Concrete leveling

Last updated September 28, 2023

In civil engineering, concrete leveling is a procedure that attempts to correct an uneven concrete surface by altering the foundation that the surface sits upon. It is a cheaper alternative to having replacement concrete poured and is commonly performed at small businesses and private homes as well as at factories, warehouses, airports and on roads, highways and other infrastructure.

Causes of settlement

Concrete slabs can be susceptible to settlement from a wide variety of factors, the most common being an inconsistency of moisture in the soil. Soil expands and contracts as the levels of moisture fluctuate during the dry and rainy seasons. In some parts of the United States, naturally occurring soils can consolidate over time, including areas ranging from Texas up through to Wisconsin. Soil erosion also contributes to concrete settlement, which is common for locations with improper drainage. Concrete slabs built upon filled-in land can excessively settle as well. This is common for homes with basement levels since the backfill on the outside of the foundation frequently is not compacted properly. In some cases, poorly designed sidewalk or patio slabs direct water towards the basement level of a structure. Tree roots can also have an impact on concrete as well, actually powerful enough to lift a slab upwards or breakthrough entirely; this is common along public roadways, especially within metropolitan areas.^[1]

Concrete settlement, uneven concrete surfaces, and uneven footings can also be caused by seismic activity especially in earthquake-prone countries including Japan, New Zealand, Turkey, and the United States.

Slabjacking

"Slabjacking" is a specialty concrete repair technology. In essence, slabjacking attempts to lift a sunken concrete slab by pumping a substance through the concrete, effectively pushing it up from below. The process is also commonly referred to as "mudjacking" and "pressure grouting.”

Accounts of raising large concrete slabs through the use of hydraulic pressure date back to the early 20th century. Early contractors used a mixture of locally available soils (sometimes including crushed limestone and/or cement for strength), producing a "mud-like" substance and thus the term "mudjacking." In recent years, some slabjacking contractors began using expanding polyurethane foam. Each method has its benefits and disadvantages.

The slabjacking process generally starts with drilling access holes in the concrete, strategically located to maximize lift. These holes range in size from 3/8" up to 3" depending on the process used.

Initial material injections fill any under slab void space. Once the void space is filled, subsequent injections will start lifting the concrete within minutes. After the slabs are lifted, the access holes are patched and the work is complete. The process is rapid when compared to traditional remove and replace applications and is minimally disturbing to the surrounding areas.

Slabjacking technology has several benefits, including:

Cost – can be significantly less expensive than new concrete
Timeliness of the repair – concrete is typically usable within hours as opposed to days with new concrete
Minimal or no environmental impact – mostly due to keeping waste out of landfills
Aesthetic – does not disturb the surrounding area and landscaping

Slabjacking also has some limitations, including:

Concrete must be in fairly sound condition – if there are too many cracks, replacement might be the only option
New cracks can occur as the slab is lifted – most would have already been present, just not visible before lifting
Possible resettlement – if concrete poured on top of poorly compacted soils it can still sink further. However, this is also possible with new concrete.

Slabjacking can typically be broken down into three main process types:

Mudjacking

The term Mudjacking^[2] originates from using a mixture of topsoil and portland cements injected underground to hydraulically lift concrete slabs. Mudjacking can be achieved with a variety of mixtures. The most common being a local soil or sand blend, mixed with water and cement. Other additives may be included in the mixture for increased "pumpabilitly"/lubrication, improved strength/curing times, or as a filler. Additives that may be present include: clay/bentonite, fly ash, pond sand, pea gravel, masonry cements, or crushed lime. This process typically requires holes between 1" and 2" in diameter. This "mud" is injected under the concrete slabs, oftentimes using a movable pump that can access most slabs. Once the void under the slab is filled, the pressure builds under the slab, lifting the concrete back into place. Once in place, the holes are filled with a color-matching grout.

Benefits of mudjacking:

Low-pressure lifting of slab
Finely controlled lifting of the slab
Possible to achieve higher compressive strength than foam leveling
Budget-friendly
Equipment can access locations at longer distances than poly foam
Environmentally friendly. Accepted at concrete recycling facilities unlike poly foam and does not need to be separated from the concrete

Disadvantages of mudjacking:

Typically shorter warranty periods than what's offered by polyurethane foam contractors.
Requires more clean-up afterward compared to foam leveling
Largest holes of the three main processes
Can be a slower process due to the smaller material volume of the movable cart.
Does not resist erosion or fill voids as well as polyurethane foam.^[3]

Limestone grout leveling

This method uses a pulverized limestone, commonly called agricultural lime. mixed with water, and sometimes Portland cement, to create a slurry about the consistency of a thick milkshake. This slurry is pumped hydraulically beneath the slab through 1" holes. Because of its semi-fluid nature, it pushes against itself, filling voids beneath the slab. Once the void is filled, pressure builds, slowly lifting the slab into place. Due to the low pressure of this method, trained professionals are able to control the lift of the concrete slab precisely, without the worry of lifting too far. This also decreases the likelihood of cracking or damaging the slab further. Once the slab is lifted into place, the holes are filled with a color-matching non-shrink grout.

Even though the injection pressure is relatively low, compared to Foam Leveling, Stone Slurry Grout Leveling has a high compressive strength of 240 pounds per square inch.^[4] This is equal to 34,560 pounds of lifting force per square foot. With Portland cement added, this can increase to over 6,000 psi^[5] or 864,000 pounds per square foot. Once the slurry dries it creates a near-solid stone foundation for the leveled concrete (much like the original stone base the concrete was poured upon.)

Benefits of stone slurry grout leveling

Low-pressure lifting of slabs
Finely controlled lifting of the slab
When the limestone grout dries out, it creates a hard subsurface for the concrete slab
Smaller holes than mudjacking
Highest compressive strength among the three methods
Environmentally friendly
Budget-friendly

Disadvantages of stone slurry grout leveling:

Requires more clean-up afterward compared with foam leveling
Slabs to be lifted must typically be within 100 feet of the truck-based pumping equipment
Larger holes than foam leveling
Without sufficient cement, rainwater can erode limestone leveling materials resulting in re-settlement

Expanding structural foam leveling

^[6]

Foam leveling uses polyurethane in an injection process.^[7] A two-part polymer ^[8] is injected through a hole less than one inch in diameter. Although the material is injected at a higher pressure than traditional cementitious grouts, the pressure is not what causes the lifting. The expansion of the air bubbles in the injected material below the slab surface performs the actual lifting action as the liquid resin reacts and becomes a structural foam. The material injected below a slab to be lifted will first find weak soils, expanding into them in such a manner as to consolidate and cause sub-soils to become denser and fill any voids below the slab. One inherent property of expanding foams is that they will follow the path of least resistance, expanding in all directions. Another inherent property includes reaching a hydro-insensitive or hydrophobic state when cured with 100% cure times as little as 30 minutes. Closed-cell injections will not retain moisture and are not subject to erosion once in place.

Some closed-cell polymer foams have baseline lifting capabilities of 6,000 lbs per sq. ft. [CONVERT] and leveling procedures have been performed in which loads as high as 125 tons have been lifted and stabilized in a surface area of less than 900 sq. ft. Some foams are even stronger, with compressive strengths of 50 psi and 100 psi in a free rise state. That is equal to 7,200–14,000 lbs. per square ft. [CONVERT] of support.^[9]^[10]

Benefits of Expanding Structural Foam Leveling

Meets compressive strength requirements when supporting highway slabs^[11]
Consumers benefit from longer warranty periods with Polyurethane Foam
Requires less clean up than Mudjacking or Limestone Grout Leveling
Smaller holes
Mobile units can reach areas inaccessible to truck-based equipment
Does not retain moisture
Does not erode when subjected to rainwater

Disadvantages of expanding structural foam leveling:

Requires specially trained technicians to properly install
Greater technical skills required for operations and maintenance of equipment
Intense heat can build up from improper installation of polyurethane
Environmentally un-friendly as polyurethane is a plastic^[12]
Potential toxicity of Structural Foam Dust^[13]
Can stick to and permanently stain other surrounding surfaces
Derived from crude oil, shipped to refineries, manufacturing plants, consumers and ultimately to job sites creating a negative environmental impact resulting in additional output of CO₂ and burning of fuel.
Intense heat can build up causing self combustion and flammability of polyurethane from improper installation

Related Research Articles

Concrete is a composite material composed of aggregate bonded together with a fluid cement that cures over time. Concrete is the second-most-used substance in the world after water, and is the most widely used building material. Its usage worldwide, ton for ton, is twice that of steel, wood, plastics, and aluminium combined.

Polyurethane refers to a class of polymers composed of organic units joined by carbamate (urethane) links. In contrast to other common polymers such as polyethylene and polystyrene, polyurethane is produced from a wide range of starting materials. This chemical variety produces polyurethanes with different chemical structures leading to many different applications. These include rigid and flexible foams, and coatings, adhesives, electrical potting compounds, and fibers such as spandex and polyurethane laminate (PUL). Foams are the largest application accounting for 67% of all polyurethane produced in 2016.

In materials science, a thermosetting polymer, often called a thermoset, is a polymer that is obtained by irreversibly hardening ("curing") a soft solid or viscous liquid prepolymer (resin). Curing is induced by heat or suitable radiation and may be promoted by high pressure or mixing with a catalyst. Heat is not necessarily applied externally, and is often generated by the reaction of the resin with a curing agent. Curing results in chemical reactions that create extensive cross-linking between polymer chains to produce an infusible and insoluble polymer network.

Grout is a dense fluid that hardens to fill gaps or used as reinforcement in existing structures. Grout is generally a mixture of water, cement, and sand, and is employed in pressure grouting, embedding rebar in masonry walls, connecting sections of precast concrete, filling voids, and sealing joints such as those between tiles. Common uses for grout in the household include filling in tiles of shower floors and kitchen tiles. It is often color tinted when it has to be kept visible and sometimes includes fine gravel when being used to fill large spaces. Unlike other structural pastes such as plaster or joint compound, correctly mixed and applied grout forms a water-resistant seal.

This page is a list of construction topics.

<span class="mw-page-title-main">Concrete slab</span> Flat, horizontal concrete element of modern buildings

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).

Soil cement is a construction material, a mix of pulverized natural soil with small amount of portland cement and water, usually processed in a tumbler, compacted to high density. Hard, semi-rigid durable material is formed by hydration of the cement particles.

A deep foundation is a type of foundation that transfers building loads to the earth farther down from the surface than a shallow foundation does to a subsurface layer or a range of depths. A pile or piling is a vertical structural element of a deep foundation, driven or drilled deep into the ground at the building site.

Basement waterproofing involves techniques and materials used to prevent water from penetrating the basement of a house or a building. Waterproofing a basement that is below ground level can require the application of sealant materials, the installation of drains and sump pumps, and more.

<span class="mw-page-title-main">Building insulation material</span>

Building insulation materials are the building materials that form the thermal envelope of a building or otherwise reduce heat transfer.

Reaction injection molding (RIM) is similar to injection molding except thermosetting polymers are used, which requires a curing reaction to occur within the mold.

Filler materials are particles added to resin or binders that can improve specific properties, make the product cheaper, or a mixture of both. The two largest segments for filler material use is elastomers and plastics. Worldwide, more than 53 million tons of fillers are used every year in application areas such as paper, plastics, rubber, paints, coatings, adhesives, and sealants. As such, fillers, produced by more than 700 companies, rank among the world's major raw materials and are contained in a variety of goods for daily consumer needs. The top filler materials used are ground calcium carbonate (GCC), precipitated calcium carbonate (PCC), kaolin, talc, and carbon black. Filler materials can affect the tensile strength, toughness, heat resistance, color, clarity, etc. A good example of this is the addition of talc to polypropylene. Most of the filler materials used in plastics are mineral or glass based filler materials. Particulates and fibers are the main subgroups of filler materials. Particulates are small particles of filler that are mixed in the matrix where size and aspect ratio are important. Fibers are small circular strands that can be very long and have very high aspect ratios.

Concrete is produced in a variety of compositions, finishes and performance characteristics to meet a wide range of needs.

<span class="mw-page-title-main">Grout curtain</span>

A grout curtain is a barrier that protects the foundation of a dam from seepage and can be made during initial construction or during repair. Additionally, they can be used to strengthen foundations and contain spills.

Pressure grouting or jet grouting involves injecting a grout material into otherwise inaccessible but interconnected pore or void space of which neither the configuration or volume are known, and is often referred to simply as grouting.

Sandjacking is the process of lifting concrete and filling in the space underneath with sand, which allows for frugal repairs in concrete applications. The basic premise is to lift concrete and to then fill the resultant void absolutely with compacted sand. Sandjacking includes the careful assessment of what is required to restore concrete to its original profile and the intelligent application of different materials to keep it that way. The filling provides the long term repair and protection of any flat concrete surface. Since the lifting and filling processes are distinctly separate events, each can be accomplished precisely.

Well cementing is the process of introducing cement to the annular space between the well-bore and casing or to the annular space between two successive casing strings. Personnel who conduct this job are called "Cementers".

Foam concrete, also known as Lightweight Cellular Concrete (LCC), Low Density Cellular Concrete (LDCC), and other terms is defined as a cement-based slurry, with a minimum of 20% foam entrained into the plastic mortar. As mostly no coarse aggregate is used for production of foam concrete the correct term would be called mortar instead of concrete; it may be called "foamed cement" as well. The density of foam concrete usually varies from 400 kg/m³ to 1600 kg/m³. The density is normally controlled by substituting fully or part of the fine aggregate with the foam.

Transfer molding is a manufacturing process in which casting material is forced into a mold. Transfer molding is different from compression molding in that the mold is enclosed rather than open to the fill plunger resulting in higher dimensional tolerances and less environmental impact. Compared to injection molding, transfer molding uses higher pressures to uniformly fill the mold cavity. This allows thicker reinforcing fiber matrices to be more completely saturated by resin. Furthermore, unlike injection molding the transfer mold casting material may start the process as a solid. This can reduce equipment costs and time dependency. The transfer process may have a slower fill rate than an equivalent injection molding process.

References

↑ Grantham, Michael (September 19, 2016). Concrete Solutions: Proceedings of Concrete Solutions, 6th International Conference on Concrete Repair, Thessaloniki, Greece, 20–23 June 2016. CRC Press. ISBN 978-1-315-31558-4. Archived from the original on September 5, 2023. Retrieved October 2, 2020.
↑ "Advantages of Mud-Jacking Grout for Use in Slab Leveling" (PDF). Archived (PDF) from the original on August 12, 2021.
↑ "Concrete Repair Best Practices A Series of Case Studies" (PDF). Archived (PDF) from the original on September 6, 2020.
↑ https://www.a1concrete.com/application/files/3215/6165/6803/AgLime_ConcreteLeveling_StrengthTest-1.pdf Archived September 5, 2023, at the Wayback Machine ^{[ bare URL PDF ]}
↑ https://www.a1concrete.com/application/files/4415/6165/6805/AgLime_ConcreteLeveling_StrengthTest-3.pdf ^{[ bare URL PDF ]}
↑ "Top Polyurethane Foam – Concrete Leveling Foam".
↑ Sivertsen, Katrine (Spring 2007). "Polymer Foams, 3.063 Polymer Physics" (PDF). Retrieved February 14, 2013.{{cite journal}}: Cite journal requires |journal= (help)
↑ "Technical Data Sheet, Precision Lift 4.0# – Components A and B" (PDF). Prime Resins, Inc. March 31, 2015. Archived from the original (PDF) on April 23, 2016. Retrieved April 13, 2016.
↑ "Slab Jacking With Polyurethane Foam – How Strong is Strong Enough?". Alchemy Polymers. June 12, 2013. Archived from the original on September 16, 2016. Retrieved September 9, 2016.
↑ National Concrete Polishing
↑ "Illinois Tollway Guidelines for Pavement Assets". Archived from the original on February 25, 2021.
↑ Wang, Jiao; Liu, Xianhua; Li, Yang; Powell, Trevor; Wang, Xin; Wang, Guangyi; Zhang, Pingping (November 15, 2019). "Microplastics as contaminants in the soil environment: A mini-review". Science of the Total Environment. 691: 848–857. Bibcode:2019ScTEn.691..848W. doi:10.1016/j.scitotenv.2019.07.209. PMID 31326808. S2CID 198132499.
↑ Thyssen, J; Kimmerle, G; Dickhaus, S; Emminger, E; Mohr, U (1978). "Inhalation studies with polyurethane foam dust in relation to respiratory tract carcinogenesis". Journal of Environmental Pathology and Toxicology. 1 (4): 501–8. PMID 722200.

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[1] Grantham, Michael (September 19, 2016). Concrete Solutions: Proceedings of Concrete Solutions, 6th International Conference on Concrete Repair, Thessaloniki, Greece, 20–23 June 2016. CRC Press. ISBN 978-1-315-31558-4. Archived from the original on September 5, 2023. Retrieved October 2, 2020.

[2] "Advantages of Mud-Jacking Grout for Use in Slab Leveling" (PDF). Archived (PDF) from the original on August 12, 2021.

[3] "Concrete Repair Best Practices A Series of Case Studies" (PDF). Archived (PDF) from the original on September 6, 2020.

[4] ttps://www.a1concrete.com/application/files/3215/6165/6803/AgLime_ConcreteLeveling_StrengthTest-1.pdf Archived September 5, 2023, at the Wayback Machine ^{[ bare URL PDF ]}

[5] ttps://www.a1concrete.com/application/files/4415/6165/6805/AgLime_ConcreteLeveling_StrengthTest-3.pdf ^{[ bare URL PDF ]}

[6] "Top Polyurethane Foam – Concrete Leveling Foam".

[MIT-7] Sivertsen, Katrine (Spring 2007). "Polymer Foams, 3.063 Polymer Physics" (PDF). Retrieved February 14, 2013.{{cite journal}}: Cite journal requires |journal= (help)

[8] "Technical Data Sheet, Precision Lift 4.0# – Components A and B" (PDF). Prime Resins, Inc. March 31, 2015. Archived from the original (PDF) on April 23, 2016. Retrieved April 13, 2016.

[9] "Slab Jacking With Polyurethane Foam – How Strong is Strong Enough?". Alchemy Polymers. June 12, 2013. Archived from the original on September 16, 2016. Retrieved September 9, 2016.

[10] National Concrete Polishing

[11] "Illinois Tollway Guidelines for Pavement Assets". Archived from the original on February 25, 2021.

[12] Wang, Jiao; Liu, Xianhua; Li, Yang; Powell, Trevor; Wang, Xin; Wang, Guangyi; Zhang, Pingping (November 15, 2019). "Microplastics as contaminants in the soil environment: A mini-review". Science of the Total Environment. 691: 848–857. Bibcode:2019ScTEn.691..848W. doi:10.1016/j.scitotenv.2019.07.209. PMID 31326808. S2CID 198132499.

[13] Thyssen, J; Kimmerle, G; Dickhaus, S; Emminger, E; Mohr, U (1978). "Inhalation studies with polyurethane foam dust in relation to respiratory tract carcinogenesis". Journal of Environmental Pathology and Toxicology. 1 (4): 501–8. PMID 722200.

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v t e Concrete
History	Ancient Roman architecture Roman architectural revolution Roman concrete Roman engineering Roman technology
Composition	Cement Portland cement Calcium aluminate cements Water Water–cement ratio Aggregate Reinforcement Fly ash Ground granulated blast-furnace slag Silica fume Metakaolin
Production	Plant Concrete mixer Volumetric mixer Reversing drum mixer Slump test Flow table test Curing Concrete cover Cover meter Rebar
Construction	Precast Cast-in-place Formwork Climbing formwork Slip forming Screed Power screed Finisher Grinder Power trowel Pump Float Sealer Tremie
Science	Properties Durability Degradation Environmental impact Recycling Segregation in concrete Alkali–silica reaction
Types	AstroCrete Energetically modified cement Fiber-reinforced Filigree Foam Lunarcrete Mass concrete Nanoconcrete Pervious Polished Polymer concrete Prestressed Ready-mix Reinforced Roller-compacting Ronsdale (natural) cement Self-consolidating Self-leveling Sulfur concrete Translucent concrete Aerated AAC RAAC
Applications	Slab (waffle, hollow-core, voided biaxial, slab on grade) Concrete block Step barrier Roads Columns Structures
Organizations	American Concrete Institute Concrete Society Institution of Structural Engineers Indian Concrete Institute Nanocem Portland Cement Association International Federation for Structural Concrete
Standards	Eurocode 2 EN 197-1 EN 206-1 EN 10080
Category:Concrete