designs in the featuring sausage-shaped fabric tubes filled with sawdust. By blocking these gaps, draught excluders enhance energy efficiency and occupant comfort without compromising necessary ventilation. Draught excluders vary by application and design to suit different gaps and building types. For external doors and windows, options include self-adhesive strips for quick, low-cost installation or more robust metal and carriers with or wiper seals that accommodate seasonal movement, such as in older or historic structures. Bottom-of-door gaps are often addressed with tubular fabric excluders filled with materials like sand or , while letterboxes and keyholes require specialized flaps or covers. Chimneys in unused fireplaces can be sealed with removable internal pillows or external caps to prevent warm air escape and cold downdraughts. In heritage contexts, reversible and low-impact seals like compression types are preferred to preserve original features while achieving up to 86% reduction in air leakage through elements like sash windows. The use of draught excluders offers notable benefits, including annual energy bill savings of around £85 for proofing doors, windows, and floors in (as of 2025), with additional savings of up to £60 from chimney proofing, for a combined total of approximately £145. This allows for lower thermostat settings without sacrificing comfort. Additional advantages encompass reduced , dust entry, and overall heat loss—potentially 15-20% in older buildings—contributing to lower carbon emissions. However, effective draught proofing must balance sealing with controlled ventilation to prevent buildup, , or risks from poor air quality, particularly in homes with gas appliances or high . Professional assessment is recommended for comprehensive installations, which can cost around £250 for a typical .

Introduction

Definition and Purpose

A draught excluder is a barrier device designed to fit around gaps in , windows, and other building openings to prevent unwanted air infiltration, such as cold drafts during winter or excess hot air in summer. These devices address the common issue of air leakage in structures, where uncontrolled through cracks and crevices compromises indoor climate control. The primary purpose of a draught excluder is to minimize heat loss from heated interiors while blocking the entry of external elements like , , and , thereby promoting energy efficiency and reducing reliance on intensive heating or cooling systems. By sealing these pathways, it helps maintain stable indoor temperatures, which can lower overall without eliminating essential for and safety. At its core, a draught excluder functions by forming a flexible or rigid seal that compresses against surfaces to obstruct air movement, effectively insulating the while preserving controlled ventilation through dedicated vents or openings. This mechanism ensures that remains adequate, as it targets only inadvertent leaks rather than all air exchange. Key benefits include enhanced for occupants, substantial potential savings on bills—such as 10-20% reductions in overall home use from air sealing measures—and support for sustainable practices by curbing unnecessary consumption. For a typical , these savings can translate to annual reductions of around £85 in heating costs in , as of 2025.

Historical Development

The practice of blocking drafts in homes predates formalized draught excluders, with pre-19th century inhabitants of dwellings using basic improvised barriers such as tapestries hung on walls and between doorways to absorb dampness and impede air flow. These early methods, while effective in medieval and earlier structures, were not specifically designed as dedicated devices and relied on available fabrics or rugs to mitigate cold air infiltration in uninsulated buildings. The term "draught excluder" emerged in the mid-19th century, with the earliest recorded use in 1851 in the architectural publication The Builder, coinciding with the Victorian era (1837–1901) when such items gained popularity in cold climates like Britain. During this period, sausage-shaped fabric "door snakes" became a common handmade solution, typically stuffed with sawdust, husks, or sand to create a weighted barrier placed at the base of doors in households seeking to retain indoor warmth. The Industrial Revolution amplified the need for such innovations by driving urbanization and the construction of larger, draft-prone homes, while advancements in manufacturing enabled more consistent production of insulating materials for domestic use. In the early 20th century, draught excluders evolved from fabric-based designs to include more durable rubber and metal seals, building on the 1839 invention of vulcanized rubber by that allowed for flexible, weather-resistant stripping applied to door and window frames. A notable advancement came in 1948 with U.S. Patent US2441073A, which described a mechanical door draught excluder incorporating springs and brushes for automatic adjustment and sealing against gaps. Post-World War II, the 1950s and 1960s saw a shift to mass-produced and products, such as foamed strips and expanded seals, which offered easier installation and better compression for everyday home use. This transition accelerated in the amid global oil crises, which heightened awareness of and prompted widespread adoption of efficient draught-proofing to reduce heating costs in residences. Entering the , developments in draught excluders have emphasized , with innovations focusing on eco-friendly materials like recycled fabrics, natural fibers, and long-lasting UV-resistant seals that minimize environmental impact while maintaining effectiveness. These modern designs reflect broader movements toward energy-efficient and practices, influenced by ongoing concerns over and resource conservation.

Materials and Designs

Traditional Materials

Traditional draught excluders relied on simple, natural materials that were readily available in households and aligned with the craftsmanship of the era. Fabric-based designs, often known as "door snakes" or sausage-shaped pillows, used heavy textiles such as velvet or for durable outer casings. These were typically stuffed with natural fillers like straw or (excelsior) to provide weight and insulation against air leaks under doors. In addition to portable fabric options, fixed installations incorporated wood and metal elements, particularly in Victorian and Edwardian homes. Simple wooden thresholds, crafted from or , served as raised barriers at door bottoms to block draughts while blending with period woodwork. Metal strips, often made of or , were fitted along door edges or sills for a more robust seal, reflecting the era's industrial advancements in durable hardware. These traditional materials offered several advantages, including biodegradability from their natural compositions, low cost due to local sourcing, and high customizability through DIY methods like and , which turned draught excluders into embroidered household crafts. However, they had limitations, such as fillers settling over time, potentially attracting pests like or , and degrading in moist environments, which could lead to rot in wood or in fabrics. The term "draught excluder" itself dates to the mid-19th century, with the first recorded use around 1851. By the , these natural options began evolving toward synthetic alternatives for improved durability.

Modern Materials

Modern draught excluders commonly incorporate synthetic rubbers such as EPDM, valued for its excellent weather resistance and ability to withstand UV exposure and degradation, making it suitable for external applications. EPDM seals provide durable compression that forms airtight barriers against drafts while offering and noise insulation properties. PVC strips are another prevalent synthetic option, often used in self-adhesive forms for quick application on doors and windows, providing flexible sealing without significant degradation over time. Foam materials like neoprene and polyethylene enhance efficiency through their closed-cell structures, which resist moisture ingress and compress effectively to seal gaps up to 5 mm. Neoprene foam excels in shock absorption and sound dampening, contributing to acoustic insulation in addition to draught prevention. Polyethylene variants offer similar thermal insulation benefits, maintaining shape under repeated use and aiding in energy conservation by reducing heat loss. Brush and pile designs utilize or bristles mounted in aluminum or plastic carriers, enabling flexible adaptation to uneven surfaces like or sash windows for consistent sealing. These synthetic bristles provide durability against wear while allowing airflow when needed, outperforming older fabric fillers that often lacked such longevity. Since the , eco-friendly innovations have gained traction, including recycled plastics in composite seals and wool blends that leverage natural insulation without synthetic additives. Biodegradable composites, such as those incorporating fibers, offer sustainable alternatives that reduce environmental impact while providing effective draught blocking and fire-retardant properties. Contemporary formulations emphasize performance enhancements, including UV-resistant rubbers for prolonged weatherproofing and materials with inherent acoustic insulation to minimize transmission. Wool's natural fire-retardant properties and additives in certain foams ensure safety compliance, particularly in residential settings. Many modern draught excluder materials adhere to energy efficiency standards, such as those endorsed by the Energy Saving Trust, which highlight their role in achieving up to £85 annual savings on heating costs through improved airtightness. These certifications guide sourcing toward products that balance durability, efficiency, and sustainability.

Types by Location

Doors

Draught excluders for doors primarily target gaps at the bottom and around the perimeter to prevent air infiltration, with designs tailored to the door's movement and environmental exposure. Bottom seals, such as automatic drop seals, are activated by the door's closing action, where a spring-loaded mechanism lowers a seal—often made of rubber or —to contact the floor, effectively blocking draughts without impeding door operation. These seals are particularly advantageous for maintaining a tight fit during closure. For high-traffic external doors, brush strips serve as a robust alternative, featuring flexible bristles that sweep across the threshold to seal gaps while accommodating door swing and from frequent use. Nylon variants of these strips offer enhanced durability in demanding areas. Perimeter options focus on the frame's sides and top, where compression seals provide a flexible barrier that compresses against the upon closure, accommodating the natural expansion and contraction of or metal frames due to and changes. Materials like self-adhesive or in these seals ensure a weather-resistant fit for both internal and external applications. Common challenges in door draught proofing include gaps arising from uneven floors or building settlement, which can undermine fixed seals by creating inconsistent contact points. Automatic drop seals address these issues through adjustable or self-levelling mechanisms that adapt to surface irregularities. For internal doors, weighted fabric snakes—filled with sand or beans and placed along the bottom—offer a simple, removable solution to fill such gaps without permanent installation. These designs are ideal for frequent-use areas, prioritizing to withstand repeated openings and environmental stresses; for instance, rubber seals on external storm doors resist and abrasion effectively. Brush and rubber materials stand out as standard choices for their longevity in high-wear scenarios.

Windows

Draught excluders for windows adapt sealing principles similar to those used for but are designed for lighter frames and vertical or hinged movements to maintain operability and visibility. For windows, which feature upper and lower sashes that slide vertically, pile seals or are commonly inserted into grooves along the meeting rails and stiles. These fin-like seals, often made from or fin pile materials, compress upon closing to block air infiltration while allowing smooth sash operation without binding or excessive friction. Systems like those from Draftfix involve replacing or retrofitting parting beads with low-friction weatherstrips, reducing draughts by up to 50% in heritage applications. Casement and windows, which open outward on hinges, require seals that withstand wind pressure and frame flexing. Self-adhesive tapes provide a flexible barrier along the jambs and head, compressing against when closed to seal gaps effectively. Magnetic strips offer a reusable alternative, adhering to the frame and attracting to a counterpart on for a secure, low-profile seal that facilitates easy opening. Brush strips along the sill edge further prevent bottom gaps in types, where projects outward. In double-glazed windows, slim seals are used around the perimeter frame to address perimeter leaks without interfering with the insulated unit. These low-profile , such as glazing seal profiles, fit into rebates to create an airtight barrier that preserves clear sightlines and does not alter the space between panes. Replacement of worn edge seals can restore efficiency, reducing heat loss through failed perimeters. Window draught excluders must balance airtightness with ventilation requirements to prevent moisture buildup and ensure . In occupied spaces, seals are applied selectively to allow controlled airflow, often complemented by trickle vents in modern frames. historic timber windows prioritizes reversible methods, such as brush pile strips in original grooves, to seal gaps while preserving the window's aesthetic integrity and avoiding damage to delicate joinery. Guidance from recommends assessing air leakage first via smoke tests before applying seals, ensuring up to 33% reduction in infiltration without compromising heritage value.

Other Entry Points

Draught excluders for letter boxes typically employ flap seals or brush inserts to prevent air infiltration while permitting mail delivery. These devices, often featuring flaps backed by for enhanced insulation, create a barrier against cold air entering through the . Brush strips, integrated into the flap mechanism, further seal the opening when closed, allowing letters to pass without obstruction. For keyholes, specialized rubber seals or covers are used to block drafts through mortise locks, fitting beneath the lock's backplate to maintain access for keys without compromising the seal. Chimney and fireplace draught excluders focus on sealing the or to halt loss during non-use periods and minimize ingress. Inflatable pillows, such as chimney balloons, expand to fit snugly within the above the damper, providing a temporary, removable barrier that reduces cold air descent. seals, positioned at the 's narrow upper section, offer a more permanent solution by blocking airflow while adhering to standards; for instance, wool-based excluders like the Chimney Sheep have undergone testing to confirm they do not ignite or contribute to fires, ensuring compliance with safety regulations for fireplaces. Beyond primary utility points, draught excluders address gaps in skirting boards, loft hatches, and electrical outlets using -based materials. Skirting board gaps are sealed with , decorators' , or expanding fillers to close voids between the board and floor or wall, preventing underfloor air circulation. Loft hatches benefit from self-adhesive strips or compression seals applied around the perimeter, creating an airtight barrier that complements insulation boards for retention. Electrical outlets require thin gaskets inserted behind wall plates to seal around wiring penetrations, blocking convective air leaks without interfering with functionality. Specialized applications of these excluders include compliance for seals, where materials must resist and allow for safe removal during use, as verified through independent testing protocols. In urban settings with high external , excluders with acoustic enhancements, such as dense or brush combinations, provide additional sound attenuation, reducing ingress of street by up to 40 dB in tested models while maintaining draught-proofing efficacy.

Installation and Use

Methods of Installation

Installing draught excluders as a DIY project begins with accurate measurement of the gaps around , windows, and other entry points to ensure a proper fit without obstructing movement. Once measured, clean the surfaces thoroughly using warm soapy water, a mild , or to remove dirt, grease, and old paint residue, allowing the area to dry completely for optimal . Common tools for this process include a , or for cutting strips, a or for securing fixings, and a cleaning cloth. For adhesive-based applications, suitable for smooth frames like uPVC, peel off the backing and press the or rubber strips firmly into place along the measured lines, ensuring even coverage to seal gaps effectively. On thresholds or uneven wooden surfaces, opt for screw-fixed excluders, such as strips or seals, by pilot holes and securing with screws, adjusting the position as needed to align properly. For sash windows, a slide-in technique works well: cut or wiper strips to length, clean the channels, and insert them into the frame grooves or attach via adhesive carriers, leaving a 1-2 mm clearance to maintain smooth sash operation. Materials like rubber or facilitate easy application on non-porous surfaces. While DIY methods suit most standard installations, assistance is recommended for custom fits in historic or older homes where precise alignment is crucial to preserve structural integrity and avoid ventilation issues. s often use specialized tools like sealants and drills for complex setups, and obtaining quotes from certified tradespeople ensures compliance with building standards. To ensure safety and functionality, avoid over-compressing or over-tightening fixings, which can cause doors or windows to bind, and test the installation by operating the entry point multiple times to check for air leaks or restricted movement.

Maintenance and Effectiveness

Maintaining draught excluders involves regular cleaning to preserve their sealing integrity and prevent accumulation of dust or debris that could compromise performance. For brush-type excluders, vacuuming the bristles periodically removes trapped particles, while rubber or foam seals should be wiped with a mild soap solution and a damp cloth to clean without damaging the material. Inspections for wear should occur every 6-12 months, focusing on signs of degradation to ensure ongoing efficacy. Replacement is necessary when excluders show indicators of reduced performance, such as cracking or brittleness in rubber seals, flattening or compression in foam materials, or visible tears that allow air penetration. These signs signal diminished sealing ability, often accompanied by noticeable drafts or increased energy use. Synthetic draught excluders typically have a lifespan of 5-10 years, though this can vary based on usage and environmental conditions. The effectiveness of draught excluders can be assessed using simple diagnostic methods like smoke tests, where a or is held near potential leak points to visualize air movement, or thermal imaging cameras that detect temperature differentials indicating drafts. These tools help identify residual air leaks post-installation, confirming the excluder's performance. According to the Energy Saving Trust (as of October 2025), effective draught proofing can save around £85 per year on heating costs for windows, doors, and floors in . Several factors influence the long-term performance of draught excluders, including exposure to harsh climates like extreme temperatures or UV radiation, which accelerate material degradation, and building movements such as or expansion that can create new gaps. Integration with overall home insulation enhances their impact by addressing broader heat loss pathways, while seasonal adjustments—such as using removable excluders in varying —help maintain optimal sealing without restricting necessary ventilation.

References

  1. https://www.oed.com/dictionary/draught-excluder_n
  2. https://dictionary.cambridge.org/us/dictionary/english/draught-excluder
  3. https://energysavingtrust.org.uk/advice/draught-proofing/
  4. https://historicengland.org.uk/advice/your-home/energy-efficiency/making-changes-to-save-energy/draught-proofing/
  5. https://www.energy.gov/energysaver/air-sealing-your-home
  6. https://www1.eere.energy.gov/buildings/publications/pdfs/building_america/airsealing_multiunit_structures.pdf
  7. https://www.pjfitz.com/blog/insulation-installation/home-improvement-history-lessons-insulation/
  8. https://advanceinsulation.ca/how-the-industrial-revolution-changed-the-way-we-insulate-buildings/
  9. https://www.britannica.com/biography/Charles-Goodyear
  10. https://patents.google.com/patent/US2441073A/en
  11. https://www.retrofoam.com/blog/history-of-home-insulation
  12. https://advanceinsulation.ca/how-the-1973-oil-crisis-sparked-the-insulation-boom-a-look-from-the-1970s-to-today/
  13. https://stokvistapes.nl/en/news/draught-excluders-sealing/
  14. https://www.granddesignsmagazine.com/sustainable-design/how-to-make-a-victorian-house-more-eco-friendly/
  15. https://www.build-review.com/cushions-through-history-to-the-here-and-how/
  16. http://lefebvreupholstery.blogspot.com/2014/06/my-furniture-is-stuffed-with-what.html
  17. https://www.stair-rodsdirect.co.uk/blogs/article/thresholds-for-historic-homes
  18. https://therubbercompany.com/sponge-foam/epdm-sponge-rubber/closed-cell-epdm-sponge-rubber/
  19. https://www.tubewaysales.com/cat/easyfix-diy-draught-excluders/easyfix-foam-and-epdm-draught-excluders/
  20. https://www.ellen-profiles.com/weatherstrip-foam
  21. https://presbond.com/products/1-4-thick-neoprene-foam-strip-3-4-width-x-50-length-black
  22. https://www.ekibv.com/foam/polyethylene-foam
  23. https://chimneysheep.co.uk/pages/about-us
  24. https://www.ecologicalbuildingsystems.com/product/chimney-sheep-square-draught-excluder
  25. https://iwto.org/wellness/flame-resistance/
  26. https://us.allegion.com/en/products/brands/zero-international/automatic-door-bottoms.html
  27. https://georgeculley.co.uk/blogs/blog/understanding-brush-seals-and-door-brush-strips
  28. https://historicengland.org.uk/images-books/publications/eehb-draught-proofing-windows-doors/heag084-draughtproofing/
  29. https://www.hiatt-hardware.com/blog/post/draught-proofing-windows
  30. https://www.draftfix.co.uk/
  31. https://www.granddesignsmagazine.com/glazing/windows/how-to-draught-proof-your-sash-windows/
  32. https://www.mightonproducts.com/category/sash-window-hardware/draughtproofing/
  33. https://therubbercompany.com/extrusions-profiles/silicone-extrusions/silicone-glazing-seal-profiles/
  34. https://www.exactseal.com/portfolio/silicone-windows-and-door-gaskets/
  35. https://www.fastframeuk.com/news/how-to-draught-proof-heritage-sash-windows/
  36. https://firesealshop.com/products/nor400
  37. https://www.homebuilding.co.uk/advice/draught-proofing-windows
  38. https://sashwindows-london.com/sash-windows/replacement/diy-guide-installing-draft-excluders-on-your-sash-windows-like-a-pro/
  39. https://homeowners.retrofitwest.co.uk/knowledge-guide/easy-diy-draught-proofing/
  40. https://www.doorsuperstore.co.uk/help-and-advice/project-guides/accessories/how-to-fit-a-draught-excluder-around-a-door/
  41. https://www.housedigest.com/1408489/best-way-clean-draft-stopper/
  42. https://www.yunlinplushtoys.com/blog/best-draught-excluders-to-keep-home-cozy-year-round/
  43. https://us.garadry.com/blogs/maintenance/how-do-i-know-if-my-garage-door-weather-seal-needs-to-be-replaced
  44. https://www.thisoldhouse.com/doors/21018244/the-essential-guide-to-weatherstripping
  45. https://www.windowworldtx.com/blog/how-often-should-you-replace-weather-stripping/
  46. https://windowhardwaredirect.com/blogs/news/everything-you-need-to-know-about-weather-stripping-for-your-home
  47. https://www.greenbuildingadvisor.com/article/using-smoke-to-find-air-leaks
  48. https://www.energy.gov/energysaver/thermographic-inspections
  49. https://www.tradewindowcentre.co.uk/what-causes-door-draughts/
  50. https://www.fluke.com/en-us/learn/blog/energy-efficiency/energy-auditing-and-weatherization-with-thermal-imagers
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