Understanding the Scope of Foundation Repair Guarantees

Understanding the Scope of Foundation Repair Guarantees

The importance of foundation repair services in maintaining the structural integrity and value of residential properties.

Types of Foundation Issues: Common problems that necessitate foundation repair, such as cracks, settlement, and upheaval.


When it comes to understanding the scope of foundation repair guarantees, it's essential to first grasp the common types of foundation issues that might necessitate such repairs. Water pooling around a home signals the need for drainage and foundation repair foundation repair expert service deep foundation. Foundation problems can be a nightmare for homeowners, as they can lead to significant structural damage if left unaddressed. Let's explore some of the typical foundation issues and then delve into what you might expect from a repair guarantee.

One of the most common foundation problems is the appearance of cracks. These can manifest in various ways, such as hairline cracks in the walls, diagonal cracks in the foundation itself, or even cracks in the floor tiles. Cracks often indicate that the foundation is under stress, possibly due to soil movement or settling. Another prevalent issue is settlement, where one section of the foundation sinks lower than the rest, causing an uneven distribution of weight and leading to structural instability. Upheaval is another concern, occurring when the foundation moves upward, often due to expansive soils or water pressure underneath.

Now, let's consider the guarantees typically offered for foundation repair. It's crucial to understand that not all guarantees are created equal, and they can vary significantly between different contractors. A comprehensive foundation repair guarantee should cover both the materials used and the labor involved in the repair process. Ideally, this guarantee should extend over a reasonable period, giving you peace of mind that the repairs will hold up over time.

A reputable contractor will usually offer a warranty that covers any issues resulting from their workmanship. This means that if the repaired area shows signs of further damage within the warranty period, the contractor will return to fix it at no additional cost. However, it's important to note that these guarantees often do not cover damage resulting from external factors, such as natural disasters, soil conditions, or improper maintenance by the homeowner.

When evaluating a foundation repair guarantee, pay close attention to the fine print. Look for any exclusions or limitations that might affect your coverage. Additionally, ensure that the warranty is transferable if you plan to sell your home in the future, as this can be a valuable selling point.

In conclusion, understanding the scope of foundation repair guarantees involves knowing the common issues that necessitate repairs and what to expect from a warranty. By being informed and choosing a reputable contractor, you can safeguard your home's structural integrity and protect your investment for years to come.

Understanding Foundation Repair Guarantees: Explanation of what guarantees typically cover and their limitations.


When homeowners face foundation problems, they often turn to professional repair services. These services usually come with guarantees, but understanding what those guarantees cover and their limitations is crucial. Foundation repair guarantees are designed to provide peace of mind, ensuring that the work done will be effective and long-lasting. However, it's important to read the fine print to grasp the full scope of these assurances.

Typically, foundation repair guarantees cover the structural integrity of the repairs made. This means that if the repairs fail due to workmanship or materials within a specified period, the company will return to fix the issue at no additional cost. For example, if a pier and beam system is installed to stabilize a settling foundation and it fails within the guarantee period, the repair company is obligated to correct it.

However, these guarantees have limitations. They generally do not cover issues arising from external factors such as soil movement, natural disasters, or poor maintenance by the homeowner. For instance, if heavy rains cause soil erosion leading to further foundation issues, this might not be covered under the guarantee. Similarly, if the homeowner fails to maintain proper drainage around the house, any subsequent problems may not be included in the guarantee.

Another common limitation is the duration of the guarantee. While some companies offer lifetime warranties, others provide coverage for only a few years. It's essential to understand how long your guarantee lasts and what specific conditions must be met to keep it valid. Some guarantees may require regular inspections or maintenance schedules to remain active, placing some responsibility on the homeowner.

Moreover, guarantees often do not cover cosmetic damage or minor adjustments that might be needed over time. While they ensure that major structural issues are addressed, small cracks in walls or slight settling might not fall under their scope. This underscores why reading through all terms and conditions is vital before signing off on any repair work.

In conclusion, understanding foundation repair guarantees involves knowing both what they cover and their limitations. While they provide assurance against poor workmanship and substandard materials, they do not shield against all potential future problems with your foundation. Homeowners must be proactive in maintaining their properties and fully informed about what their guarantees entail to avoid surprises down the road.

Key Components of a Foundation Repair Guarantee: Elements like warranty period, exclusions, and conditions for coverage.


When it comes to foundation repair guarantees offered by contractors or companies specializing in these services , understanding their scope involves delving into several key components . These elements ensure homeowners grasp what exactly they're getting when they sign up for these services . Let' s break down these crucial aspects . One fundamental component is undoubtedly warranty period . This specifies how long after completion , service providers guarantee their work . Some warranties might last only few years , others may extend upto lifetime coverage depending upon type , extent ,and quality workmanship used during repair process . This gives homeowners peace mind knowing any issues arising within set timeframe should get addressed without extra cost implication . Next , it' s crucial consider exclusions within guarantee . Not every aspect foundation repair may be covered under warranty . Common exclusions include damage caused by natural disasters , acts God , improper maintenance post-repair , or normal settling house that occurs over time . Understanding these exemptions helps manage expectations regarding what' s truly covered . Lastly , conditions coverage outlines circumstances under which guarantee remains valid . This typically involves maintaining proper drainage around foundation , ensuring regular inspections plumbing systems , among other responsibilities homeowner must fulfill maintain warranty effectiveness . These conditions aim protect both parties interest ensuring longevity success foundation repairs performed . In conclusion , grasping scope foundation repair guarantees requires thorough examination warranty period , exclusions , conditions coverage . By doing so , homeowners make informed decisions about their investments while safeguarding themselves potential pitfalls along way . Always read fine print ask questions clarity before committing any agreement ensure maximum protection offered under guarantee terms .

Factors Affecting Guarantee Validity: Issues such as soil conditions, environmental changes, and homeowner responsibilities that can impact the guarantee.


When it comes to understanding the scope of foundation repair guarantees, it's crucial to consider several factors that can affect their validity. These factors often revolve around soil conditions, environmental changes, homoeowner responsibilities including poor home maintence issues among others issues discussed below :first soil conditions plays significat role on foundation repair .Soil types vary greatly, from expansive clays that swell with moisture to sandy soils that can shift and settle. If the soil beneath a foundation is unstable or undergoes significant changes due to moisture content, weathering, or other environmental factors, it can lead to further foundation issues even after repairs have been made. Most guarantees will not cover damage resulting from natural soil movement or changes that occur post-repair.

Environmental changes also play a significant role in the longevity of foundation repairs. Extreme weather conditions, such as heavy rainfall, droughts, or freezing temperatures, can impact the stability of the soil and, consequently, the foundation. Flooding can erode soil or create hydrostatic pressure against the foundation, while droughts can cause soil shrinkage and settlement. These environmental factors are typically beyond the control of repair companies and are often excluded from guarantees.

Homeowner responsibilities are another critical aspect that can affect guarantee validity. Proper maintenance is essential to preserve the integrity of a repaired foundation. This includes ensuring adequate drainage around the home, addressing plumbing leaks promptly, and maintaining consistent moisture levels in the soil surrounding the foundation. Neglecting these responsibilities can lead to new or recurring foundation problems, which may not be covered under the original repair guarantee. For example, failure to direct water away from the home can result in soil erosion or excessive moisture accumulation, both of which can compromise the foundation.

Additionally, any structural modifications or additions made to the home after the foundation repair can void the guarantee. These changes can alter the load distribution on the foundation, leading to new stress points and potential issues. It's important for homeowners to consult with professionals before making any significant structural changes to ensure they do not compromise the repaired foundation.

In summary, understanding the scope of foundation repair guarantees involves recognizing the interplay between soil conditions, environmental changes, and homeowner responsibilities. While repair companies strive to provide long-lasting solutions, certain factors outside their control can impact the validity of their guarantees. Homeowners should be proactive in maintaining their homes and aware of environmental conditions that could affect their foundations to maximize the effectiveness and longevity of repairs

Evaluating Warranty Options: Tips for comparing warranties from different service providers to make an informed decision.


When it comes to foundation repair, one of the most crucial aspects to consider is the warranty offered by service providers-it's your safety net ensuring long term protection against future issues arising from their workmanship . Evaluating these warranties requires careful comparison so you can make an informed decision based on coverage scope , length , transferability , cost , liability limitations , repair methods covered , annual inspections included , exclusions & limitations . Here are some tips :

Firstly , understand the scope . A comprehensive warranty should cover all aspects of your foundation repair including materials and labor . Look for explicit details on what's included-the more specific , the better . Some warranties might only cover certain repair methods or exclude others altogether-be aware of these differences .

Secondly , consider the warranty duration . Lifetime warranties sound promising but read fine print closely . 'Lifetime' could mean lifetime of structure's expected lifespan rather than your ownership period . Compare short term vs long term coverage considering your future plans with property-a longer warranty is usually preferable .

Thirdly , check transferability . If there's a chance you might sell your property , a transferable warranty can add value during resale . This option allows new owners to benefit from remaining warranty period . However , non transferable warranties could limit prospective buyers' interest due to potential future costs related with fixing foundational concerns .

Next , evaluate any costs associated with warranty . While some warranties are free , others come at an additional cost . Weigh these expenses against potential savings from future repairs-sometimes paying extra upfront makes sense in long run . Also , examine liability limitations-understand what happens if something goes wrong during or after repair process & know maximum coverage offered under warranty claim process .

Another key aspect is understanding whether annual inspections are included . Regular checkups help identify & address any arising issues early on preventing minor problems turning major headaches . Some providers include these inspections within warranty offerings helping maintain peace -of -mind post repair work .

Lastly , scrutinize exclusions & limitations thoroughly . Every warranty has conditions it won't cover-make sure you're clear on these points before committing . Exclusions could range from natural disasters to certain types of structural damage-ensure you comprehend implications fully . A reliable service provider should clearly outline these aspects without hiding behind jargon or complex legal language .

The Role of Professional Inspections: Importance of regular inspections to maintain the validity of the guarantee and ensure ongoing structural integrity.


When it comes foundation repairs handling foundation repair guaranteeshould not be taken lightly, as they play a crucial role in ensuring the long-term stability and safety of your home. One key aspect that often goes overlooked is the role of professional inspections. Regular inspections are not just a formality; they are vital for maintaining the validity of your guarantee and ensuring the ongoing structural integrity of your foundation.

Imagine buying a new car. You wouldn't just drive it off the lot and never bother with maintenance, expecting the warranty to cover any issues that arise. Similarly, a foundation repair guarantee isn't a set-it-and-forget-it deal. Regular inspections are like the routine check-ups that keep your foundation 'warranty' valid and your home structurally sound.

Professional inspections serve several purposes. Firstly, they allow experts to identify and address any potential issues early on before they become major problems. Foundations can shift, settle, or develop cracks over time due to various factors like soil movement, water damage, or the natural aging process of materials. Regular inspections can catch these changes early, ensuring that any necessary repairs are made promptly and correctly.

Secondly, many foundation repair guarantees require regular inspections as part of their terms and conditions. Failure to comply with these requirementscan voidyour guarantee occurs , meaningyoucouldbelefttofootthebillforanyrepairsoutofsufficientfundsnormaterialswhenwhenproblemscariseaftertheinitialrepairspeciallyincaseswherethereisnotproperinspectiondonebasedonyourrequirements . Therefore regularly scheduled professional inspectionssafeguardsyourguaranteekeepingittvalidforthelongterm . Ensuringsuchinspectionsarescheduledregularbasiswillhelpkeepyourhomeprotectedagainstmajorstructuralissueswhichcouldcostsignificantlymorethanregularmaintenancechecksinlongrun . Every home owner wishes totakecareofhispropertykeepingitsvalueintactforfuturebenefitsespeciallyifconsideringsellingorsimplypassingtonextgenerationalfamilyline . Professional inspectorsprovideunbiasedthirdpartyobjectivereportsaboutcurrentstateoffoundationsuggestingenecessarycorrectactionsneedbeundertakenpreserveintegrityofstructure . Alwaysensuregetyourhomeregularprofessionalscheckedinspectedensureminimumstandardsmaintainedavoidanyunexpectedissuesfromarisingfuture . Henceprofessionalsprovidepeaceofmindknowinglyyourhome structurallysoundwellprotectedagainstanyunderlyingissueswhichmaycauseconcernsfuturetherebyhelpingresalevaluehighwhennecessarycomesellmoveotherlocationwithouanyhasslesworriesregardingfoundationalintegrityoverallstructurehomeresidentsafety family . Regular inspections provide peace omincreasesresale valueincaseofsellinghousefutureendeavors . Be responsible homeownergetchecksyourownhomeyearbasisfoundationalintegrityguaranteeingstructuralwellbeingsafetyfamily . Investintimeprofessionalskeepinghomesafealwaysbestapproachanypropertyownerlongtermkeepstructuresoundprotectfromanyunforeseencostsarisefuturecases .



Suspended slab under construction, with the formwork still in place
Suspended slab formwork and rebar in place, ready for concrete pour.

A concrete slab is a common structural element of modern buildings, consisting of a flat, horizontal surface made of cast concrete. Steel-reinforced slabs, typically between 100 and 500 mm thick, are most often used to construct floors and ceilings, while thinner mud slabs may be used for exterior paving ( see below).[1][2]

In many domestic and industrial buildings, a thick concrete slab supported on foundations or directly on the subsoil, is used to construct the ground floor. These slabs are generally classified as ground-bearing or suspended. A slab is ground-bearing if it rests directly on the foundation, otherwise the slab is suspended.[3] For multi-story buildings, there are several common slab designs (

see § Design for more types):

  • Beam and block, also referred to as rib and block, is mostly used in residential and industrial applications. This slab type is made up of pre-stressed beams and hollow blocks and are temporarily propped until set, typically after 21 days.[4]
  • A hollow core slab which is precast and installed on site with a crane
  • In high rise buildings and skyscrapers, thinner, pre-cast concrete slabs are slung between the steel frames to form the floors and ceilings on each level. Cast in-situ slabs are used in high rise buildings and large shopping complexes as well as houses. These in-situ slabs are cast on site using shutters and reinforced steel.

On technical drawings, reinforced concrete slabs are often abbreviated to "r.c.c. slab" or simply "r.c.". Calculations and drawings are often done by structural engineers in CAD software.

Thermal performance

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Energy efficiency has become a primary concern for the construction of new buildings, and the prevalence of concrete slabs calls for careful consideration of its thermal properties in order to minimise wasted energy.[5] Concrete has similar thermal properties to masonry products, in that it has a relatively high thermal mass and is a good conductor of heat.

In some special cases, the thermal properties of concrete have been employed, for example as a heatsink in nuclear power plants or a thermal buffer in industrial freezers.[6]

Thermal conductivity

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Thermal conductivity of a concrete slab indicates the rate of heat transfer through the solid mass by conduction, usually in regard to heat transfer to or from the ground. The coefficient of thermal conductivity, k, is proportional to density of the concrete, among other factors.[5] The primary influences on conductivity are moisture content, type of aggregate, type of cement, constituent proportions, and temperature. These various factors complicate the theoretical evaluation of a k-value, since each component has a different conductivity when isolated, and the position and proportion of each components affects the overall conductivity. To simplify this, particles of aggregate may be considered to be suspended in the homogeneous cement. Campbell-Allen and Thorne (1963) derived a formula for the theoretical thermal conductivity of concrete.[6] In practice this formula is rarely applied, but remains relevant for theoretical use. Subsequently, Valore (1980) developed another formula in terms of overall density.[7] However, this study concerned hollow concrete blocks and its results are unverified for concrete slabs.

The actual value of k varies significantly in practice, and is usually between 0.8 and 2.0 W m−1 K−1.[8] This is relatively high when compared to other materials, for example the conductivity of wood may be as low as 0.04 W m−1 K−1. One way of mitigating the effects of thermal conduction is to introduce insulation (

see § Insulation).

Thermal mass

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The second consideration is the high thermal mass of concrete slabs, which applies similarly to walls and floors, or wherever concrete is used within the thermal envelope. Concrete has a relatively high thermal mass, meaning that it takes a long time to respond to changes in ambient temperature.[9] This is a disadvantage when rooms are heated intermittently and require a quick response, as it takes longer to warm the entire building, including the slab. However, the high thermal mass is an advantage in climates with large daily temperature swings, where the slab acts as a regulator, keeping the building cool by day and warm by night.

Typically concrete slabs perform better than implied by their R-value.[5] The R-value does not consider thermal mass, since it is tested under constant temperature conditions. Thus, when a concrete slab is subjected to fluctuating temperatures, it will respond more slowly to these changes and in many cases increase the efficiency of a building.[5] In reality, there are many factors which contribute to the effect of thermal mass, including the depth and composition of the slab, as well as other properties of the building such as orientation and windows.

Thermal mass is also related to thermal diffusivity, heat capacity and insulation. Concrete has low thermal diffusivity, high heat capacity, and its thermal mass is negatively affected by insulation (e.g. carpet).[5]

Insulation

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Without insulation, concrete slabs cast directly on the ground can cause a significant amount of extraneous energy transfer by conduction, resulting in either lost heat or unwanted heat. In modern construction, concrete slabs are usually cast above a layer of insulation such as expanded polystyrene, and the slab may contain underfloor heating pipes.[10] However, there are still uses for a slab that is not insulated, for example in outbuildings which are not heated or cooled to room temperature (

see § Mud slabs). In these cases, casting the slab directly onto a substrate of aggregate will maintain the slab near the temperature of the substrate throughout the year, and can prevent both freezing and overheating.

A common type of insulated slab is the beam and block system (mentioned above) which is modified by replacing concrete blocks with expanded polystyrene blocks.[11] This not only allows for better insulation but decreases the weight of slab which has a positive effect on load bearing walls and foundations.

Formwork set for concrete pour.
Concrete poured into formwork. This slab is ground-bearing and reinforced with steel rebar.

Design

[edit]
Further information: Marcus' method

Ground-bearing slabs

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See also: Shallow foundation § Slab on grade

Ground-bearing slabs, also known as "on-ground" or "slab-on-grade", are commonly used for ground floors on domestic and some commercial applications. It is an economical and quick construction method for sites that have non-reactive soil and little slope.[12]

For ground-bearing slabs, it is important to design the slab around the type of soil, since some soils such as clay are too dynamic to support a slab consistently across its entire area. This results in cracking and deformation, potentially leading to structural failure of any members attached to the floor, such as wall studs.[12]

Levelling the site before pouring concrete is an important step, as sloping ground will cause the concrete to cure unevenly and will result in differential expansion. In some cases, a naturally sloping site may be levelled simply by removing soil from the uphill site. If a site has a more significant grade, it may be a candidate for the "cut and fill" method, where soil from the higher ground is removed, and the lower ground is built up with fill.[13]

In addition to filling the downhill side, this area of the slab may be supported on concrete piers which extend into the ground. In this case, the fill material is less important structurally as the dead weight of the slab is supported by the piers. However, the fill material is still necessary to support the curing concrete and its reinforcement.

There are two common methods of filling - controlled fill and rolled fill.[13]

  • Controlled fill: Fill material is compacted in several layers by a vibrating plate or roller. Sand fills areas up to around 800 mm deep, and clay may be used to fill areas up to 400 mm deep. However, clay is much more reactive than sand, so it should be used sparingly and carefully. Clay must be moist during compaction to homogenise it.[13]
  • Rolled fill: Fill is repeatedly compacted by an excavator, but this method of compaction is less effective than a vibrator or roller. Thus, the regulations on maximum depth are typically stricter.

Proper curing of ground-bearing concrete is necessary to obtain adequate strength. Since these slabs are inevitably poured on-site (rather than precast as some suspended slabs are), it can be difficult to control conditions to optimize the curing process. This is usually aided by a membrane, either plastic (temporary) or a liquid compound (permanent).[14]

Ground-bearing slabs are usually supplemented with some form of reinforcement, often steel rebar. However, in some cases such as concrete roads, it is acceptable to use an unreinforced slab if it is adequately engineered (

see below).

Suspended slabs

[edit]

For a suspended slab, there are a number of designs to improve the strength-to-weight ratio. In all cases the top surface remains flat, and the underside is modulated:

  • A corrugated slab is designed when the concrete is poured into a corrugated steel tray, more commonly called decking. This steel tray improves strength of the slab, and prevents the slab from bending under its own weight. The corrugations run in one direction only.
  • A ribbed slab gives considerably more strength in one direction. This is achieved with concrete beams bearing load between piers or columns, and thinner, integral ribs in the perpendicular direction. An analogy in carpentry would be a subfloor of bearers and joists. Ribbed slabs have higher load ratings than corrugated or flat slabs, but are inferior to waffle slabs.[15]
  • A waffle slab gives added strength in both directions using a matrix of recessed segments beneath the slab.[16] This is the same principle used in the ground-bearing version, the waffle slab foundation. Waffle slabs are usually deeper than ribbed slabs of equivalent strength, and are heavier hence require stronger foundations. However, they provide increased mechanical strength in two dimensions, a characteristic important for vibration resistance and soil movement.[17]
The exposed underside of a waffle slab used in a multi-storey building

Unreinforced slabs

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Unreinforced or "plain"[18] slabs are becoming rare and have limited practical applications, with one exception being the mud slab (

see below). They were once common in the US, but the economic value of reinforced ground-bearing slabs has become more appealing for many engineers.[10] Without reinforcement, the entire load on these slabs is supported by the strength of the concrete, which becomes a vital factor. As a result, any stress induced by a load, static or dynamic, must be within the limit of the concrete's flexural strength to prevent cracking.[19] Since unreinforced concrete is relatively very weak in tension, it is important to consider the effects of tensile stress caused by reactive soil, wind uplift, thermal expansion, and cracking.[20] One of the most common applications for unreinforced slabs is in concrete roads.

Mud slabs

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Mud slabs, also known as rat slabs, are thinner than the more common suspended or ground-bearing slabs (usually 50 to 150 mm), and usually contain no reinforcement.[21] This makes them economical and easy to install for temporary or low-usage purposes such as subfloors, crawlspaces, pathways, paving, and levelling surfaces.[22] In general, they may be used for any application which requires a flat, clean surface. This includes use as a base or "sub-slab" for a larger structural slab. On uneven or steep surfaces, this preparatory measure is necessary to provide a flat surface on which to install rebar and waterproofing membranes.[10] In this application, a mud slab also prevents the plastic bar chairs from sinking into soft topsoil which can cause spalling due to incomplete coverage of the steel. Sometimes a mud slab may be a substitute for coarse aggregate. Mud slabs typically have a moderately rough surface, finished with a float.[10]

Substrate and rebar prepared for pouring a mud slab

Axes of support

[edit]

One-way slabs

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A one-way slab has moment-resisting reinforcement only in its short axis, and is used when the moment in the long axis is negligible.[23] Such designs include corrugated slabs and ribbed slabs. Non-reinforced slabs may also be considered one-way if they are supported on only two opposite sides (i.e. they are supported in one axis). A one-way reinforced slab may be stronger than a two-way non-reinforced slab, depending on the type of load.

The calculation of reinforcement requirements for a one-way slab can be extremely tedious and time-consuming, and one can never be completely certain of the best design.[citation needed] Even minor changes to the project can necessitate recalculation of the reinforcement requirements. There are many factors to consider during the structural structure design of one-way slabs, including:

  • Load calculations
  • Bending moment calculation
  • Acceptable depth of flexure and deflection
  • Type and distribution of reinforcing steel

Two-way slabs

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A two-way slab has moment resisting reinforcement in both directions.[24] This may be implemented due to application requirements such as heavy loading, vibration resistance, clearance below the slab, or other factors. However, an important characteristic governing the requirement of a two-way slab is the ratio of the two horizontal lengths. If where is the short dimension and is the long dimension, then moment in both directions should be considered in design.[25] In other words, if the axial ratio is greater than two, a two-way slab is required.

A non-reinforced slab is two-way if it is supported in both horizontal axes.

Construction

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A concrete slab may be prefabricated (precast), or constructed on site.

Prefabricated

[edit]

Prefabricated concrete slabs are built in a factory and transported to the site, ready to be lowered into place between steel or concrete beams. They may be pre-stressed (in the factory), post-stressed (on site), or unstressed.[10] It is vital that the wall supporting structure is built to the correct dimensions, or the slabs may not fit.

On-site

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On-site concrete slabs are built on the building site using formwork, a type of boxing into which the wet concrete is poured. If the slab is to be reinforced, the rebars, or metal bars, are positioned within the formwork before the concrete is poured in.[26] Plastic-tipped metal or plastic bar chairs, are used to hold the rebar away from the bottom and sides of the form-work, so that when the concrete sets it completely envelops the reinforcement. This concept is known as concrete cover. For a ground-bearing slab, the formwork may consist only of side walls pushed into the ground. For a suspended slab, the formwork is shaped like a tray, often supported by a temporary scaffold until the concrete sets.

The formwork is commonly built from wooden planks and boards, plastic, or steel. On commercial building sites, plastic and steel are gaining popularity as they save labour.[27] On low-budget or small-scale jobs, for instance when laying a concrete garden path, wooden planks are very common. After the concrete has set the wood may be removed.

Formwork can also be permanent, and remain in situ post concrete pour. For large slabs or paths that are poured in sections, this permanent formwork can then also act as isolation joints within concrete slabs to reduce the potential for cracking due to concrete expansion or movement.

In some cases formwork is not necessary. For instance, a ground slab surrounded by dense soil, brick or block foundation walls, where the walls act as the sides of the tray and hardcore (rubble) acts as the base.

See also

[edit]
  • Shallow foundation (Commonly used for ground-bearing slabs)
  • Hollow-core slab (Voided slab, one-way spanning)
  • Beam and block (voided slab, one way spanning)
  • Voided biaxial slab (Voided slab, two-way spanning)
  • Formwork
  • Precast concrete
  • Reinforced concrete
  • Rebar
  • Concrete cover

References

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  1. ^ Garber, G. Design and Construction of Concrete Floors. 2nd ed. Amsterdam: Butterworth-Heinemann, 2006. 47. Print.
  2. ^ Duncan, Chester I. Soils and Foundations for Architects and Engineers. New York: Van Nostrand Reinhold, 1992. 299. Print.
  3. ^ "Ground slabs - Introduction". www.dlsweb.rmit.edu.au. Archived from the original on 2019-11-18. Retrieved 2017-12-07.
  4. ^ "What is a rib and block slab?". www.royalconcreteslabs.co.za. Royal concrete slabs.
  5. ^ a b c d e Cavanaugh, Kevin; et al. (2002). Guide to Thermal Properties of Concrete and Masonry Systems: Reported by ACI Committee 122. American Concrete Institute.
  6. ^ a b Campbell-Allen, D.; Thorne, C.P. (March 1963). "The thermal conductivity of concrete". Magazine of Concrete Research. 15 (43): 39–48. doi:10.1680/macr.1963.15.43.39. UDC 691.32.001:536.21:691.322.
  7. ^ Valore, R.C. Jr. (February 1980). "Calculation of U-values of Hollow Concrete Masonry". Concrete International. 2: 40–63.
  8. ^ Young, Hugh D. (1992). "Table 15.5". University Physics (7th ed.). Addison Wesley. ISBN 0201529815.
  9. ^ Sabnis, Gajanan M.; Juhl, William (2016). "Chapter 4: Sustainability through Thermal Mass of Concrete". Green Building with Concrete: Sustainable Design and Construction (2nd ed.). Taylor & Francis Group. ISBN 978-1-4987-0411-3.
  10. ^ a b c d e Garber, George (2006). Design and Construction of Concrete Floors (2nd ed.). Amsterdam: Butterworth-Heinemann. ISBN 978-0-7506-6656-5.
  11. ^ "What is a polystyrene concrete slab?". www.royalconcreteslabs.co.za. Royal concrete slabs.
  12. ^ a b McKinney, Arthur W.; et al. (2006). Design of Slabs-on-Ground: Reported by ACI Committee 360 (PDF). American Concrete Institute. Archived from the original (PDF) on 2021-05-08. Retrieved 2019-04-04.
  13. ^ a b c Staines, Allan (2014). The Australian House Building Manual. Pinedale Press. pp. 40–41. ISBN 978-1-875217-07-6.
  14. ^ "Concrete in Practice 11 - Curing In-Place Concrete" (PDF). Engineering.com. National Ready Mixed Concrete Association. Archived from the original (PDF) on 4 April 2019. Retrieved 4 April 2019.
  15. ^ "Ribbed Slabs Datasheet" (PDF). Kaset Kalip. Archived from the original (PDF) on 29 March 2018. Retrieved 4 April 2019.
  16. ^ "Ribbed and waffle slabs". www.concretecentre.com. Retrieved 2019-04-04.
  17. ^ Concrete Framed Buildings: A Guide to Design and Construction. MPA The Concrete Centre. 2016. ISBN 978-1-904818-40-3.
  18. ^ Garrison, Tim (19 February 2014). "Clearing the confusion on 'plain concrete'". Civil & Structural Engineer. Archived from the original on 8 May 2019. Retrieved 8 May 2019.
  19. ^ Walker, Wayne. "Reinforcement for slabs on ground". Concrete Construction. Retrieved 8 May 2019.
  20. ^ "Rupture depth of an unreinforced concrete slab on grade" (PDF). Aluminium Association of Florida, Inc. Archived from the original (PDF) on 2020-09-26. Retrieved 2019-05-08.
  21. ^ Arcoma, Peter. "What is a mud slab?". Builder-Questions.com. Retrieved 8 May 2019.
  22. ^ Postma, Mark; et al. "Floor Slabs". Whole Building Design Guide. National Institute of Building Sciences. Retrieved 8 May 2019.
  23. ^ Gilbert, R. I. (1980). UNICIV Report 211 (PDF). University of New South Wales.
  24. ^ Prieto-Portar, L. A. (2008). EGN-5439 The Design of Tall Buildings; Lecture #14: The Design of Reinforced Concrete Slabs (PDF). Archived from the original (PDF) on 2017-08-29. Retrieved 2019-04-04.
  25. ^ "What is the difference between one way and two way slab?". Basic Civil Engineering. 16 June 2019. Retrieved 8 July 2019.
  26. ^ Concrete Basics: A Guide to Concrete Practice (6th ed.). Cement Concrete & Aggregates Australia. 2004. p. 53.
  27. ^ Nemati, Kamran M. (2005). "Temporary Structures: Formwork for Concrete" (PDF). Tokyo Institute of Technology. Archived from the original (PDF) on 12 July 2018. Retrieved 4 April 2019.
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Driving Directions From Palmisano (Henry) Park to
Driving Directions From Lake Katherine Nature Center and Botanic Gardens to
Driving Directions From Navy Pier to

https://www.google.com/maps/dir/Navy+Pier/United+Structural+Systems+of+Illinois%2C+Inc/@41.8918633,-87.6050944,14z/data=!3m1!4b1!4m14!4m13!1m5!1m1!1sunknown!2m2!1d-87.6050944!2d41.8918633!1m5!1m1!1sChIJ-wSxDtinD4gRiv4kY3RRh9U!2m2!1d-88.1396465!2d42.0637725!3e0

https://www.google.com/maps/dir/Lake+Katherine+Nature+Center+and+Botanic+Gardens/United+Structural+Systems+of+Illinois%2C+Inc/@41.6776048,-87.8010774,14z/data=!3m1!4b1!4m14!4m13!1m5!1m1!1sunknown!2m2!1d-87.8010774!2d41.6776048!1m5!1m1!1sChIJ-wSxDtinD4gRiv4kY3RRh9U!2m2!1d-88.1396465!2d42.0637725!3e2

https://www.google.com/maps/dir/Palmisano+%28Henry%29+Park/United+Structural+Systems+of+Illinois%2C+Inc/@41.8429903,-87.6490151,14z/data=!3m1!4b1!4m14!4m13!1m5!1m1!1sunknown!2m2!1d-87.6490151!2d41.8429903!1m5!1m1!1sChIJ-wSxDtinD4gRiv4kY3RRh9U!2m2!1d-88.1396465!2d42.0637725!3e1

Reviews for

Jeffery James

(5)

Very happy with my experience. They were prompt and followed through, and very helpful in fixing the crack in my foundation.

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.

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!

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

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.

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Frequently Asked Questions

** Generally , additional foundational issues outside those specific areas repaired initially might not fall under your guarantee . However , some companies extend coverage beyond immediate repairs , offering comprehensive warranties which cover broader structural integrity concerns resulting from previous work done . Ensure any service agreement spells out clearly how subsequent problems would be handled financially / procedurally moving forward .**
** To maintain validity frequent maintenance visits ensuring that no further deterioration occurs due neglect keeping up regular communications regarding any noticeable changes affecting structural health should suffice maintaining consistent records proving adherence towards recommended practices mentioned within warranty documentation also helps reinforce compliance measures justifying claims eligibility seamlessly whenever required so pay close attention following guidance right after initial consultations respectfully.**