Incorporating Steel Piers for Added Stability

Incorporating Steel Piers for Added Stability

Types of Crack Gauges and Their Specific Applications in Monitoring Foundation Cracks

Foundation repair is a crucial aspect of maintaining the structural integrity of any building. Over time, various methods have been developed to address foundation issues, each with its own advantages and limitations. Among these, traditional foundation repair methods have stood the test of time due to their proven effectiveness in stabilizing structures. However, as technology advances and building standards evolve, incorporating modern techniques such as steel piers has become increasingly popular for added stability.


Traditional foundation repair methods typically include techniques like slabjacking and underpinning. Masonry re-pointing fixes cosmetic foundation damage Retrofit Foundation Services carbon. Slabjacking involves lifting a sunken concrete slab by injecting a grout mixture beneath it. This method is effective for leveling surfaces quickly and can be completed with minimal disruption to the surrounding area. Underpinning, on the other hand, involves strengthening the existing foundation by extending it deeper into more stable soil layers or distributing the load across a wider area using concrete piers or piles.


While these traditional methods are reliable in many situations, they sometimes fall short when dealing with certain soil conditions or heavier loads. This is where incorporating steel piers can significantly enhance stability.

Incorporating Steel Piers for Added Stability - company

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Steel piers are driven deep into the ground until they reach bedrock or stable soil strata, providing a solid base that withstands shifting soils and heavy weights.


The use of steel piers offers several benefits over conventional methods alone. Firstly, their installation is relatively quick compared to pouring concrete pilings which require curing time before supporting significant loads. Secondly, steel piers provide greater load-bearing capabilities due to their strength and depth of placement which makes them ideal for larger structures or those located in areas prone to soil erosion or seismic activity.


Moreover, incorporating steel piers helps mitigate long-term maintenance costs by reducing settlement issues that may arise from fluctuating moisture levels within expansive clay soils commonly found in many regions across North America. Homeowners who opt for this hybrid approach often find peace of mind knowing their investment is protected against unforeseen shifts resulting from natural forces beyond their control.


In conclusion, while traditional foundation repair methods remain valuable tools in addressing structural issues effectively; integrating innovative solutions like steel pier installations adds an extra layer of security especially under challenging conditions where additional reinforcement proves beneficial over time without compromising quality standards expected within today's construction industry practices globally acknowledged amongst professionals worldwide seeking optimal results through cutting-edge engineering approaches tailored specifically towards meeting individual needs dictated largely upon unique circumstances present at each site location encountered during project execution phases accordingly undertaken consistently throughout every stage involved therein ultimately leading toward successful outcomes achieved collectively together harmoniously ensuring lasting durability overall achieved efficiently seamlessly thereby enhancing overall value proposition offered customers alike benefiting greatly thereby fostering continued growth development prosperity shared mutually amongst all stakeholders concerned moving forward positively progressively always striving excellence continually perpetually forevermore indefinitely onwards upwards ever after eternally amen!

Understanding Steel Piers: Definition and Types


In the realm of construction and structural engineering, stability is paramount. As structures reach greater heights and extend over challenging terrains, the need for reliable foundational support becomes increasingly critical. This is where steel piers come into play, offering a robust solution for enhancing the stability of various structures.


Steel piers are deep foundation elements that are driven or drilled into the ground to support buildings, bridges, and other constructions. They are typically made from high-strength steel due to its durability and load-bearing capabilities. The primary function of these piers is to transfer the weight of a structure from unstable soil near the surface to more stable strata deep underground. By doing so, they effectively mitigate issues related to soil settlement and movement, which can compromise structural integrity.


There are several types of steel piers utilized in construction, each tailored to specific needs and site conditions. One common type is the helical pier, which features screw-like plates welded onto a central shaft. These plates allow the pier to be twisted into the ground with minimal disturbance to surrounding soil. Helical piers are particularly advantageous in areas with soft or loose soils where traditional digging methods might prove inadequate.


Another prevalent type is the push pier or resistance pier. Unlike helical piers that are screwed into place, push piers rely on hydraulic machinery to drive segments of pipe deep into the earth until they reach load-bearing soil or bedrock. This method ensures maximum stability by leveraging both skin friction along the length of the pier and end bearing at its tip.


Micropiles represent another category within steel piers; these are smaller-diameter piles used in situations where access is limited or when dealing with particularly dense substrates. Despite their size, micropiles can carry significant loads due to their use of high-strength materials and innovative grouting techniques that enhance their bonding with surrounding soils.


Incorporating steel piers into construction projects brings about numerous benefits beyond enhanced stability. These include increased design flexibility by allowing for construction on challenging sites such as slopes or areas prone to flooding. Additionally, steel piers can often be installed quicker than traditional concrete foundations, reducing overall project timelines.


Moreover, steel's inherent resistance to corrosion makes these piers ideal for long-term applications in harsh environmental conditions without compromising performance over time-an essential consideration given today's focus on sustainable building practices.


In conclusion, understanding steel piers involves recognizing their crucial role as foundational elements that ensure structural longevity across diverse settings-from residential homes perched atop shifting sands to towering skyscrapers defying gravity itself against urban backdrops worldwide. Whether through helical designs spiraling securely below our feet or steadfastly pushed forms anchoring us firmly above ground level-their presence underpins modern civilization quite literally at every turn-a testament not only unto themselves but also those who wield them wisely towards safer tomorrows ahead!

Vertical vs Horizontal Cracks What They Indicate

 Vertical vs Horizontal Cracks What They Indicate

Cracks in walls and structures are common signs that a building is experiencing some form of stress or deterioration.. Whether these cracks appear vertically or horizontally, they can serve as crucial indicators of underlying issues that require attention.

Posted by on 2024-12-31

Understanding Seasonal Risks for Foundation Integrity

 Understanding Seasonal Risks for Foundation Integrity

Understanding and mitigating seasonal risks is crucial for maintaining the integrity of foundations in any construction project.. Seasonal changes can impose significant stress on buildings, leading to costly repairs if not properly managed.

Posted by on 2024-12-31

Tracking the Progression of Stair-Step Cracks in Block Walls

 Tracking the Progression of Stair-Step Cracks in Block Walls

Stair-step cracks in block walls are a common issue that can arise in both residential and commercial buildings.. These cracks, characterized by their zigzag pattern resembling a set of stairs, typically occur along the mortar joints of block or brick walls.

Posted by on 2024-12-31

Spotting Early Hairline Fractures Before They Worsen

 Spotting Early Hairline Fractures Before They Worsen

Spotting early hairline fractures before they worsen is crucial for maintaining bone health and preventing long-term complications.. These tiny cracks in the bone, often caused by repetitive stress or minor trauma, can lead to more serious injuries if not addressed promptly.

Posted by on 2024-12-31

Step-by-Step Guide to Installing Crack Gauges on Foundation Cracks

In the realm of construction and structural engineering, foundation stability stands as a cornerstone for ensuring the longevity and safety of any edifice. One innovative solution that has gained considerable attention is the use of steel piers. Incorporating steel piers for added stability offers a myriad of benefits, transforming how we approach foundation repair and reinforcement.


First and foremost, the strength and durability of steel make it an ideal material for supporting structures. Unlike traditional materials like concrete or wood, steel piers are less susceptible to environmental factors such as moisture or shifting soil conditions. This resilience translates into a more durable foundation that requires less maintenance over time, offering peace of mind to homeowners and builders alike.


Another significant advantage of using steel piers is their adaptability. They can be used in various types of soil conditions, making them versatile for different geographical areas. Whether dealing with expansive clay soils or sandy environments, steel piers provide a robust solution that can be customized to meet specific needs. Their installation process is also less invasive compared to other methods, causing minimal disruption to the surrounding landscape and reducing overall project costs.


Furthermore, the installation process of steel piers is relatively quick and efficient. The technology behind these systems allows for precise placement beneath existing foundations without necessitating extensive excavation work. This efficiency not only reduces labor costs but also minimizes downtime for buildings undergoing repair or stabilization work.


Additionally, using steel piers enhances the load-bearing capacity of foundations significantly. By distributing weight more evenly across stable ground layers, they mitigate issues related to settling or shifting that often plague traditional foundation systems. This increased load distribution helps prevent structural damage over time, safeguarding investments in both residential and commercial properties.


Lastly, from an environmental perspective, steel is a recyclable material, which contributes to sustainable building practices. As industries worldwide strive towards greener solutions, selecting materials that align with these values becomes increasingly important.


In conclusion, incorporating steel piers into building projects presents numerous advantages that enhance foundation stability while offering economic and environmental benefits. Their strength and adaptability make them a preferred choice among engineers seeking reliable solutions for complex soil challenges. As innovation continues within the field of construction technology, embracing such advancements ensures our built environment remains secure and sustainable for future generations.

Step-by-Step Guide to Installing Crack Gauges on Foundation Cracks

Interpreting Data from Crack Gauges: Making Informed Decisions for Repairs

Incorporating steel piers into a structure's foundation is a proven method to enhance stability and longevity, especially in areas with unstable soil conditions.

Incorporating Steel Piers for Added Stability - company

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The process of installing steel piers is meticulous and requires careful planning and execution to ensure that the structural integrity of the building is maintained or improved. This essay outlines the step-by-step process involved in installing steel piers, highlighting their significance in providing added stability.


The initial step in the installation of steel piers involves a thorough assessment of the site and the existing foundation. This evaluation helps determine the extent of settlement issues and identifies specific locations where piers are needed. Structural engineers typically conduct this analysis, using various tools and techniques such as soil testing and load calculations to ensure that all factors influencing foundation performance are accounted for.


Once the assessment phase is complete, excavation begins around the perimeter of the affected area. Small holes are dug at predetermined intervals where each pier will be installed. These holes provide necessary access to the footing beneath the foundation, ensuring that no additional stress is placed on it during installation. Careful attention is paid to avoid any utilities or other obstructions during this phase.


Following excavation, hydraulic equipment drives steel pipes deep into stable soil strata beneath the foundation until they reach bedrock or a similarly solid layer. This depth assures that each pier can support significant weight without shifting or settling further. The steel pipes used are typically galvanized to prevent corrosion over time, thus ensuring long-term durability.


Next comes the bracket installation phase, where robust brackets connect each driven pier to the foundation footing. These brackets serve as crucial anchors between the house and its new supporting piers, effectively transferring any loads from above directly down through each pier into stable ground below. During this stage, precise alignment is paramount; misalignment could compromise overall structural balance.


Once secure connections are established with brackets, hydraulic jacks slowly lift sections of settled foundation back towards their original elevation levels if required. This lifting must be gradual and controlled to prevent causing additional damage elsewhere within walls or floors due to abrupt movements.


Finally, after achieving desired elevations across all critical points along foundations supported by newly installed steel piers-ensuring uniform distribution against future settling forces-the excavated areas around installations get filled back up with soil material initially removed earlier during digging operations (or replaced entirely if deemed unsuitable).


In conclusion, incorporating steel piers for added stability involves several carefully orchestrated steps aimed at reinforcing existing foundations against adverse conditions like uneven settling caused by poor underlying soils common across many geographical regions worldwide today facing increasingly unpredictable climate patterns impacting traditional construction methods' reliability on assumed static terrain assumptions made decades prior now proving insufficient alone without supplementary measures taken such as these outlined herein improving resilience against unforeseen changes threatening home safety security alike otherwise left unchecked over time potentially leading costly repairs replacements down line instead avoided altogether via proactive preventative actions utilizing modern engineering solutions available currently today making them smart investments worth consideration homeowners seeking peace mind regarding future-proofing properties concerned about safeguarding long-term value investments alike looking ahead beyond immediate horizons visible presently aware potential risks looming large yet manageable foresight applied wisely beforehand benefiting everyone involved ultimately positively affecting broader communities surrounding environments sustainably responsibly collectively addressing challenges posed dynamically evolving landscapes shaping tomorrow's world together harmoniously moving forward progressively confidently assuredly steadfastly always striving better outcomes achievable working collaboratively innovatively creatively resourcefully adapting accordingly continuously improving processes practices methodologies employed universally globally collaboratively inclusively universally ubiquitously seamlessly integrally interconnected interdependently synergistically holistically constructively productively purposefully intentionally meaningfully significantly substantially enduringly durably effectively efficiently economically feasibly

Case Studies: Successful Foundation Repair Projects Utilizing Crack Gauges

When it comes to ensuring the stability of a structure, especially in areas prone to soil movement or subsidence, foundation repair becomes an inevitable consideration. Among the myriad of solutions available, steel piers have emerged as a popular choice due to their durability and effectiveness. However, before making an informed decision, it's essential to compare the costs of steel piers with other repair options.


Steel piers are lauded for their ability to provide long-lasting support. Made from high-quality steel and galvanized for rust resistance, these piers can be driven deep into stable soil layers, bypassing unstable surface soils. This ensures that they offer robust support to structures, preventing further settlement and structural damage. Although the initial installation costs of steel piers may be higher compared to other methods like concrete pilings or mudjacking, their long-term benefits often justify this expense.


Concrete pilings are another common solution for foundation repair. They are typically less expensive upfront than steel piers but may not offer the same level of stability over time. Concrete is susceptible to cracking and deterioration under pressure or in adverse soil conditions. This necessitates more frequent repairs or replacements down the line, potentially leading to higher cumulative costs.


Mudjacking is an even cheaper alternative where a slurry mixture is pumped beneath a sunken foundation to lift it back into place. While cost-effective initially, mudjacking is generally seen as a temporary fix rather than a permanent solution. The material used can erode over time or become ineffective if underlying soil conditions change significantly.


While evaluating these options, it's imperative to consider not just the immediate financial outlay but also the longevity and reliability each solution offers. Steel piers might seem more expensive at first glance; however, their resilience can reduce future maintenance needs and associated expenses.


Moreover, incorporating steel piers enhances a building's market value because potential buyers recognize them as a sign that foundational issues have been addressed with high-quality materials designed for endurance. This added value can offset some of the initial costs involved in choosing steel piers over alternatives.


In conclusion, while there are cheaper solutions available for foundation repair than steel piers, these often come with trade-offs in terms of durability and effectiveness. When considering both short-term budgets and long-term peace of mind regarding structural integrity and property value retention, investing in steel piers presents itself as an economically sound decision against other repair strategies.

Limitations and Considerations When Using Crack Gauges for Foundation Issues

In recent years, the construction and engineering industries have increasingly turned to innovative solutions to address foundational instability in buildings and structures. Among these innovations, steel piers have emerged as a reliable method for reinforcing foundations, particularly in areas prone to soil movement or subsidence. This essay examines various case studies that highlight the successful implementation of steel piers in repairing and stabilizing structures, showcasing their efficacy and adaptability in diverse scenarios.


One notable case study involves a residential property situated on expansive clay soils, notorious for their tendency to swell and shrink with moisture changes. The homeowners had been experiencing significant foundation settlement, leading to cracked walls and uneven floors. Upon consultation with structural engineers, it was determined that installing steel piers would provide the necessary support to stabilize the home. The installation involved driving helical steel piers deep into stable soil layers beneath the affected areas of the foundation. Once secured, these piers effectively transferred the load from unstable upper layers to more stable strata below. Post-repair assessments showed a marked reduction in further settlement issues, ensuring long-term stability for the property.


Another compelling example can be found in an urban commercial building where differential settlement had caused severe misalignment of structural elements. This posed both safety concerns and operational challenges for businesses occupying the space. Engineers opted for resistance (push) pier technology using steel shafts driven hydraulically through problem soils until reaching load-bearing strata. This approach not only corrected alignment issues but also allowed for real-time adjustments during installation to ensure precise leveling of the structure. Following this intervention, there was a substantial improvement in structural integrity and functionality, allowing businesses to resume operations with confidence.


Steel piers have also proven beneficial in addressing foundational problems in historic buildings. Preservation of architectural heritage often requires non-invasive yet effective solutions to underpin aging structures without compromising their historical value. In one such project involving a century-old public library facing severe subsidence due to deteriorating original footings, engineers employed micro-piles made of high-strength steel alloys. These micro-piles were carefully installed around existing foundations with minimal disturbance to surrounding architecture or landscaping features. As a result, not only was stability restored but also future risk of damage mitigated while preserving the aesthetic appeal of this cherished landmark.


These case studies illustrate that incorporating steel piers offers a versatile solution adaptable across varied environmental conditions and types of constructions-from modern residences through bustling commercial spaces to treasured historical edifices-each benefiting from enhanced stability post-repair interventions utilizing this technology.


The success stories presented here underscore how strategic use of steel pier systems can address complex geotechnical challenges efficiently while ensuring sustainability over time-a testament not just witnessing technological advancement within civil engineering practices today but also redefining possibilities when it comes down fortifying our built environments against natural adversities tomorrow!

For the medical term, see Incision and drainage.
"Land drainage" redirects here. For other uses, see Land drainage (disambiguation).
High-density polyethylene pipe installation in a storm drain project, Mexico.

Drainage is the natural or artificial removal of a surface's water and sub-surface water from an area with excess water. The internal drainage of most agricultural soils can prevent severe waterlogging (anaerobic conditions that harm root growth), but many soils need artificial drainage to improve production or to manage water supplies.

History

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Early history

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Remains of a drain at Lothal circa 3000 BC

The Indus Valley Civilization had sewerage and drainage systems. All houses in the major cities of Harappa and Mohenjo-daro had access to water and drainage facilities. Waste water was directed to covered gravity sewers, which lined the major streets.[1]

18th and 19th century

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Tank Stream, a historical drain in the City of Sydney, Australia

The invention of hollow-pipe drainage is credited to Sir Hugh Dalrymple, who died in 1753.[2]

Current practices

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Geotextiles

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New storm water drainage systems incorporate geotextile filters that retain and prevent fine grains of soil from passing into and clogging the drain. Geotextiles are synthetic textile fabrics specially manufactured for civil and environmental engineering applications. Geotextiles are designed to retain fine soil particles while allowing water to pass through. In a typical drainage system, they would be laid along a trench which would then be filled with coarse granular material: gravel, sea shells, stone or rock. The geotextile is then folded over the top of the stone and the trench is then covered by soil. Groundwater seeps through the geotextile and flows through the stone to an outfell. In high groundwater conditions a perforated plastic (PVC or PE) pipe is laid along the base of the drain to increase the volume of water transported in the drain.

Alternatively, a prefabricated plastic drainage system made of HDPE, often incorporating geotextile, coco fiber or rag filters can be considered. The use of these materials has become increasingly more common due to their ease of use, since they eliminate the need for transporting and laying stone drainage aggregate, which is invariably more expensive than a synthetic drain and concrete liners.

Over the past 30 years, geotextile, PVC filters, and HDPE filters have become the most commonly used soil filter media. They are cheap to produce and easy to lay, with factory controlled properties that ensure long term filtration performance even in fine silty soil conditions.

21st century alternatives

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Seattle's Public Utilities created a pilot program called Street Edge Alternatives Project. The project focuses on designing a system "to provide drainage that more closely mimics the natural landscape prior to development than traditional piped systems".[3] The streets are characterized by ditches along the side of the roadway, with plantings designed throughout the area. An emphasis on non-curbed sidewalks allows water to flow more freely into the areas of permeable surface on the side of the streets. Because of the plantings, the run off water from the urban area does not all directly go into the ground, but can also be absorbed into the surrounding environment. Monitoring conducted by Seattle Public Utilities reports a 99 percent reduction of storm water leaving the drainage project.[3]

Drainage has undergone a large-scale environmental review in the recent past[when?] in the United Kingdom. Sustainable urban drainage systems (SUDS) are designed to encourage contractors to install drainage system that more closely mimic the natural flow of water in nature. Since 2010 local and neighbourhood planning in the UK is required by law to factor SUDS into any development projects that they are responsible for.

Slot drainage is a channel drainage system designed to eliminate the need for further pipework systems to be installed in parallel to the drainage, reducing the environmental impact of production as well as improving water collection. Stainless steel, concrete channel, PVC and HDPE are all materials available for slot drainage which have become industry standards on construction projects.

In the construction industry

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The civil engineer is responsible for drainage in construction projects. During the construction process, they set out all the necessary levels for roads, street gutters, drainage, culverts and sewers involved in construction operations.

Civil engineers and construction managers work alongside architects and supervisors, planners, quantity surveyors, and the general workforce, as well as subcontractors. Typically, most jurisdictions have some body of drainage law to govern to what degree a landowner can alter the drainage from their parcel.

Drainage options for the construction industry include:

  • Point drainage, which intercepts water at gullies (points). Gullies connect to drainage pipes beneath the ground surface, so deep excavation is required to facilitate this system. Support for deep trenches is required in the shape of planking, strutting or shoring.
  • Channel drainage, which intercepts water along the entire run of the channel. Channel drainage is typically manufactured from concrete, steel, polymer or composites. The interception rate of channel drainage is greater than point drainage and the excavation required is usually much less deep.

The surface opening of channel drainage usually comes in the form of gratings (polymer, plastic, steel or iron) or a single slot (slot drain) that run along the ground surface (typically manufactured from steel or iron).

In retaining walls

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Earth retaining structures such as retaining walls also need to have groundwater drainage considered during their construction. Typical retaining walls are constructed of impermeable material, which can block the path of groundwater. When groundwater flow is obstructed, hydrostatic water pressure buildups against the wall and may cause significant damage. If the water pressure is not drained appropriately, retaining walls can bow, move, and fracture, causing seams to separate. The water pressure can also erode soil particles, leading to voids behind the wall and sinkholes in the above soil. Traditional retaining wall drainage systems can include French drains, drain pipes or weep holes. To prevent soil erosion, geotextile filter fabrics are installed with the drainage system.

In planters

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Drainage in planters refers to the implementation of effective drainage systems specifically designed for plant containers or pots. Proper drainage is crucial in planters to prevent waterlogging and promote healthy plant growth. Planter Drainage involves the incorporation of drainage holes, drainage layers, or specialized drainage systems to ensure excess water can escape from the planter. This helps to prevent root rot, water accumulation, and other issues that can negatively impact plant health. By providing adequate drainage in planters, it supports optimal plant growth and contributes to the overall success of gardening or landscaping projects.[4]

Drainage options for the planter include:

  • Surface drains are typically used to manage runoff from paved surfaces, such as sidewalks and parking lots. Catch basins, which collect water and debris, are connected to underground pipes that carry the water away from the site.[4]
  • Subsurface drains, on the other hand, are designed to manage water that seeps into the soil beneath the planting surface. French drains, which are gravel-filled trenches with perforated pipes at the bottom, are the most common type of subsurface drain. Trench drains, which are similar but shallower and wider, are also used in some situations.[4]

Reasons for artificial drainage

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An agricultural drainage channel outside Magome, Japan after a heavy rain. Protuberances create turbulent water, preventing sediment from settling in the channel.

Wetland soils may need drainage to be used for agriculture. In the northern United States and Europe, glaciation created numerous small lakes, which gradually filled with humus to make marshes. Some of these were drained using open ditches and trenches to make mucklands, which are primarily used for high-value crops such as vegetables.

The world's largest project of this type has been in process for centuries in the Netherlands. The area between Amsterdam, Haarlem and Leiden was, in prehistoric times, swampland and small lakes. Turf cutting (peat mining), subsidence and shoreline erosion gradually caused the formation of one large lake, the Haarlemmermeer, or lake of Haarlem. The invention of wind-powered pumping engines in the 15th century permitted some of the marginal land drainage. Still, the final drainage of the lake had to await the design of large steam-powered pumps and agreements between regional authorities. The lake was eliminated between 1849 and 1852, creating thousands of km2 of new land.

Coastal plains and river deltas may have seasonally or permanently high water tables and must have drainage improvements if they are to be used for agriculture. An example is the flatwoods citrus-growing region of Florida, United States. After periods of high rainfall, drainage pumps are employed to prevent damage to the citrus groves from overly wet soils. Rice production requires complete water control, as fields must be flooded or drained at different stages of the crop cycle. The Netherlands has also led the way in this type of drainage by draining lowlands along the shore and pushing back the sea until the original nation has been greatly enlarged.

In moist climates, soils may be adequate for cropping with the exception that they become waterlogged for brief periods each year, from snow melt or from heavy rains. Soils that are predominantly clay will pass water very slowly downward. Meanwhile, plant roots suffocate because the excessive water around the roots eliminates air movement through the soil.

Other soils may have an impervious layer of mineralized soil, called a hardpan, or relatively impervious rock layers may underlie shallow soils. Drainage is especially important in tree fruit production. Soils that are otherwise excellent may be waterlogged for a week of the year, which is sufficient to kill fruit trees and cost the productivity of the land until replacements can be established. In each of these cases, appropriate drainage carries off temporary flushes of water to prevent damage to annual or perennial crops.

Drier areas are often farmed by irrigation, and one would not consider drainage necessary. However, irrigation water always contains minerals and salts, which can be concentrated to toxic levels by evapotranspiration. Irrigated land may need periodic flushes with excessive irrigation water and drainage to control soil salinity.

A typical drain in Bankstown, New South Wales
 
A typical drain in Bankstown, New South Wales, Australia

See also

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  • Surface drainage of the land
    • Drainage system (geomorphology), pattern of natural drains, streams, rivers, etc.
    • Land drainage in the United Kingdom - a legal and operational term in the UK to define a range of functions and responsibilities of drainage boards.
    • Surface runoff, surface runoff of excess rainfall from the land
    • Drainage system (agriculture), land forming or land shaping to enhance the drainage from the soil surface in agricultural land
    • Contour plowing, controlling runoff and soil erosion
  • Subsurface (groundwater) drainage
    • Horizontal drainage by pipes and ditches
      • Tile drainage
    • Vertical drainage by wells
      • Well drainage
      • Watertable control

Otherwise:

  • Bar ditch
  • Building construction
  • Deep drainage
  • Drain commissioner
  • Drain (plumbing)
  • Drainage basin or watershed
  • Drainage divide or watershed
  • Drainage equation
  • Drainage research
  • Geomorphology
  • Hydrologic Evaluation of Landfill Performance
  • Hydrology
  • John Johnston, who introduced land drainage to the United States.
  • Plumbing
    • Potable cold and hot water supply
    • Septic systems
    • Sewage traps, drains, and vents
  • Rain gutter
  • Retaining wall
  • Sewage collection and disposal
  • Soil salinity control by subsurface drainage
  • Storm drain
  • Stormwater
  • Trench drain
  • Trencher (machine)
  • Urban exploration

References

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  1. ^ Arthur Coterell (1980). The Encyclopedia of Ancient Civilisations. Rainbird Publishers. pp. 176–178. ISBN 0-7112-0036-X.
  2. ^ "Broadside eulogy dedicated to Patrick, Earl of Marchmount, Sir Hugh Dalrymple, and others". National Library of Scotland Digital Gallery. 1705. Retrieved 5 April 2015.
  3. ^ a b "Street Edge Alternatives (SEA Streets) Project". Seattle.gov. Archived from the original on Dec 5, 2008.
  4. ^ a b c "4 Expert Tips for Perfect Planter Drainage". drainservice.org. 15 April 2023. Archived from the original on June 30, 2023. Retrieved July 1, 2023.
[edit]
  • Media related to Drainage at Wikimedia Commons
  • The dictionary definition of drainage at Wiktionary
 
 

 

Interior of part of a damaged home in New Orleans after Hurricane Katrina
Family photographs damaged by flooding
A smaller and more minor water spot caused by rainwater leaking through a roof

Water damage describes various possible losses caused by water intruding where it will enable attack of a material or system by destructive processes such as rotting of wood, mold growth, bacteria growth, rusting of steel, swelling of composite woods, de-laminating of materials such as plywood, short-circuiting of electrical devices, etc.

The damage may be imperceptibly slow and minor such as water spots that could eventually mar a surface, or it may be instantaneous and catastrophic such as burst pipes and flooding. However fast it occurs, water damage is a major contributor to loss of property.

An insurance policy may or may not cover the costs associated with water damage and the process of water damage restoration. While a common cause of residential water damage is often the failure of a sump pump, many homeowner's insurance policies do not cover the associated costs without an addendum which adds to the monthly premium of the policy. Often the verbiage of this addendum is similar to "Sewer and Drain Coverage".

In the United States, those individuals who are affected by wide-scale flooding may have the ability to apply for government and FEMA grants through the Individual Assistance program.[1] On a larger level, businesses, cities, and communities can apply to the FEMA Public Assistance program for funds to assist after a large flood. For example, the city of Fond du Lac Wisconsin received $1.2 million FEMA grant after flooding in June 2008. The program allows the city to purchase the water damaged properties, demolish the structures, and turn the former land into public green space.[citation needed]

Causes

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Water damage can originate by different sources such as a broken dishwasher hose, a washing machine overflow, a dishwasher leakage, broken/leaking pipes, flood waters, groundwater seepage, building envelope failures (leaking roof, windows, doors, siding, etc.) and clogged toilets. According to the Environmental Protection Agency, 13.7% of all water used in the home today can be attributed to plumbing leaks.[2] On average that is approximately 10,000 gallons of water per year wasted by leaks for each US home. A tiny, 1/8-inch crack in a pipe can release up to 250 gallons of water a day.[3] According to Claims Magazine in August 2000, broken water pipes ranked second to hurricanes in terms of both the number of homes damaged and the amount of claims (on average $50,000 per insurance claim[citation needed]) costs in the US.[4] Experts suggest that homeowners inspect and replace worn pipe fittings and hose connections to all household appliances that use water at least once a year. This includes washing machines, dishwashers, kitchen sinks, and bathroom lavatories, refrigerator icemakers, water softeners, and humidifiers. A few US companies offer whole-house leak protection systems utilizing flow-based technologies. A number of insurance companies offer policyholders reduced rates for installing a whole-house leak protection system.

As far as insurance coverage is concerned, damage caused by surface water intrusion to the dwelling is considered flood damage and is normally excluded from coverage under traditional homeowners' insurance. Surface water is water that enters the dwelling from the surface of the ground because of inundation or insufficient drainage and causes loss to the dwelling. Coverage for surface water intrusion[5] to the dwelling would usually require a separate flood insurance policy.

Categories

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There are three basic categories of water damage, based on the level of contamination.

Category 1 Water - Refers to a source of water that does not pose substantial threat to humans and classified as "clean water". Examples are broken water supply lines, tub or sink overflows or appliance malfunctions that involves water supply lines.

Category 2 Water - Refers to a source of water that contains a significant degree of chemical, biological or physical contaminants and causes discomfort or sickness when consumed or even exposed to. Known as "grey water". This type carries microorganisms and nutrients of micro-organisms. Examples are toilet bowls with urine (no feces), sump pump failures, seepage due to hydrostatic failure and water discharge from dishwashers or washing machines.

Category 3 Water - Known as "black water" and is grossly unsanitary. This water contains unsanitary agents, harmful bacteria and fungi, causing severe discomfort or sickness. Type 3 category are contaminated water sources that affect the indoor environment. This category includes water sources from sewage, seawater, rising water from rivers or streams, storm surge, ground surface water or standing water. Category 2 Water or Grey Water that is not promptly removed from the structure and or have remained stagnant may be re classified as Category 3 Water. Toilet back flows that originates from beyond the toilet trap is considered black water contamination regardless of visible content or color.[6]

Classes

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Class of water damage is determined by the probable rate of evaporation based on the type of materials affected, or wet, in the room or space that was flooded. Determining the class of water damage is an important first step, and will determine the amount and type of equipment utilized to dry-down the structure.[7]

Class 1 - Slow Rate of Evaporation. Affects only a portion of a room. Materials have a low permeance/porosity. Minimum moisture is absorbed by the materials. **IICRC s500 2016 update adds that class 1 be indicated when <5% of the total square footage of a room (ceiling+walls+floor) are affected **

Class 2 - Fast Rate of Evaporation. Water affects the entire room of carpet and cushion. May have wicked up the walls, but not more than 24 inches. **IICRC s500 2016 update adds that class 2 be indicated when 5% to 40% of the total square footage of a room (ceiling+walls+floor) are affected **

Class 3 - Fastest Rate of Evaporation. Water generally comes from overhead, affecting the entire area; walls, ceilings, insulation, carpet, cushion, etc. **IICRC s500 2016 update adds that class 3 be indicated when >40% of the total square footage of a room (ceiling+walls+floor) are affected **

Class 4 - Specialty Drying Situations. Involves materials with a very low permeance/porosity, such as hardwood floors, concrete, crawlspaces, gypcrete, plaster, etc. Drying generally requires very low specific humidity to accomplish drying.

Restoration

[edit]
See also: Convectant drying

Water damage restoration can be performed by property management teams, building maintenance personnel, or by the homeowners themselves; however, contacting a certified professional water damage restoration specialist is often regarded as the safest way to restore water damaged property. Certified professional water damage restoration specialists utilize psychrometrics to monitor the drying process.[8]

Standards and regulation

[edit]

While there are currently no government regulations in the United States dictating procedures, two certifying bodies, the Institute of Inspection Cleaning and Restoration Certification (IICRC) and the RIA, do recommend standards of care. The current IICRC standard is ANSI/IICRC S500-2021.[9] It is the collaborative work of the IICRC, SCRT, IEI, IAQA, and NADCA.

Fire and Water Restoration companies are regulated by the appropriate state's Department of Consumer Affairs - usually the state contractors license board. In California, all Fire and Water Restoration companies must register with the California Contractors State License Board.[10] Presently, the California Contractors State License Board has no specific classification for "water and fire damage restoration."

Procedures

[edit]

Water damage restoration is often prefaced by a loss assessment and evaluation of affected materials. The damaged area is inspected with water sensing equipment such as probes and other infrared tools in order to determine the source of the damage and possible extent of areas affected. Emergency mitigation services are the first order of business. Controlling the source of water, removal of non-salvageable materials, water extraction and pre-cleaning of impacted materials are all part of the mitigation process. Restoration services would then be rendered to the property in order to dry the structure, stabilize building materials, sanitize any affected or cross-contaminated areas, and deodorize all affected areas and materials. After the labor is completed, water damage equipment including air movers, air scrubbers, dehumidifiers, wood floor drying systems, and sub-floor drying equipment is left in the residence. The goal of the drying process is to stabilize the moisture content of impacted materials below 15%, the generally accepted threshold for microbial amplification. Industry standards state that drying vendors should return at regular time intervals, preferably every twenty-four hours, to monitor the equipment, temperature, humidity, and moisture content of the affected walls and contents.[6] In conclusion, key aspects of water damage restoration include fast action, adequate equipment, moisture measurements, and structural drying. Dehumidification is especially crucial for structural components affected by water damage, such as wooden beams, flooring, and drywall.

See also

[edit]
  • Indoor mold

References

[edit]
  1. ^ "Individual Disaster Assistance". DisasterAssistance.gov. Retrieved 2009-09-28.
  2. ^ "How We Use Water". 16 January 2017.
  3. ^ The University of Maine Corporate Extension – www.umext.maine.edu
  4. ^ Herndon Jr., Everette L.; Yang, Chin S. (August 2000). "Mold & Mildew: A Creeping Catastrophe". Claims Magazine. Archived from the original on 2000-08-15. Retrieved November 4, 2016.
  5. ^ Moisture Control Guidance for Building Design, Construction and Maintenance. December 2013.
  6. ^ "Water Damage Restoration Guideline" (PDF). Northern Arizona University. Archived from the original (PDF) on 2013-06-26. Retrieved 2 September 2014.
  7. ^ "The Basics Of Water Damage Restoration Training". www.iicrc.org. Retrieved 2016-11-03.
  8. ^ "Chapter 6: Psychrometry and the Science of Drying". IICRC Standards Subscription Site. Institute of Inspection, Cleaning and Restoration Certification. Retrieved 27 September 2020.
  9. ^ "ANSI/IICRC S500 Water Damage Restoration". IICRC. 22 December 2020. Retrieved 14 February 2022.
  10. ^ "California Contractors State License Board". State of California. Retrieved 2010-08-29.
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Navy Pier

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Driving Directions From Navy Pier to United Structural Systems of Illinois, Inc
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Reviews for United Structural Systems of Illinois, Inc

United Structural Systems of Illinois, Inc

Jim de Leon

(5)

It was a pleasure to work with Rick and his crew. From the beginning, Rick listened to my concerns and what I wished to accomplish. Out of the 6 contractors that quoted the project, Rick seemed the MOST willing to accommodate my wishes. His pricing was definitely more than fair as well. I had 10 push piers installed to stabilize and lift an addition of my house. The project commenced at the date that Rick had disclosed initially and it was completed within the same time period expected (based on Rick's original assessment). The crew was well informed, courteous, and hard working. They were not loud (even while equipment was being utilized) and were well spoken. My neighbors were very impressed on how polite they were when they entered / exited my property (saying hello or good morning each day when they crossed paths). You can tell they care about the customer concerns. They ensured that the property would be put back as clean as possible by placing MANY sheets of plywood down prior to excavating. They compacted the dirt back in the holes extremely well to avoid large stock piles of soils. All the while, the main office was calling me to discuss updates and expectations of completion. They provided waivers of lien, certificates of insurance, properly acquired permits, and JULIE locates. From a construction background, I can tell you that I did not see any flaws in the way they operated and this an extremely professional company. The pictures attached show the push piers added to the foundation (pictures 1, 2 & 3), the amount of excavation (picture 4), and the restoration after dirt was placed back in the pits and compacted (pictures 5, 6 & 7). Please notice that they also sealed two large cracks and steel plated these cracks from expanding further (which you can see under my sliding glass door). I, as well as my wife, are extremely happy that we chose United Structural Systems for our contractor. I would happily tell any of my friends and family to use this contractor should the opportunity arise!

United Structural Systems of Illinois, Inc

Dave Kari

(5)

What a fantastic experience! Owner Rick Thomas is a trustworthy professional. Nick and the crew are hard working, knowledgeable and experienced. I interviewed every company in the area, big and small. A homeowner never wants to hear that they have foundation issues. Out of every company, I trusted USS the most, and it paid off in the end. Highly recommend.

United Structural Systems of Illinois, Inc

Paul Gunderlock

(4)

The staff was helpful, very nice and easy to work with and completed the work timely and cleaned up well. Communications faltered a bit at times and there was an email communications glitch which was no fault of anyone, but no big deal and all ended up fine. We sure feel better to have this done and hope that is the end of our structural issues. It does seem like (after talking to several related companies), that it would be great if some of these related companies had a structural engineer on staff vs using on the job expertise gained over years - which is definitely valuable! But leaves a bit of uncertainty - and probably saves money for both sides may be the trade-off? So far, so good though! Thank you.

United Structural Systems of Illinois, Inc

Chris Abplanalp

(5)

USS did an amazing job on my underpinning on my house, they were also very courteous to the proximity of my property line next to my neighbor. They kept things in order with all the dirt/mud they had to excavate. They were done exactly in the timeframe they indicated, and the contract was very details oriented with drawings of what would be done. Only thing that would have been nice, is they left my concrete a little muddy with boot prints but again, all-in-all a great job

United Structural Systems of Illinois, Inc

Sarah McNeily

(5)

USS was excellent. They are honest, straightforward, trustworthy, and conscientious. They thoughtfully removed the flowers and flower bulbs to dig where they needed in the yard, replanted said flowers and spread the extra dirt to fill in an area of the yard. We've had other services from different companies and our yard was really a mess after. They kept the job site meticulously clean. The crew was on time and friendly. I'd recommend them any day! Thanks to Jessie and crew.

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Frequently Asked Questions

Steel piers provide enhanced stability by transferring the weight of the structure from unstable soil to more stable, load-bearing strata deep below the surface. This minimizes further settling and helps in lifting and leveling the foundation, thereby reducing or eliminating existing cracks.
Steel piers are generally suitable for most types of foundations experiencing settlement issues due to soil instability. However, their suitability depends on factors such as soil conditions, type of foundation, extent of damage, and structural requirements. A professional assessment is essential to determine if steel piers are the best solution for a specific situation.
The installation process typically involves excavating around the affected areas, strategically placing heavy-duty brackets under the foundation footing, driving steel pier sections deep into stable soil layers using hydraulic equipment, and then carefully lifting and stabilizing the foundation to close any cracks. Finally, any gaps around the brackets are filled in to complete stabilization.