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Natural chute (falls) on the left and man-made logging chute on the right on the Coulonge River in Quebec, Canada

A chute is a vertical or inclined plane, channel, or passage through which objects are moved by means of gravity.

Landform

[edit]

A chute, also known as a race, flume, cat, or river canyon, is a steep-sided passage through which water flows rapidly.

Akin to these, man-made chutes, such as the timber slide and log flume, were used in the logging industry to facilitate the downstream transportation of timber along rivers. These are no longer in common use. Man-made chutes may also be a feature of spillways on some dams. Some types of water supply and irrigation systems are gravity fed, hence chutes. These include aqueducts, puquios, and acequias.

Building chutes

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Chutes are in common use in tall buildings to allow fast and efficient transport of items and materials from the upper floors to a central location on one of the lower floors, especially the basement. Chutes may be of a round, square or rectangular cross-section at the top and/or the bottom.

  • Laundry chutes in hotels are placed on each floor to allow the expedient transfer and collection of dirty laundry to the hotel's laundry facility without having to use elevators or stairs. These chutes are generally constructed from aluminized or stainless steel sections, welded together to avoid any extruding parts or sharp edges that may tear or damage the materials.

Home laundry chutes are typically found in homes with basement laundry to allow the collection of all household members' dirty laundry, conveniently near the bedrooms and laundry facilities, without the constant transport of laundry bins from floor-to-floor, room-to-room or up and down stairs. Home laundry chutes may be less common than previously due to building codes or concern regarding fireblocking, the prevention of fire from spreading from floor-to-floor,[1] as well as child safety.[2][3] However, construction including cabinets, doors, lids, and locks may make both risks significantly less than with simple stairwells.

  • Refuse chutes, rubbish chutes, or garbage chutes are common in high-rise apartment buildings and are used to collect all the building's waste in one place. The bottom end of the chute is normally positioned directly above a large, open-topped waste container, but sometimes may also include a mechanical waste compactor. This makes garbage collection and disposal faster and more efficient, however it can be a potential hygiene risk and health hazard due to garbage residue left inside the chutes, which must be cleaned regularly.
  • Mail chutes are used in some buildings to collect and store the occupants' mail. A notable example is the Asia Insurance Building.
  • Escape chutes are used and proposed for use in evacuation of mining equipment and high-rise buildings.[4][5]
  • Construction chutes are used to safely remove rubble and similar demolition materials and waste from taller buildings. These temporary structures typically consist of a chain of cylindrical or conical plastic tubes, each fitted into the top of the one below and tied together, usually with a strong metal chain. Together, they form a long flexible tube, which is hung down the side of the building. The lower end of this tube is placed over a skip or other receptacle, and waste materials are dropped from the top. Heavy duty steel chutes may also be used when the waste being deposited is heavy duty and in cases of particularly taller buildings.

An elevator is not a chute, as it is not moved under gravity.

  • Home laundry chute
    Home laundry chute
  • Garbage chute
    Garbage chute
  • Waste incinerator chute, no longer in use
    Waste incinerator chute, no longer in use
  • Mail chute
    Mail chute
  • Construction chute
    Construction chute
  • Circular garbage chute
    Circular garbage chute

Chutes in transportation

[edit]

Goust, a hamlet in southwestern France, is notable for its mountainside chute that is used to transport coffins.[6][7]

Chutes are also found in:

References

[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

Chute (gravity)

View on Grokipedia
from Grokipedia
A chute is a vertical or inclined plane, channel, or passage through which objects are moved by means of gravity.[1] These can occur naturally, such as geological formations in mountains or riverbeds that channel water, snow, or debris, or be engineered systems designed for specific purposes. Engineered gravity chutes, often called refuse or laundry chutes, are integrated into multi-story buildings to transport materials like waste, linens, or construction debris from upper floors to a collection area at the base, relying solely on gravity.[2] They typically feature intake openings with self-closing doors on each floor, leading to a smooth-walled conduit for safe descent without mechanical aid.[3] Common applications of engineered chutes include refuse systems in high-rise residential and commercial buildings, consolidating waste into basement compactors and reducing manual transport via stairs or elevators.[4] Laundry chutes channel soiled items to processing areas in hotels and hospitals, while temporary debris chutes aid construction site cleanup.[5] Gravity chutes for refuse disposal emerged in the late 19th century, evolving from basic drops to sophisticated systems; early designs often included basement incinerators, which were phased out in the 1970s due to air quality regulations.[6] Modern engineered chutes use durable, non-combustible materials such as galvanized steel or concrete to resist impacts and fires, complying with building codes like the International Building Code (referencing NFPA 82) that require minimum diameters of 24 inches (610 mm), fire-rated enclosures, and self-latching doors.[7][8] These standards ensure safety by limiting fire spread and structural risks, while ventilation features address odors and pests for hygiene. Benefits encompass improved efficiency, lower labor costs, and reduced injury from heavy loads, establishing them as essential in global urban high-rises.[1]

Definition and Principles

Definition

A gravity chute is a vertical or steeply inclined channel, passage, or trough designed to transport objects, materials, or fluids from a higher to a lower elevation solely by the action of gravitational force, without any mechanical assistance or propulsion.[9] This structure facilitates the controlled descent of items such as bulk solids, liquids like water, or even logs in industrial or natural settings, relying on the incline to convert potential energy into kinetic motion.[10] Key characteristics of gravity chutes include surfaces that are typically smooth or lined with low-friction materials, such as steel, plastic, or rubber, to reduce resistance and ensure efficient flow.[11] Their cross-sections vary to suit specific applications, commonly rectangular for straight industrial transfers or circular for spiral designs that minimize turbulence.[12] Lengths range from a few meters in engineered systems, like building laundry chutes, to several kilometers in natural formations, allowing scalability across contexts.[1] The term "chute" derives from the Old French "cheoite" or "cheute," meaning a fall or rapid descent, rooted in the verb "cheoir" (to fall), which traces back to Latin "cadere."[13] It entered English in the early 18th century, initially describing waterfalls or steep river descents before extending to both natural and artificial gravity-driven passages by the 19th century.[14] Gravity chutes differ from recreational slides, which prioritize human enjoyment with curved paths and padding, and from powered conveyors, which employ motors or belts for active transport rather than passive gravitational pull.[15][16]

Physical Principles

The primary force driving motion in a gravity chute is gravity, acting downward with magnitude $ F_g = mg $, where $ m $ is the mass of the object and $ g \approx 9.81 , \mathrm{m/s^2} $ is the acceleration due to gravity on Earth's surface. This force is opposed by kinetic friction, $ F_f = \mu_k N $, where $ \mu_k $ is the coefficient of kinetic friction and $ N $ is the normal force exerted by the chute surface on the object. For an inclined chute, the normal force is $ N = mg \cos \theta $, with $ \theta $ denoting the angle of inclination from the horizontal. The net acceleration down the chute for a sliding object is given by $ a = g (\sin \theta - \mu_k \cos \theta) ,assumingconstantfrictionandnootherresistances.Thisequationarisesfromresolvingthegravitationalforceintocomponentsparallel(, assuming constant friction and no other resistances. This equation arises from resolving the gravitational force into components parallel ( mg \sin \theta )andperpendicular() and perpendicular ( mg \cos \theta )totheincline,withfrictionsubtractingfromtheparallelcomponent.Forverticalchutes() to the incline, with friction subtracting from the parallel component. For vertical chutes ( \theta = 90^\circ $), $ \cos \theta = 0 $, so acceleration simplifies to $ a = g $ if wall friction is negligible, though in practice, contact with chute walls introduces frictional effects that reduce acceleration. From an energy perspective, the object's initial gravitational potential energy $ mgh $, where $ h $ is the vertical height of descent, converts to kinetic energy $ \frac{1}{2} mv^2 $ at the bottom, minus work done against friction. The frictional work over the chute length $ l = h / \sin \theta $ is $ W_f = \mu_k mg \cos \theta \cdot l = \mu_k mgh \cot \theta $, leading to the exit velocity $ v = \sqrt{2gh (1 - \mu_k \cot \theta)} $ for cases where $ \tan \theta > \mu_k $ (ensuring net downhill motion).[17] Additional losses from air resistance become relevant for high-speed or long descents but are typically secondary to surface friction in enclosed chutes. Several factors influence the descent rate in gravity chutes. A steeper incline ($ \theta $ closer to $ 90^\circ $) increases the parallel gravity component, yielding faster acceleration and higher exit speeds. Surface materials affect $ \mu_k $; for example, low-friction linings such as ultra-high-molecular-weight polyethylene (UHMW-PE) yield $ \mu_k \approx 0.1-0.2 $ for many solids against steel surfaces, reducing frictional opposition compared to dry steel ($ \mu_k \approx 0.4 )orroughermaterialslike[concrete](/page/Concrete)() or rougher materials like [concrete](/page/Concrete) ( \mu_k \approx 0.6 $).[18][19] Load type also plays a role: discrete solid objects follow the above sliding dynamics, while granular materials exhibit collective flow behaviors influenced by particle size and packing, and fluids may approximate inviscid descent at low viscosities.

Natural Chutes

Geological Formation

Natural chutes primarily form through erosional processes driven by water, wind, or glacial action, which carve steep incisions into rock or soil over extended periods. Water erosion, often initiated by waterfalls or seasonal streams, progressively deepens and widens channels by exploiting weaknesses in the landscape, creating steep gradients that facilitate gravitational flow. Wind contributes in arid environments by abrading surfaces and transporting loose material, while glacial action in mountainous regions scours bedrock through the movement of ice masses loaded with debris. These processes collectively shape chutes as efficient pathways for material transport under gravity.[20][21] Two prominent types of natural chutes emerge from these erosional dynamics: rock chutes, resulting from differential erosion in sedimentary layers where softer materials weather faster than surrounding harder strata, forming narrow, steep channels; and avalanche chutes, which develop in mountainous terrain through repeated scouring by snow, ice, and rockfall, often aligned with topographic lows and lithologic weaknesses. Key mechanisms include hydraulic action, where water pressure dislodges particles from cracks; abrasion, involving the grinding of surfaces by sediment-laden flows; and chemical weathering, which dissolves minerals in softer rocks, accelerating incision. These processes operate synergistically, with gravity enhancing downslope material removal.[22][23][20] Formation timescales for natural chutes typically span thousands to millions of years, depending on the intensity of erosional agents and substrate resistance, with glacial and fluvial processes often requiring millennia to establish mature features. Climate plays a pivotal role, as wetter regions experience accelerated water-based erosion due to higher precipitation volumes. Recent analyses using satellite imagery have revealed chute evolution accelerating in response to climate change-induced increases in extreme precipitation events, leading to enhanced gully and chute incision rates globally.[20][24][25]

Notable Examples

In the southwestern United States, slot canyons in Arizona, such as Antelope Canyon on Navajo Nation land, exemplify narrow gravitational chutes carved by flash floods over millennia, with passages typically 1-3 meters wide and depths reaching up to 40 meters in the upper sections, though some deeper variants exceed 100 meters in related formations like those in Zion National Park.[26][27] These chutes result from episodic high-velocity water flows eroding soft Navajo sandstone, creating sinuous channels that channel gravity-driven water during rare but intense monsoon events. Across the European Alps, avalanche chutes serve as steep, natural snow channels that direct gravitational slides away from populated areas, particularly in the Swiss Alps where such features have been monitored for safety since the early 19th century through initial earthen barriers and later systematic observation by forestry departments.[28] For instance, chutes in regions like the Valais canton prevent snow buildup by funneling avalanches into contained paths, with modern tracking by the WSL Institute for Snow and Avalanche Research building on historical records dating back to the 1800s.[29] Natural chutes hold ecological significance as wildlife corridors, facilitating animal migration and genetic exchange in fragmented landscapes; for example, slot canyons in Arizona provide sheltered pathways for species like bighorn sheep and reptiles to traverse arid terrains, enhancing biodiversity connectivity.[30] They also pose hazards, including flash flood risks that can rapidly fill narrow channels, as evidenced by deadly events in Antelope Canyon where sudden water surges have trapped hikers due to the chutes' steep, enclosed geometry.[31] Culturally, these formations are vital indigenous sites, such as Antelope Canyon, revered by the Navajo as a sacred place symbolizing the flow of life and ancestral stories, with access guided by tribal protocols to preserve spiritual integrity.[32] Recent climate impacts have amplified chute activity in the Himalayas, where post-2020 shifts in monsoon patterns—driven by warming—have increased intense rainfall and glacier melt, accelerating erosion and forming or deepening gravitational chutes in regions like Uttarakhand, heightening landslide and flood vulnerabilities. In 2024, a glacial lake outburst flood (GLOF) in Nepal's Himalayas further illustrated this, with accelerated glacial melt contributing to new erosional features and increased flood risks as of 2025.[33][34][35]

Engineered Chutes

Architectural Applications

Garbage and laundry chutes serve as essential vertical shafts in high-rise buildings, typically spanning 10 to 50 stories, to transport waste, recyclables, and linens via gravity from upper floors to centralized collection areas at ground level. These systems enhance sanitation and efficiency in urban environments by eliminating the need for manual carrying down stairwells or elevators. Garbage chutes are designed to handle bulkier items like household refuse, while laundry chutes focus on lighter textiles, often featuring smoother interiors to prevent snags. Common materials include 16-gauge aluminized steel or stainless steel for durability and fire resistance, with galvanized steel used in some installations to prevent corrosion; PVC linings may be applied in laundry variants for reduced friction during descent.[36][37][38] In the United States, design and installation of these chutes adhere to NFPA 82, the Standard on Incinerators and Waste and Linen Handling Systems and Equipment, which specifies minimum fire protection measures to mitigate risks in multi-story structures, as referenced in the International Building Code (IBC). Key requirements include automatic sprinklers integrated into the chute enclosure to suppress fires at intake and discharge points. Chutes must also terminate in fire-rated rooms with at least two-hour resistance, and standard dimensions often feature circular diameters of 0.61 to 1 meter (approximately 24 to 40 inches), balancing capacity with structural integration. These standards ensure safe operation, with typical garbage chute diameters around 24 inches (610 mm) for residential high-rises.[39][40][41] The integration of chutes into architecture originated in the late 19th century amid escalating sanitation crises in densely populated cities like New York, where tenement overcrowding led to overflowing streets and health epidemics. Early modern garbage chutes appeared in urban multi-family buildings around this period, evolving from rudimentary waste disposal methods to structured systems that centralized collection and reduced public health hazards; the 1901 Tenement House Act addressed sanitation through required courtyards for garbage disposal, marking a shift toward engineered solutions for vertical waste management in growing metropolises.[42][43][44] Emergency chutes represent another architectural application, providing swift evacuation routes in crises such as fires. These inflatable escape chutes, deployable from building facades or ship decks in under 30 seconds, consist of flame-retardant fabric tubes that guide occupants to safety at controlled speeds, often capable of evacuating up to 700 persons in 30 minutes on vessels. Unlike permanent waste systems, they prioritize rapid, one-time use and are stored compactly until activated.[45][46][47] Post-2020 sustainability trends have influenced chute design in green buildings, emphasizing recyclable and low-impact materials to support circular economy goals. Manufacturers have introduced systems using recycled steel or composite alloys, reducing embodied carbon by up to 30% compared to virgin metals, while integrating features like modular components for easier end-of-life recycling. These advancements align with broader LEED certifications, promoting resource efficiency without compromising safety or functionality.[48][49][50]

Transportation and Industrial Uses

In transportation and industrial settings, gravity chutes facilitate the efficient loading and unloading of bulk materials into ships and railcars, particularly for commodities like grain and coal. These systems often incorporate adjustable gates or valves to regulate flow rates, typically ranging from 100 to 500 tons per hour depending on the material and equipment design.[51] For instance, railcar flood-loading chutes can handle coal at capacities up to 8,000 tons per hour, minimizing spillage and optimizing throughput in port and rail operations.[52] In mining operations, ore chutes within vertical shafts enable the controlled descent of extracted materials, with typical shaft depths reaching 60 to 100 meters and diameters of 1.5 to 2.8 meters to accommodate large lumps up to one-fifth of the shaft size.[53] Similarly, in logging, log flumes serve as gravity-assisted channels that redirect felled timber downhill over distances of several miles, using water flow to transport logs from remote forest sites to sawmills or railheads.[54] Airport baggage handling employs sloped chute systems, often integrated with conveyor belts, to feed luggage into aircraft holds at inclines of 15 to 20 degrees for safe and efficient loading.[55] These gravity-fed or roller-assisted chutes connect to broader conveyor networks, allowing seamless transfer from sorting areas to belt loaders positioned at the aircraft.[56] Safety features in industrial chutes include dust suppression systems, such as water mist or chemical sprays, to capture airborne particles and mitigate explosion risks from combustible materials like coal or grain dust.[57] Under OSHA regulations, fall protection is required for elevations of 4 feet (1.2 meters) or more above lower levels, mandating guardrails or personal arrest systems around chute openings to prevent worker falls.[58] The use of gravity chutes in industrial assembly lines evolved significantly in the 20th century, with Ford Motor Company adopting them in the 1920s to enable parts descent along multi-level production floors, complementing conveyor systems for streamlined Model T assembly.[59] Recent automation trends, aligned with Industry 4.0 principles since around 2015, incorporate sensor-controlled chutes in logistics to monitor flow, detect blockages, and enable real-time adjustments via integrated IoT devices and automated alerts.[60] These smart systems optimize material handling in bulk operations by tracking inventory and preventing downtime through predictive maintenance.[61]

References

  1. Chutes Selection Guide: Types, Features, Applications - GlobalSpec
  2. Waste Disposal via Chute Systems | Modus Engineering
  3. Definition of Rubbish Chutes
  4. Trash Chutes and Laundry Chutes 101 for Commercial Buildings
  5. https://hodchutes.com/big-chutes-and-trash-chutes-to-make-life-easier
  6. Residential Building Context - Zero Waste Design Guidelines
  7. Refuse Chute Enclosures - UpCodes
  8. 2009 International Building Code (IBC) - 708.13 Refuse and laundry ...
  9. What Is a Chute?
  10. CHUTE Definition & Meaning - Dictionary.com
  11. Definition of chute - Mindat
  12. The Basics of Gravity Chute Conveyors: a Beginner's Guide
  13. Spouts, chutes, and transitions: Gravity flow design is critical ... - IMEG
  14. CHUTE Definition & Meaning - Merriam-Webster
  15. A trash “chute” or “shoot”? - The Grammarphobia Blog
  16. Powered Conveyors vs Gravity Conveyors: Which Do You Need?
  17. The Difference Between Gravity and Power Conveyors
  18. Friction - Coefficients for Common Materials and Surfaces
  19. 5 Weathering, Erosion, and Sedimentary Rocks - OpenGeology
  20. How Glaciers Change the Landscape (U.S. National Park Service)
  21. Formation of low-gradient bedrock chutes by dry rockfall on ...
  22. (PDF) Lithologic, Structural, and Topographic Influences on Snow ...
  23. Land use and climate change impacts on global soil erosion ... - PNAS
  24. Estimating Gully Erosion Induced by Heavy Rainfall Events ... - MDPI
  25. Niagara Falls Facts | Geology Facts & Figures - Niagara Parks
  26. Deglaciation and Formation of a Knickpoint: Niagara Falls
  27. Natural Phenomenon - Niagara Falls National Heritage Area
  28. What Actually is Antelope Canyon?
  29. Exploring Lower Antelope Canyon Geology - Ken's Tours
  30. History of avalanche protection
  31. Analysing avalanche events
  32. 5 Ways Corridors Help Wildlife Survive and Thrive
  33. Flash Flood - Antelope Canyon, Lake Powell - Climb Utah
  34. Antelope Canyon in Arizona ℹ️ This slot canyon was carved by ...
  35. Is climate change turning India's Himalayas into a disaster zone?
  36. High Mountain Asia's shrinking glaciers linked to monsoon changes
  37. Wilkinson® Trash Chutes
  38. Internal Steel Trash & Laundry Chutes for Hospitals, Apartments ...
  39. [PDF] chute-specifications.pdf - Metropolitan Compactor
  40. NFPA Waste & Linen Chute Standards: Compliance & Maintenance
  41. [PDF] NFPA 82, Standard on Incinerators and Waste and Linen Handling ...
  42. The 19th-Century Night Soil Men Who Carted Away America's Waste
  43. THE EARLY TENEMENTS OF NEW YORK—DARK, DANK, AND ...
  44. https://hodchutes.com/construction-garbage-chutes-and-trash-chutes
  45. Single Entry, Multi Entry, Portable Chutes - Fire Escape Chute
  46. Ship marine evacuation slide
  47. Solas Emergency Escape Marine Evacuation System with Slide Chute
  48. Trash Chute Systems Analysis 2025 and Forecasts 2033
  49. Garbage Chutes & Green Building Initiatives | Kapella
  50. Global Trash Chute Market Size, Trends, Share 2025 - 2034
  51. [PDF] Full Line Product Brochure - Dust Control and Loading Systems
  52. Telescopic Loading Chutes - HMA Group
  53. The Design of Ore Pass Chutes - CKIT
  54. America's Last Log Flume - Amusing Planet
  55. [PDF] Baggage Handling Systems - Daifuku Airport Technologies
  56. Airport Conveyor Baggage Chute - Telford Designs
  57. Dust Suppression & Control | Benetech, Inc.
  58. https://www.osha.gov/laws-regs/regulations/standardnumber/1910/1910.28
  59. [PDF] Ford Motor Company Assembly Plant
  60. https://www.binmaster.com/news/plugged-chutes.html
  61. Intelligent Sensors for Reliable Bulk Solids Handling - BulkInside
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