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Epoxy versus Polyurethane Crack Injection

Epoxy vs Polyurethane Injection

Crack Injection Superheroes

Epoxy Resins versus Polyurethane Resins
A Concrete Crack Injection Comparison

Epoxy versus Polyurethane Crack Injection

Epoxy and Polyurethane Resin Based Crack Repair Systems are the Superheroes of Concrete Crack Repair

When you need to repair a crack in a concrete structure — such as a foundation or wall — from the inside (negative side) of the structure, there are typically two injection techniques and corresponding product technologies that you need to consider — epoxy resin injection and polyurethane chemical grout injection.

Epoxy Versus Polyurethane Injection – How to Differentiate the two Injection Methods and Techniques

Epoxy injection is typically performed on dry substrates versus polyurethane injection that works very well on wet and actively leaking substrates.

Fully cured high quality epoxy offers outstanding compressive and tensile strength properties, making epoxy injection the preferred method where structural crack repair is desired.

Polyurethane injection is performed to seal active leaks, prevent moisture migration and to protect structures from corrosion and water related decay. Polyurethanes are designed to interact and expand in contact with moisture, making polyurethane injection technology superior in wet and actively leaking environments.

There is an injection solution to most concrete crack related problems. But, there is no one-size-fits-all solution.

In this article we compare some of the main characteristics of each type of crack injection, outlining their strengths and their recommended range of applications.

Injection Repair Conditions and Objectives

Does your crack impact the structure?
Do you need to restore structural strength to the structure?
Does the crack carry water?
Is the crack actively leaking?
Do you need to protect the structure from water ingress and water damages?

Comparison of the Characteristics of Epoxy and Polyurethane Polymers and Elastomers

Epoxies and polyurethane polymers are chemical resins with different reaction profiles and physical properties.

Epoxy is a strong adhesive or glue that does essentially not expand. While curing epoxy creates a strong bond with the concrete substrate and ultimately provides a repair of high compressive and tensile strength properties.

Epoxy is a two component system, one component is the epoxy resin and the second is the hardener. The components are blended in the static mixer of the injection pump applicator immediately before crack injection. Injection epoxies cure chemically within a specified time and harden further over days and weeks.

Polyurethane injection foam is primarily a water activated sealant or leak-seal grout with expanding properties during reaction. The cured product creates a compression seal of varying flexibility.

Polyurethane foam resin often utilizes an activator or accelerator. Resin and activator are mixed before they are injected. Polyurethane resins are also available in two component chemical cure variants. No moisture needed.

Polyurethanes are extremely versatile. Their chemical and physical properties vary to suit the needs of specific applications and jobsite conditions.

Polyurethane resins vary from rigid and strong to flexible, rubbery and soft elastomer compositions. The initial cure time for crack injection polyurethanes is generally 1 – 10 minutes and is influenced by accelerator usage, temperature and moisture availability.

Differences in The Epoxy and Polyurethane Crack Injection Processes

Epoxy crack injections are typically performed at lower injection pressures (20-200 psi) and with surface mounted ports.

Polyurethane crack injection is often performed at higher pressures to move the expanding foam through the cracks with special injection pumps and packers installed into drilled holes. The injected polyurethane is supposed to fill the crack through the entire thickness of the structure thereby preventing water from entering the crack.

Epoxy Crack Injection

Structural Repair – The tensile strength and compression strength of cured epoxy is typically much greater than the strength of concrete making epoxy a good choice for foundation wall structural crack repair. When tension is applied to a crack due to thermal cycling or other forces, the cured epoxy crack repair will not typically yield. Epoxy is typically rigid and not flexible.
Extended curing time allows the epoxy to penetrate the crack and fine fissures. SealBoss epoxies can be obtained in various viscosities to suit fine to wide cracks.
Dry Substrate Recommended – Epoxy typically has reduced adhesion to wet and saturated surfaces. A dry environment is desired for best results. Actively Leaking Cracks – Epoxy cannot be used for actively leaking cracks. Epoxy resin needs to be contained in a crack until cured sufficiently to achieve full strength.
Epoxy injection is performed through surface mounted ports. Moisture adversely affects the adhesive qualities of the anchoring epoxy used to glue the injection ports onto the crack. Without sufficient bond strength, the anchoring epoxy will not withstand the pressure of the injection.
SealBoss provides mechanical packers and special plastic packers to permit epoxy injection in adverse environments.

Polyurethane Crack Injection

Wet and Dry Applications – Polyurethane injection foams and resins can be used in adverse environments regardless of the condition of the crack and the weather. The crack can be fine or wide, actively leaking, full of mud and/or mineral deposits. (Whenever possible it is advised to flush and clean out a crack prior to injection)
Water Stop and Structure Preservation – The rapid curing of polyurethane is beneficial when stopping a gushing leak. The chemical expansion of the polyurethane foam (typically 2-40 times its original volume) makes polyurethane very effective at filling voids within the concrete. Polyurethane resins and foams play an important role in preserving concrete and rebar.
Not a Structural Repair – Polyurethanes do not provide structural repairs in concrete cracks.
High injection pressures are often required to move PU foam into fine cracks and fissures.
Mechanical packers require drill holes. No matter if the crack is actively leaking, under water or the concrete is deteriorated, mechanical packers are designed to work in adverse environments.

Product Characteristics

EPOXY (EP)

Rigid, very strong adhesive for structural repairs
Mainly for dry or damp environments, potentially reduced adhesion on wet substrates
Excellent to regain structural strength in torn structures: earthquake damage, extended stress damage, shrinkage cracks, corrosion
Not a water-stop material and does not tolerate extended movement – cracks can form next to repair
Two component formulation – Quick reaction time and cure
Viscosities from very low liquid to paste
Very resistant, long term solution
Available in bulk and cartridges
Recommended Products:
Resins: 4040, 4050
Paste/Putty: 4500 Epoxy Quick Seal
Cartridge System: 4000 Epoxy Cartridge System
SealBoss Surface Mounted Ports / Injection Packers

POLYURETHANE (PU)

Flexible to semi-flexible sealants with less structural strength compared to EP
Typically Hydro-Active – reacts with water forming foams (water-stop & leak-seal), gels and solid (non cellular) flexible or semi flexible sealants
Two Component PU Resins can be dry reactive. No water needed
Classified as hydrophobic (foams/resins) for crack injection, joints voids or hydrophilic (foams/gels) for curtain, bladder injection behind structures. Both groups are water activated for use in wet environments
Superior water-stop capabilities
Single or two component, accelerators common. Viscosities low to medium. Very resistant, long term solution
Recommended Products:
Foams: 1510, 1570, 1570 LV
Flexible resin: 1403, 1503 LV-Resin Line
Gel/Foam: Flexgel2
Cartridge System Available

Epoxy versus Polyurethane – Conclusion

In non structural water related repairs PU is generally the material of choice. This is true for most below grade repairs including basements, tunnels, parking garages and manholes. PU is a good void filler and is also used to stabilize dirt and lift structures.

EP is an excellent adhesive for structural repairs of stressed concrete substrates and deteriorated concrete structures.

TIP

When initiating concrete crack injection, it’s advisable to commence with an exploratory grouting or mock-up injection stage. This entails identifying a deep, distinctly defined, and potentially actively leaking crack for the initial injection. This preliminary step facilitates the estimation of required material quantity and necessary injection pressures.

The consumption of material should be closely monitored and measured, and the injection pressures should be accurately assessed.

This process helps us understand the conditions of the project and plan the remaining injection process effectively.

Accessories

EPOXY (EP)

Surface port injection at lower injection pressures 30 – 100 psi — Reason: Injection is typically done in dry environments and surface ports can be attached easily with epoxy adhesive.
Holes do not have to be drilled – there are exceptions
The crack surface between the ports has to be surface sealed to prevent leakage during injection
The viscosity of the epoxy resin stays low during the injection process, resulting in lower injection pressures
Recommended Products:
Surface ports, specialty ports

POLYURETHANE (PU)

Mechanical packer injection at higher pressures 50 – 3000 psi — Reason: PU injection is often performed in a wet environment where adhesives for surface ports cannot be used.
Mechanical packers are installed by drilling a hole into the structure which the packer fits snugly. The packer is tightened mechanically for high pressure injection
PU Foam immediately reacts with moisture in the crack increasing resistance of product flow, resulting in higher injection pressures
Recommended Products:
Complete line of packers: S-Type, R-Type, custom sizes, Hammer-in packers, specialty packers

Conclusion:

PU generally needs higher pressures and therefor the more sophisticated connectors / packers. There are many exceptions. For example curtain injection with PU gel into the space between structure and soil needs lower injection pressures but higher rates of material flow. The filling of larger voids and joint injection also uses lower pressures. PU injection through surface ports is not common, but high pressure epoxy injection through packers is seen more frequently. Reasons could be very thick concrete to be penetrated or damp / wet surface conditions.

Pumps

EPOXY (EP)

Two component equipment for most epoxy resins for ease of use and precise mixing
Epoxy is a very strong adhesive and may render equipment unusable if not cleaned thoroughly
EP is not very moisture sensitive and not moisture reactive. Epoxy does not expand during reaction – which results in lower injection pressures
Pneumatic or manual guns for cartridge systems / smaller jobs
Two component injection pumps achieve high injection pressures for large volume commercial injection projects. Pumps are pneumatic or electric
SealBoss Corp. supplies EP resins and paste also in cartridges
Recommended Products:
Hand held guns, electric pump P3003, pneumatic pump PA3000, 4000 Cartridge System

POLYURETHANE (PU)

Single component equipment for most water activated hydrophobic PU foams, accelerator to be added prior to pumping
Either single or two component equipment for true two component PU resins such as 1400 LV-Resin Line
Either single component or multi-ratio two component equipment for hydrophilic PU Gels based on the application and product.
Single component pumps include inexpensive hand held devices, hand pumps and electric pumps
Multi ratio devices can be manual, electric and pneumatic. SealBoss Corp. supplies PU in bulk and in containers as small as 1 gal units and in cartridges
Recommended Products:
Hand held guns, manual pumps, electric pumps, Signature Line Pumps

Choose Your Pump:

No matter if you are faced with a minor basement leak or a major tunnel gusher of large hydrostatic pressure , we have you covered. You need to have the right tools at hand to achieve the results. SealBoss infrastructure repair pumps provide you with tried and true concrete solutions.

Final Thoughts:

Over the years, injection technology has evolved, becoming both sophisticated and intricate. At SealBoss, we pride ourselves on offering a diverse range of products, pumps, and accessories tailored to meet the ever-growing needs of injection applications.

Our commitment extends beyond just providing products; we offer comprehensive technical support to ensure you find the perfect product-equipment synergy for your project’s success. We invite you to leverage our expertise and training resources. Remember, we are only a phone call away, eager to assist and guide you.

SealBoss ® EPOXY

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SealBoss ® POLYURETHANE

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Contact Your SealBoss ® Technician

Epoxy Crack Injection Concrete Repair

Epoxy Crack Injection
Concrete Repair

Epoxy Concrete Crack Injection Systems

Epoxy Crack Injection Resin can mitigate problems of cracked concrete with larger and fine cracks. ACI specifies cracks widths that are acceptable in structures under defined conditions. ACI 224R-012 provides a guideline for crack widths for reinforced concrete under service loads for new construction. Crack widths deemed acceptable may range from 0.004 in. (0.1 mm) to 0.016 in. (0.41 mm), and even smaller widths for concrete in wet or aggressive environments. These crack dimensions would be considered fine and hairline cracks.

Pushing the Envelope – SealBoss Epoxy Systems
– Resins, Pastes, Injection Ports and Pumps –

Epoxy Crack Injection

Cracking does not always affect structural performance, but it can adversely affect the durability of structures.

Common causes of concrete cracking are post cure and drying shrinkage, thermal stress, chemical reaction caused by alkali-reactive silica & sulfates, freezing and thaw cycles due to water expansion, corrosion of steel rebar, settlement, load stresses, construction short comings such as design and construction errors.

The incorporation of steel reinforcement within structural concrete allows these elements to function under both compression and tension, frequently resulting in tension-induced fracturing of the concrete in certain regions.

Water is a major contributor to concrete corrosion in parking garages, bridges, industrial facilities and more. Water, chloride and carbon dioxide can migrate deep into the structure initiating corrosion of the reinforcement structure.

Water ingress, facilitated by fissures or compromised joints, often carries corrosive substances and chlorides that contribute to the degradation of concrete and the corrosion of steel reinforcements and rebar. Fortunately, epoxy concrete crack injection can address many of these concerns in structures exhibiting signs of such issues. Employing a proficient concrete repair team can frequently circumvent the need for a complete teardown.

SealBoss Epoxy Resins

SealBoss Epoxy Crack Injection resins for structural crack repairs conform to ASTM C881 specifications, with appropriate viscosities for the crack widths. The bond strength of epoxy to clean concrete is greater than the tensile strength of concrete itself.

Wider cracks may require a higher viscosity epoxy, small cracks a lower viscosity injection resin. Depending on the requirements, viscosities may range from approximately 150 to 600 cps at room temperature.

SealBoss Epoxy Crack Injection concrete repair can be performed with SealBoss Epoxy Cartridge Systems or SealBoss epoxy bulk resins using air guns, hand-actuated delivery systems, or dual-component injection electric or air-driven pumps.

Prior to repair, the structure must be carefully examined to establish that epoxy crack injection is indeed the correct method to regain the desired structural integrity. The cause of cracking must be determined. Cracks must be identified and the allowable crack width needs to be established. The width of cracks can be measured by using crack gauge cards. In some instances it may be recommended to measure the expansion and contraction cycles of a crack. To determine the depth and cause of cracking, core samples can be taken and examined by petrographic and chemical testing. In addition, nondestructive testing (NDT) ultrasonic pulse velocity can be used to measure the depth of cracks.

Once it has been established that epoxy concrete crack injection is the chosen method of repair, the SealBoss Epoxy Injection System can be utilized to restore the structural integrity of the concrete.

SealBoss ® Surface Mount Injection Ports

Surface-mounted injection ports are typically adequate for injecting most cracks. However, badly deteriorated concrete or higher injection pressures may require the use of drill-in or hammer-in plastic ports or even mechanical packers. Surface ports, aka plastic tubing ports, are glued on the surface over the open cracks using SealBoss epoxy paste adhesive. The injection ports are typically installed at a spacing that is equal to or slightly narrower than the depth of the crack. Hairline cracks require closer spacing than wider cracks.

Wire brushing and vacuuming the crack surface along the crack is often sufficient for surface preparation. In areas of badly deteriorated concrete, pressure washing, grinding, and V-grooving may be specified.

After the surface has been cleaned, surface ports are installed. Sealboss 4500 crack-sealer epoxy paste will be used as surface port adhesive and be applied on the face of the crack between and around the ports.

Once the injection ports are installed, Sealboss 4500 crack-sealer epoxy paste is applied on the face of the crack between and around the ports. To contain the epoxy resin in the crack until it hardens, it is a good practice to seal cracks on all sides of the substrate if possible.

Begin the Epoxy Crack Injection at the Point of the Structure

As soon as the epoxy appears at the next higher port, the current port is capped and the injection is continued from the next port. Multi port injection may be used in most epoxy injection environments. Typical injection pressures are between 50 to 100 psi (3 to 6 bars), with very fine cracks requiring pressures of over 200 psi (12 bars).

Epoxy resins are temperature sensitive. At higher temperatures resin viscosity decreases, but reaction time increases. For best performance during application, it is advised to keep the resin at room temperature or slightly above during injection.

After the injection resin has cured, the epoxy paste adhesive is removed from the surface of the concrete.

Quality assurance and control measures include visual observation of the injection process and product consumption, testing the injection equipment for mix ratio, taking core samples and testing repaired cracks using nondestructive testing methods.

Epoxy Crack Injection System – Epoxy Resins, Ports, Pumps

SealBoss epoxy injection system solution.
Ranging from epoxy resins and structural epoxy gels to injection ports and two component epoxy pumps.

SealBoss ® 4040 LV

SealBoss Highest Quality Epoxy Standard

Injection Epoxy Resin
Multi-Use Epoxy Resin

4040 low viscosity, 100% solids, hi-mod, 2-component, moisture-tolerant, low-viscosity, high strength, multi purpose, epoxy injection resin adhesive

– Commercial Bulk Packaging
– Cartridge System

SealBoss ® 4050 SLV

Super Low Viscosity Epoxy Resin

4050 super low viscosity, 100% solids, hi-mod,
2-component, moisture-tolerant, low-viscosity, high strength, epoxy injection resin adhesive

– Commercial Bulk Packaging
– Cartridge System

SealBoss ® 4500 F

SealBoss Highest Quality Epoxy Standard

Fast Cure Epoxy Paste

Epoxy paste products for surface repairs, to prepare cracks for resin injection, and to bond SealBoss surface ports. 4500 NSF Drinking Water Approved Formula available.

– Commercial Bulk Packaging
– Cartridge System

1/4 EPOXY PORT | TRIBASE PORT
SURFACE MOUNTED PORT

SURFACE PORT

Epoxy Injection Port – Industry Standard Bestseller

Durable plastic design surface mounted port suitable for epoxy injections. Tri-Base design with perforation holes for best possible adhesion with SealBoss 4500 Epoxy Paste Adhesive. Caps included. For EP grouts.

Bestseller – a SealBoss Standard

1/4 EPOXY PORT | TRIBASE PORT
SURFACE MOUNTED PORT

1/2" EPOXY DRILL HOLE / HAMMER-IN PORT

‘BELOW’ SURFACE PORT

Epoxy Injection Drill Hole Mount Port

Durable plastic port designed to fit 1/2″ drill hole for higher injection pressures than regular surface ports. Suitable for epoxy injections. Caps included. For EP grouts.

1/2" EPOXY DRILL HOLE / HAMMER-IN PORT

PA3000 The Epoxy Pump Standard

High & Low Pressure
Epoxy Injection & Polyurethane Injection

Top of the Line – Professional Use
Pumps Epoxy & PU resin
Pneumatic
850 psi
2 Comp.
Ratio: 2:1 Standard, 1:1 custom

P3003-2C PUR & Epoxy Pump

High & Low Pressure
Epoxy & Polyurethane Injection Piston System

Versatile,
Pumps Epoxy & PU Resin
Electric Drill Operated
Dual Piston System
5000 psi
2 Comp.
Ratio: 2:1 standard, 1:1 custom

SealBoss ® Epoxy

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epoxy

Contact Your SealBoss ® Technician

Epoxy Injection in Cold Weather

Epoxy Injection
In Cold Weather

Overcoming the Challenges

Cold weather can complicate concrete repair and waterproofing, especially when working with chemical grouts like polyurethane foams, gels and, in this case, epoxy resins. All theses polymer products rely on temperature for proper curing.

Despite an incoming cold front, a mock-up epoxy injection training session had to proceed. With careful preparation and the right tools, such as heat guns to warm resins and surfaces, the team was able to successfully navigate the chilly conditions.

This cold Thursday morning was no exception to the rule. During a mock-up epoxy injection training an impending cold front was on its way toward Oregon and Washington states, resulting in unusually cold temperatures. However, when a crew needs to receive proper technical training on Sealboss Systems, the show must go on.

We Provide Training in All Conditions

A week prior to the training we wanted to make sure that we were prepared so that everybody in attendance could get the most out of the experience. We proactively sent an email to the contractor requesting that they provide the ancillary items necessary to make the training as efficient and effective as possible.

One of the items requested was a focused source of heat in the way of a heat gun. We were very pleased to see that they were prepared with two heat guns which enabled them to speed up the setting process for the crack seal paste. When chemistry is at play, temperature is a very important factor. In almost all cases, heat will speed up reactions between different chemicals.

In cold weather it is critical to precondition the epoxy resins to room temperature prior to use. Epoxy resins may not react below 35-45°F, but will begin to cure again once the temperature rises. A heat gun can be used to warm up the concrete surface prior to installing surface mounted ports and to increase the temperature of the installed epoxy adhesive to approximately 100°F or 40°C to initiate the exothermic reaction and speed up the cure time. Take care to avoid heating the surface or epoxy to over 130°F or 55°C .

While there are many things out of everyone’s control such as the weather, those things that are in our grasp ought to be executed to the best of everyone’s ability thanks to the preparedness from all members involved with this session, the team was able to benefit from and learn the basics as it relates to structural epoxy injection all the way from port setting to clean out of the pump.

Please inquire about training opportunities with your local SealBoss representative.

We are standing by to do what we can to make sure your teams have the requisite knowledge to be successful when it comes to using SealBoss Systems.

Concrete Wall Repair

Structural Concrete Wall Repair with Epoxy Injection

Introduction

Concrete walls are integral to the structural stability of countless buildings and infrastructure projects. Over time, however, even the most robust walls can develop cracks due to factors such as settling, weather conditions, and material fatigue. These cracks compromise structural integrity, safety, and longevity, necessitating timely and effective repair solutions.

Epoxy injection systems have emerged as a gold standard in addressing these challenges, offering precision, durability, and cost-effectiveness. By filling cracks and restoring the original strength of concrete, these systems prevent further damage and extend the life of the structure. This article discusses the transformative impact of epoxy injection technology, exploring a major structural repair project that highlights the efficiency and reliability of SealBoss systems in concrete wall repair.

Concrete Wall Repair using Structural Epoxy Resins

Massive Concrete Wall Repair: Advanced Solutions with Epoxy Injection Systems

Structural integrity is vital for the durability and safety of any concrete wall, whether designed for soil retention, seawall protection, or other applications.

Cracks represent one of the most significant threats to this stability, as they can undermine both the strength and longevity of the structure if not promptly addressed. Effective concrete wall repair not only restores structural soundness but also prevents further damage and potential failure. Epoxy injection systems offer precision, efficiency, and long-term durability, making them a premier solution for concrete crack repair. This article explores the application of SealBoss epoxy injection systems in a major structural repair project, showcasing the effectiveness of these advanced systems.

Project Overview: Prestigious Estate Repair

A prestigious estate in Texas faced a significant structural challenge: Several thousand feet of cracks in a major concrete retaining wall. Addressing this critical issue required an immediate and effective concrete wall repair solution to ensure the wall’s long-term stability and safety. An experienced epoxy injection contractor leveraged SealBoss’s epoxy injection technology to deliver outstanding results in this high-profile project.

Step-by-Step Approach to Concrete Wall Repair

Preparation Phase

Thorough preparation is essential for successful concrete crack repair. For this project, the preparation phase spanned an entire week. During this period, the team:

Set Injection Ports: Several thousand surface-mounted tribase ports were strategically installed along the length of the cracks to serve as controlled entry points for the epoxy injection.

Applied SealBoss 4500 Epoxy Paste: This high-performance paste was used to seal the surface of the crack and secure the ports. Its strong adhesion ensured a reliable barrier, preventing leakage during the injection process.

Injection Process

After completing the preparation, the team began the injection stage using the SealBoss P3003-2C pump. This state-of-the-art pump, designed for high-pressure injection, ensured efficient and controlled delivery of SealBoss 4040 epoxy resin deep into the crack. Remarkably, the entire injection process was completed in just 25 minutes, demonstrating the efficiency of SealBoss systems for concrete wall repair.

Materials Utilized

The success of this project relied heavily on the quality and compatibility of the materials used. Key components included:

SealBoss P3003-2C Pump: A dual-component injection pump that ensured precise mixing and application of the epoxy resin.
Static Mixers: These devices ensured uniform mixing of the epoxy components for consistent performance throughout the process.
Surface-Mounted Tribase Ports: Several thousand ports were used to treat the crack effectively, providing targeted delivery and maximizing repair outcomes.
SealBoss 4040 Epoxy Resin: This low-viscosity resin penetrated deep into the crack, offering exceptional strength, durability, and chemical resistance.
SealBoss 4500 Epoxy Paste: Used to secure the ports and seal the crack’s surface, this paste contributed to the long-term durability of the repair.

Key Features of SealBoss Epoxy Injection Systems

SealBoss epoxy injection systems provide a host of features that make them ideal for addressing structural issues in concrete walls:

Low-Viscosity Penetration

SealBoss epoxy resins are designed to penetrate even the finest cracks, ensuring comprehensive sealing and structural bonding. This is particularly effective for narrow and deep cracks that are otherwise difficult to address.

High Compressive and Tensile Strength

Once cured, SealBoss epoxies offer exceptional mechanical properties, restoring the original strength and load-bearing capacity of the concrete structure. This makes them suitable for high-stress applications.

Chemical Resistance

SealBoss epoxy systems are resistant to a wide range of chemicals, including oils, fuels, and solvents. This ensures long-term performance in environments subject to chemical exposure.

Cost-Effective Solutions

By extending the lifespan of the structure and minimizing the need for extensive demolition and reconstruction, epoxy injection systems offer a cost-effective alternative to traditional repair methods.

Video: Concrete Wall Repair with SealBoss Epoxy Injection Systems

Why Choose Epoxy Injection for Concrete Wall Repair?

Epoxy injection has become the gold standard for concrete crack repair due to its many advantages:

Restoration of Structural Integrity: Epoxy effectively bonds concrete components, returning the structure to its original strength.
Prevention of Further Damage: Properly sealed cracks prevent water infiltration, reducing the risk of corrosion, freeze-thaw damage, and chemical deterioration.
Versatility: Epoxy injection systems can address a wide range of crack widths and depths, making them suitable for various applications.
Efficiency: Advanced equipment like the SealBoss P3003-2C pump ensures quick and precise application, reducing downtime.

Long-Term Benefits of Epoxy Injection Systems

Prolonged Lifespan of Structures

By addressing cracks early and effectively, epoxy injection systems significantly extend the lifespan of concrete walls and other structures.

Enhanced Safety

Restoring structural integrity ensures that the repaired wall can continue to bear loads safely, reducing the risk of failure.

Environmental Benefits

Epoxy injection minimizes waste and resource use by repairing, rather than replacing, damaged structures. This makes it an eco-friendly option for concrete wall repair.

Lessons from the Major Structural Concrete Wall Repair Project

This case study provides valuable insights into best practices for concrete wall repair:

Thorough Preparation is Key

Detailed preparation, including the proper placement of surface ports and the use of high quality non sag and quick cure epoxy paste, ensures a seamless injection process and optimal results.

Advanced Equipment Makes a Difference

The SealBoss P3003-2C pump’s light weight, ease of operation, two component ratio precision, and reliability played a crucial role in the project’s success, demonstrating the importance of high-quality tools.

Material Quality Matters

Using premium products like SealBoss 4040 epoxy resin and 4500 epoxy paste ensures correct setting times, suitable viscosities, durability and long-term effectiveness.

Conclusion

Concrete wall repair, as demonstrated in this major structural repair project, benefits significantly from the precision, efficiency, and durability of epoxy injection systems. SealBoss’s advanced materials and equipment, combined with skilled execution, offer a proven solution for restoring and preserving concrete structures. Whether addressing minor cracks or significant structural damage, SealBoss epoxy injection systems provide an effective and reliable pathway to long-term stability and safety. For contractors and engineers seeking efficient, cost-effective solutions, epoxy injection stands out as a best-in-class method for concrete crack repair.

SealBoss ® 4040 LV

SealBoss Highest Quality Epoxy Standard

Injection Epoxy Resin
Multi-Use Epoxy Resin

4040 low viscosity, 100% solids, hi-mod, 2-component, moisture-tolerant, low-viscosity, high strength, multi purpose, epoxy injection resin adhesive

– Commercial Bulk Packaging
– Cartridge System

SealBoss ® 4500 F

SealBoss Highest Quality Epoxy Standard

Fast Cure Epoxy Paste

Epoxy paste products for surface repairs, to prepare cracks for resin injection, and to bond SealBoss surface ports. 4500 NSF Drinking Water Approved Formula available.

– Commercial Bulk Packaging
– Cartridge System

1/4 EPOXY PORT | TRIBASE PORT
SURFACE MOUNTED PORT

SURFACE PORT

Epoxy Injection Port – Industry Standard Bestseller

Bestseller – a SealBoss Standard

1/4 EPOXY PORT | TRIBASE PORT
SURFACE MOUNTED PORT

P3003-2C PUR & Epoxy Pump

High & Low Pressure
Epoxy & Polyurethane Injection Piston System

Versatile,
Pumps Epoxy & PU Resin
Electric Drill Operated
Dual Piston System
5000 psi
2 Comp.
Ratio: 2:1 standard, 1:1 custom

Concrete Wall Repair Epoxy System

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Injection

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Concrete Crack Repair

A Quick Guide to Polymer Grout Injection

Introduction:

Concrete structures are highly valued in construction for their durability and strength, but even the most resilient concrete can develop cracks over time. Concrete crack repair is essential to maintain both the structural integrity and the appearance of concrete buildings and infrastructure. Among the most effective techniques is polymer grout injection, which includes using polyurethane resins and foams, acrylates, and epoxy resins. This guide explores these polymer-based injection methods, their benefits, and detailed processes to ensure effective concrete crack repair.

Polymer Grout Injection for Concrete Crack Repair

Injection grouting is a versatile and widely adopted technique for concrete crack repair. It involves injecting specialized liquid grouts into cracks within the concrete under pressure.

As the grout hardens, it seals the cracks while either creating a flexible waterproof seal or restoring the structural integrity of the concrete using high-strength bonding agents.

This article covers three main types of polymer grouts for concrete crack repair:

Polyurethane resins and foams, acrylates, and epoxy resins.

Concrete Crack Repair with Polyurethane Resin and Foam Injection

Polyurethane resin and foam are excellent and highly effective for waterproofing and sealing cracks in concrete structures. Known for their flexibility, polyurethane-based resin and foam solutions are ideal for concrete crack repairs in foundations, basements, retaining walls, dams and concrete structures where water ingress poses a significant problem.

Benefits of Polyurethane Injection for Concrete Crack Repair:

Flexible waterproof seal: Accommodates movement in concrete
Water stop and moisture barrier: Prevents water infiltration
Structural reinforcement: Inhibiting further deterioration of concrete.

Process Overview:

Drill holes at regular intervals along the crack based on conditions
Clean the cracks and holes
Install injection packers into the drilled holes
Inject polyurethane resin starting from the lowest point
Remove injection ports

Polyurethane resins are ideal for waterproofing as they form a watertight seal, preventing water ingress in basements and other below-grade structures. These resins also add structural integrity to the concrete by filling the cracks and preventing further deterioration.

The injection process begins with drilling holes along the length of the crack at regular intervals. The spacing of the holes depends on the size and extent of the crack. The cracks and drilled holes are then thoroughly cleaned to remove any dust, debris, or contaminants, ensuring proper adhesion of the polyurethane resin.

Injection ports, also known as packers, are installed into the drilled holes to prevent leakage during the injection process. The polyurethane resin is injected starting from the lowest point if the crack is vertical or from one end if it is horizontal, continuing until the resin appears at the next port or from the surface.

After the resin has cured, the injection ports are removed and the surface is cleaned. If necessary, the area is ground or sanded to match the surrounding concrete.

Concrete Crack Repair with Acrylate Injection

Acrylate injection grouts are popular for concrete crack repair due to their super low viscosity and fast-setting characteristics. Acrylates are well-suited for fine cracks and are often used in curtain injection to create a waterproof barrier behind the concrete.

Benefits of Acrylate Injection for Concrete Crack Repair:

Super Low viscosity: Penetrates very fine cracks and fissures
Fast setting: Ideal for curtain injection
Versatility: Suitable for various leak and moisture conditions

Process Overview:

For curtain injection drill holes in a pattern at suitable intervals through the structure to create a bladder/curtain seal on the positive side behind the structure
Clean the cracks and holes to remove contaminants
Install injection ports
Inject acrylate grout starting from the lowest point
Remove ports and clean the surface

Due to their low viscosity, acrylates can migrate through very fine cracks that other grouts cannot, making them ideal for situations where other resins cannot penetrate.

The injection process for acrylates begins with drilling holes along the crack at intervals suitable for the size of the crack. The cracks and holes are then thoroughly cleaned to remove any contaminants.

Injection ports are installed into the drilled holes and securely placed to prevent leakage. The acrylate is injected starting from the lowest point or one end of the crack, continuing until the acrylate appears at the next port or the surface. Once the acrylate has cured, the injection ports are removed and the surface is cleaned.

Concrete Crack Repair with Epoxy Injection

Epoxy injection is widely recognized for its high strength and bonding capabilities,making it an excellent choice for structural concrete crack repair. Epoxy resins not only restore the strength of concrete but also create a durable, watertight seal.

Benefits of Epoxy Injection for Concrete Crack Repair:

High tensile and compressive strength: Restores structural integrity to concrete
Versatility in viscosity: Can repair both fine and wide cracks
Outstanding bonding: Forms a permanent bond with the concrete

Process Overview:

Install surface ports over the crack
Seal the crack between the ports
Inject epoxy resin starting from the bottom of the crack
Remove the ports and finish by cleaning and grinding

Epoxy resin formulations provide high tensile and compressive strength, making them ideal for restoring the structural properties of compromised cracked concrete. Available in varying viscosities, epoxy can be used to repair both hairline and wider cracks.

The injection process for epoxy begins with placing surface ports over the crack and bonding them using a fast setting epoxy paste. The crack between the packers is sealed using the same fast cure epoxy paste to prevent epoxy leakage.

The epoxy resin is injected starting from the bottom of the crack and working up, continuing until the epoxy appears at the next surface port. After the epoxy has cured, the injection ports are removed. If necessary, the area is ground or sanded to match the surrounding concrete.

Conclusion - Why Polymer Grout Injection is Ideal for Concrete Crack Repair

Polymer grout injection—which includes using polyurethane resins, acrylates, and epoxy resins—is one of the most effective methods for concrete crack repair. Each type of grout offers unique properties that make it suitable for specific applications, from waterproofing to structural reinforcement. By following the correct procedures and selecting the right materials, repair professionals can successfully restore and preserve the integrity and appearance of concrete structures.

If you need guidance or technical support for your concrete crack repair projects, consult with industry experts. SealBoss offers comprehensive solutions and expert assistance to help you achieve long-lasting results in your concrete crack repair efforts.

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Types of Concrete Cracks

A Concrete Crack Overview

Introduction:

Concrete structures can experience a range of cracks due to various causes, including environmental factors, structural issues, and material weaknesses. As a concrete repair professional, understanding these different crack types and how to address them using suitable repair methods—such as polyurethane resin, foam injection, acrylate gel, and epoxy injection—is essential for maintaining the integrity and longevity of concrete structures.

For Concrete Crack Repair Details read our Quick Guide

Concrete Crack Repair – A Quick Guide to Polymer Grout Injection

Types of Concrete Cracks

Shrinkage Cracks in Concrete
Shrinkage cracks occur when hardened concrete loses moisture during the curing process, causing it to contract. These cracks are common in driveways, slabs, and foundation walls. As concrete dries over time, this moisture loss can lead to shrinkage if the concrete is restrained, resulting in cracks. These cracks may be larger and can appear throughout the structure.
Cause: Uneven moisture loss and restraint in the structure.
Repair Solution: Polyurethane resin, foam injection, depending on the severity and circumstances, to seal the cracks, prevent moisture ingress, or, in some cases, epoxy injection to regain structural strength.
Plastic Shrinkage Cracks in Concrete
Plastic shrinkage cracks form while the concrete is still in its plastic (unhardened) state. They result from rapid moisture evaporation from the surface, often due to high temperatures, low humidity, or strong winds. These shallow cracks resemble a spiderweb pattern and typically affect newly poured slabs.
Unlike regular shrinkage cracks, which develop after the concrete has hardened and contracted over time, plastic shrinkage cracks appear within the first few hours after pouring, making them a common issue in newly poured slabs or exposed surfaces. These cracks are typically shallow and widespread across the surface, while regular shrinkage cracks are generally larger and occur throughout hardened concrete structures.
Cause: Rapid moisture loss from the surface during curing.
Repair Solution: Typically Polyurethane resin, foam injection, depending on the severity and circumstances, to seal the cracks, prevent moisture ingress. Acrylate gel in some cases.
Spalling Concrete Cracks
Spalling occurs when sections of concrete break away from the surface, exposing the reinforcing steel. This typically results from corrosion within the steel, causing it to expand and exert pressure on the surrounding concrete.
Cause: Corrosion of embedded reinforcing steel.
Repair Solution: Epoxy injection to fill and bond the cracks, combined with a surface coating to prevent future corrosion.
D-Cracking in Concrete
Durability cracking, or D-Cracking, results from concrete’s inability to withstand freeze-thaw conditions. It usually manifests as cracks running parallel to joints or linear cracks, often with discoloration around the affected area. D-Cracking is primarily caused by the use of coarse aggregates that trap moisture, which expands during freezing and leads to cracking over time.
Cause: Coarse aggregates that absorb moisture and expand during freezing.
Repair Solution: Polyurethane injection, which remains flexible during freeze-thaw cycles.
Corrosion Cracks in Concrete
Corrosion cracks develop due to the rusting of steel reinforcement embedded in concrete. As the steel corrodes, it expands, creating internal pressure that leads to cracking.
Cause: Rusting of embedded steel.
Repair Solution: Polyurethane resin, foam injection, depending on the severity and circumstances, to seal the cracks, prevent moisture ingress, or epoxy injection to regain structural strength.
Stress Corrosion Cracks in Concrete
Stress corrosion cracks arise from a combination of tensile stress and a corrosive environment. These cracks are common in marine structures, bridges exposed to de-icing salts, or industrial facilities where chemical exposure is prevalent. This phenomenon often involves the interaction of aggressive chemicals (like chlorides or sulfates) with embedded steel reinforcement, resulting in cracks that may propagate rapidly under continued stress.
Cause: Interaction of tensile stress with corrosive chemicals.
Repair Solution: Polyurethane resin, foam injection, depending on the severity and circumstances, to seal the cracks, prevent moisture ingress, or epoxy injection to regain structural strength.
Overloading Cracks in Concrete
Overloading cracks develop when concrete structures bear more weight than they were designed to handle. These cracks usually occur in heavily trafficked areas like driveways or industrial floors where heavy machinery operates.
Cause: Excessive loads exceeding the design capacity.
Repair Solution: Most likely high-strength epoxy injection to restore structural integrity.
Concrete Expansion Cracks
Expansion cracks develop when concrete expands due to heat, exerting pressure on the structure. Like most materials, concrete expands when heated, and if it lacks sufficient space to expand, the resulting internal stress can cause cracks. Expansion joints are often installed to provide relief and absorb the stress of expanding concrete.

Cause: Thermal expansion without adequate expansion joints.
Repair Solution: Polyurethane foam injection, which is flexible enough to accommodate movement.
Heaving Cracks in Concrete
Heaving cracks typically occur in cold climates where freeze-thaw cycles are common. When water within the concrete freezes, it expands considerably, causing the concrete slab to lift or “heave.” As temperatures rise and the ice melts, the slab settles back down, leading to the formation of cracks due to the constant movement. This can be prevented by allowing space for expansion and contraction.
Cause: Freeze-thaw cycles and temperature changes.
Repair Solution: Flexible polyurethane foam that can expand and contract with temperature variations.
Crazing and Crusting Cracks in Concrete
Crazing refers to shallow, fine cracks resembling spider webs that appear due to premature drying. Crusting, on the other hand, occurs when the top surface dries faster than the bottom during stamping. While these cracks are not usually structural concerns, they can impact aesthetics and lead to moisture ingress.
Cause: Uneven drying during the curing or stamping process.
Repair Solution: Low-viscosity polyurethane foam for sealing and moisture protection.
Disintegration Cracks in Concrete
Disintegration cracks are a result of the gradual breakdown of concrete, starting with surface scaling and leading to large pieces breaking away. Disintegration often results from chemical attacks like carbonation or sulfate exposure and poor construction practices.
Cause: Chemical attacks or poor-quality aggregates.
Repair Solution: High-strength epoxy injection to reinforce the structure and sealant application to prevent further chemical exposure.
Re-Entrant Corner Cracks in Concrete
Re-entrant corner cracks occur at areas with abrupt changes in geometry, such as around columns, pipe penetrations, sharp corners column bases, pipe penetrations, around rounded objects like manholes, and intersections where slab and wall joints meet. As the concrete dries, uneven shrinkage around these regions creates stress concentrations that lead to cracking.
Cause: Stress concentration around corners or openings.
Repair Solution: Polyurethane resin, foam injection, depending on the severity and circumstances, to seal the cracks, prevent moisture ingress, or, epoxy injection to regain structural strength.
Alkali-Silica Reaction (ASR) Cracks in Concrete
Alkali-Silica Reaction (ASR), also known as concrete cancer, is a harmful chemical reaction between highly alkaline cement paste and reactive silica in aggregates. This reaction produces a hygroscopic gel that absorbs water, expands, exerts internal pressure, and progressive loss of concrete strength leading to map cracking, also known as pattern cracking or alligator cracking. This distinct crack pattern consists of randomly-oriented, web-like cracks on the surface of concrete elements that move in multiple directions.
Cause: Reaction between alkaline cement and reactive silica.
Repair Solution: Polyurethane resin, foam injection, depending on the severity and circumstances, to seal the cracks, prevent moisture ingress, or epoxy injection to regain structural strength.

Choosing the Right Repair Method for many Types of Concrete Cracks

When selecting a repair method for different types of cracks, consider the crack’s cause, size, and impact on the structure:

Polyurethane Foam and Resin Injection: Ideal for flexible sealing in areas with moisture issues and minor movements. Works well for sealing finest cracks as well as large voids or areas prone to temperature changes, due to its expanding and flexible properties.
Acrylate Gel: Perfect for curtain injection and super fine hairline cracks.
Epoxy Injection: Best suited for structural repairs of cracks requiring high strength and load-bearing restoration.

Conclusion

Concrete cracks are an inevitable challenge for any concrete structure due to the diverse range of factors that can cause them, such as environmental conditions, structural issues, and material weaknesses. Understanding the different types of concrete cracks, such as shrinkage cracks, plastic shrinkage cracks, spalling, D-cracking, and more, is crucial for professionals tasked with maintaining the structural integrity of concrete elements.

By recognizing the root causes of these cracks, repair professionals can determine the most effective methods for restoration. For example, structural cracks due to overloading or stress corrosion may require high-strength epoxy injection to restore the original load-bearing capacity, while cracks resulting from freeze-thaw cycles or moisture ingress are better addressed using flexible polyurethane foam injections. For fine hairline cracks or moisture control in large sections, acrylate gels provide a versatile and efficient solution.

Proper selection of repair materials and techniques not only helps in addressing visible damage but also aids in preventing future deterioration, extending the life of the concrete structure. Each crack type demands careful evaluation to choose the right repair approach, ensuring both safety and durability.

Polymer-based injections, including polyurethane resins, foams, acrylates, and epoxies, offer comprehensive solutions for addressing a wide variety of concrete cracks. They provide the versatility to handle anything from superficial fine cracks to deep structural fissures, making them indispensable for professionals committed to maintaining the integrity of concrete elements.

By integrating these repair methods into their toolkit, professionals can confidently tackle any concrete crack repair challenge, ensuring long-term durability and safety for the structures they manage. As always, consulting experts and selecting high-quality products for each specific application remains key to achieving successful and lasting results.

To learn more about how to approach specific concrete crack repair projects, explore our Concrete Crack Repair Quick Guide

Concrete Crack Repair – A Quick Guide to Polymer Grout Injection

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Bridge Crack Repair

Structural Epoxy Injection with Professional Equipment

Structural Epoxy Injection & Equipment for Bridge Crack Repair

Bridges, crucial for transport and commerce, often face damage from harsh environments and heavy traffic, leading to cracks and structural issues.

A cost-effective solution is crucial for maintaining bridge safety, and structural epoxy injection has become a popular method to repair cracks and restore integrity without expensive replacements.

Structural Epoxy Injection & Equipment for Bridge Crack Repair

Bridges, crucial for transport and commerce, often face damage from harsh environments and heavy traffic, leading to cracks and structural issues.

A cost-effective solution is crucial for maintaining bridge safety, and structural epoxy injection has become a popular method to repair cracks and restore integrity without expensive replacements.

Bridge Crack Repair:
Enhancing Structural Integrity with Advanced Epoxy Injection Solutions

Bridges serve as vital arteries for transportation and commerce, constantly bearing the brunt of heavy traffic and exposure to harsh environmental conditions. Over time, this wear and tear can lead to cracks and other structural issues that compromise their integrity. Addressing these problems promptly is critical for ensuring public safety and the longevity of these essential infrastructure elements.

When it comes to repairing bridge cracks, contractors and engineers are turning to cost-effective and efficient solutions like structural epoxy injection. This technique has proven to be an industry-standard for restoring the structural integrity of bridges without the costly and time-consuming process of complete replacements.

Structural Epoxy Injection:
A Reliable and Cost-Effective Solution for Bridge Crack Repair

Structural epoxy injection is a cutting-edge method that involves injecting specially formulated epoxy resins into cracks. These resins fill and bond the gaps, significantly enhancing the strength and stability of the entire structure. Let us explore why epoxy injection is a preferred solution for bridge crack repair.

Structural epoxy injection offers several benefits, including:

Cost-effectiveness: By utilizing structural epoxy injection, unnecessary expenditures on demolishing and rebuilding can be avoided. This approach cuts down on both material and labor costs, making it a budget-friendly solution.
Time savings: Compared to traditional repair methods, structural epoxy injection is significantly faster, leading to minimal disruptions and reduced downtime for bridge traffic.
Versatility: Whether the bridge is made of concrete, steel, or masonry, epoxy injection can effectively repair a wide range of structural materials, making it a versatile choice for diverse bridge designs
Improved strength and structural performance: Beyond simply repairing existing cracks, epoxy injection e3nhances the overall performance of the structure by improving load-bearing capacity of the bridge and providing resistance to future environmental stressors and wear.

Professional Equipment for Successful Bridge Crack Repair

Achieving optimal results in bridge crack repair relies heavily on utilizing professional-grade equipment. SealBoss offers a comprehensive suite of tools and materials to ensure precision and efficiency in structural epoxy injection projects.

SealBoss PA3000 Epoxy Injection Pump

The SealBoss PA3000 epoxy injection pump stands out as a pneumatic powerhouse designed for handling extensive bridge crack repair projects and many linear feet of structural epoxy injection per day. With a large stainless steel reservoir and dual-component capabilities, it delivers a continuous flow of epoxy for uninterrupted injection.

Key features of the SealBoss PA3000 epoxy injection pump include:

User-Friendly Design: Designed with ease of operation in mind, minimal training is needed for contractors to operate this pump efficiently, reducing setup time and increasing productivity.
High performance: Capable of maintaining consistent epoxy delivery throughout the day, the pump enables seamless and efficient crack repairs, especially in high-traffic areas.
Versatility Across Applications: The SB PA3000 can be used for various applications, including crack repair, bonding, and sealing in bridges, tunnels, dams, and other critical civil engineering infrastructures
Durability for Harsh Conditions: With robust construction and a modular design, the SealBoss PA3000 is built for easy maintenance and to withstand tough worksite conditions, ensuring long-lasting reliability.

SealBoss Epoxy Injection Ports

SealBoss® Epoxy Injection Ports provide versatile, durable solutions for various epoxy crack injection needs. Engineered to integrate seamlessly with SealBoss Epoxy systems, they support manual, pneumatic, pump, cartridge, and high-pressure applications. Designed to handle rough surfaces, corner cracks, and high-pressure scenarios, these ports offer specialized options like angled and round base designs for efficient and reliable performance.

Key Benefits of SealBoss Epoxy Injection Ports include:

Versatile Design: Four durable port designs for varied conditions.
Comprehensive Compatibility: Supports manual, pneumatic, pump, cartridge, and high-pressure injection methods.
Specialized Solutions: Angled ports for corners and round base ports for shallow drill holes.
Reliable and Efficient: Seamlessly integrates with SealBoss systems for optimal performance.

Montana Department of Transportation
A Real-World Example: Montana DOT Bridge Crack Repair Restoration Project

The Montana Department of Transportation (DOT) has recently released an extensive work plan covering multiple bridge restoration initiatives, which involve the use of structural strength epoxy resin systems for crack injections.

A leading construction firm was tasked with the responsibility of executing these repairs. The project entails the injection of structural epoxy resin into specified cracks utilizing the SealBoss Epoxy Injection System.

The core elements of this repair strategy included:

SealBoss 4040 LV Structural Epoxy Resin: A low-viscosity, structural strength resin formulated for deep penetration into narrow cracks.
SealBoss 4500F Crack Seal and Port Setting Paste: Ensuring secure adhesion and setting of injection ports.
SealBoss Tri-Base Surface Mount Injection Ports: Facilitating precise injection of resin into targeted areas.
SealBoss PA3000 Epoxy Injection Pump: Delivering consistent and reliable performance throughout the project.

During this project, SealBoss regional manager Chris Conderre conducted a detailed on-site training session covering the operation and maintenance of the SealBoss PA3000 epoxy injection pump.

The training also emphasized the correct usage of accessories such as static mixers, Tri-Base Plastic Epoxy Injection Surface Mount Ports, and all connecting equipment required establishing a flawless union between the applicator and the substrate.

Conclusion

Reliable Bridge Crack Repair Solutions for the Future

Bridge crack repair using structural epoxy injection is a cost-effective and dependable approach that meets the needs of modern infrastructure maintenance, contractors and engineers.

By employing advanced equipment like the SealBoss PA3000 epoxy injection pump, along with high-quality materials such as the SealBoss 4040 low viscosity structural epoxy resin and the SealBoss 4500F crack seal and port setting paste, contractors can achieve exceptional repair results while minimizing downtime and costs.

Furthermore, proper training and education on the usage of these advanced tools and techniques are critical in achieving the desired outcomes.

As the demand for reliable and cost-effective bridge crack repair solutions continues to grow, it is essential for contractors and engineers to stay updated with the latest advancements in technology and materials. By adopting innovative methods like structural epoxy injection and utilizing state-of-the-art equipment, industry professionals can ensure the longevity and safety of bridges and other vital infrastructure components.

In summary, bridge crack repair using structural epoxy injection and advanced equipment like the SealBoss PA3000 epoxy injection pump offers numerous benefits. By adopting solid injection techniques and professional equipment, contractors and engineers can ensure the safety, reliability, and longevity of bridges and other critical infrastructure components, ultimately benefiting the communities they serve.

Structural Epoxy Injection System Products Used

By leveraging these innovative techniques and equipment, contractors can confidently tackle bridge crack repair projects, reinforcing the durability and safety of crucial transport infrastructure for years to come.

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Epoxy Injection Preparation Tips

Introduction:

Epoxy injection is a highly effective, polymer delivery method through a pumping system for repairing cracks in concrete structures. This process involves sealing all accessible sides of a crack and bonding them with a high and strength, low-viscosity epoxy resin by pressure injection.

Proper preparation is crucial for successful epoxy injection. It begins with cleaning the crack thoroughly, surface sealing the crack, and installing surface mount Tri-Base ports along the crack at specific intervals with a fast setting, non-sag epoxy paste. Following these preparation steps ensures the epoxy resin can penetrate and bond the cracked concrete effectively, restoring its structural integrity in the process.

Epoxy Injection Preparation Tips – Installing Surface Mount Tri-Base Ports

Epoxy Injection is a typically a low pressure to medium pressure crack filling solution where all sides of the crack are sealed and structurally glued together with a high strength low viscosity Epoxy Resin.

To prep for injection, the crack must be cleaned with a wire brush and all dust removed. Any surface contaminants, such as oils or paints, must be removed for the epoxy paste-over to bond properly. If available, use clean compressed air to remove any dust and debris. For best results perform epoxy injection preparation when the crack and surface are dry. Any water seeping from the crack should be stopped prior to epoxy injection. For sealing water bearing cracks click here.

Once the surface is cleaned, the Surface Mount Epoxy Injection Ports are installed directly over the crack 6” – 8” (15-20 cm) apart. The finer the crack, the narrower the spacing should be.

Shown in this example are standard surface mounted Tri-Base ports, however corner ports and ½” drill in ports are available for specific applications.

Tri-Base Ports are mounted by placing epoxy on each of the three tabs on the base of the port. Once ports are placed, the non-sag paste is applied to both sides of the wall, sealing the crack.

When applying paste, the mixed material should be applied generously at roughly 1/8” (3-4 mm) thickness, and mounded up around each port to approximately 1/4″ (6-7 mm) thick or more using a putty knife or other suitable tool. The paste-over should be a minimum of 1 inch (3 cm) wide along the crack. If the paste is not applied thick enough it may crack and epoxy will escape during injection, preventing proper penetration and epoxy flow within the crack itself. Note: The length of time needed for the epoxy paste to fully cure varies with ambient and substrate temperature.

“ Once ports are placed, the non-sag paste is applied at roughly 1/8” thickness and mounded up around each port. If the paste is not applied thick enough it may crack open and epoxy will escape during injection. “

SealBoss Technical Support Team

After the surface paste has hardened, structural strength epoxy resin can be injected starting at the lowest port on the crack, for horizontal or lateral cracks start on one side and work your way over.

Because the crack has been sealed on both sides, the next port in line will need to have the cap removed to allow the displaced air to escape. Once the Epoxy resin can be seen escaping from that next port injection stops, the applicator is disconnected from the injected port and the port is capped.

The applicator is then connected to the next port and the process is repeated. Once the crack has been fully injected and the Epoxy resin has cured, ports and paste can be ground off for aesthetics.

Epoxy does not Flow as Expected – Troubleshooter

Injected crack is not continuous or the area being injected is saturated
Crack is blocked by debris or cured epoxy paste
Surface mount port does not align with the crack
Epoxy has cured in injection nozzle, port or crack
Epoxy resin viscosity too high

Epoxy injection is an efficient and economical method of repairing cracks in structural concrete walls, slabs, columns and piers. If applied in compliance with all recommendations and specifications, high strength epoxy is capable of restoring concrete structures to their strength prior to crack development.

If at any time during your epoxy injection preparation and any other repairs you encounter issues that can’t be resolved, please call us here at SealBoss for support – 714-662-4445. Your technical representative will gladly be of assistance.

At SealBoss, we offer full system solutions for Structural Epoxy Injection Repairs including Electric and Pneumatic Pumps, various Ports, Epoxy Resins, Paste and Cartridge System.

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Plastic Surface Mount Injection Ports | Epoxy Injection Ports

Plastic Surface Mount Injection Ports
Epoxy Injection Ports

SealBoss ® Surface Port Advantages

Four Durable Plastic Port Designs to Suit Jobsite Conditions
Epoxy Pressure Crack Injection
Cartridge Injection with Low Pressure Zerk Type System
Rough | Uneven Surface Epoxy Crack Injection
Corner Crack Injection
High Pressure Epoxy Injection

Why should I use SealBoss Plastic Surface Mount Injection Ports?
– More Choices

Our quality surface mount epoxy injection ports are expertly designed to meet a wide array of jobsite application challenges. They are meticulously engineered to integrate flawlessly with the entire range of SealBoss epoxy injection systems. This comprehensive compatibility includes:

Handheld manual gun injection: Ensuring ease of use and precision for smaller applications
Pneumatic gun injection: Facilitating efficient and consistent application pressures and flow
Epoxy pump injection: Offering robust performance for large-scale and demanding applications
Cartridge injection: Providing a convenient and quick solution for smaller or more detailed repair tasks
High-pressure zerk coupler connected epoxy injection: Catering to high-pressure scenarios requiring utmost reliability and strength.

These ports are the epitome of versatility and reliability, ensuring that no matter the system or application requirement, our solution seamlessly aligns with your project needs, enhancing efficiency and effectiveness.

Challenging Application?
– We have You Covered

SealBoss surface ports are designed to cover typical application conditions including smooth, rough and uneven concrete surfaces, corner injection and high pressure epoxy injection.

In addition to the standard Tri-Base port, we offer 90 degree base angled ports designed for corner crack injection and 1/2 inch (13mm) round base plastic ports for shallow drill hole recessed port injection.

Using High Epoxy Injection Pressures?

– Go BIG

Our plastic surface port with zerk fitting can be equipped with either a regular high pressure or a low pressure injection zerk fitting to suit your needs for epoxy pump or epoxy cartridge injection. Equipped with a large base, this port provides a massive adhesion contact surface when glued to the concrete substrate, providing superior stability for higher injection pressures where needed.

1/4 EPOXY PORT | TRIBASE PORT
SURFACE PORT

1/4 EPOXY CORNER PORT
NOZZLE

1/2" EPOXY DRILL HOLE
HAMMER-IN PORT

BIG PLASTIC SURFACE PORT
WITH ZERK

Most epoxy crack injection is performed with the use of surface mounted injection ports. The port is glued to the concrete surface with SealBoss 4500 epoxy paste adhesive. Our nozzle type injection ports have a perforated base to increase the surface for the adhesive to hold on to the port and provide a secure connection between port and substrate.

Our zerk type surface port with extra large base plate takes surface port injection to another level. Now you can use high pressure zerk coupler equipped injection equipment with a surface mounted port for better connection security and higher injection pressures.

Please don't hesitate to contact us here at SealBoss for more information about our extensive packer selection. Your representative will be happy to assist.

We provide on-site support and training in eight Southern States for all SealBoss System Solutions.

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Retaining Wall Repair

Injection Methods Compared

Understanding Retaining Wall Repair:

Polyurethane vs. Epoxy Injection Methods

Retaining walls play a pivotal role in infrastructure and landscape, offering both functional support and aesthetic appeal. These structures, while robust, are susceptible to environmental factors and age related weakening that can lead to cracks, spalls, water leakage, or other forms of structural damage.

Addressing these issues promptly and effectively is crucial to ensure the longevity and safety of the wall. In the realm of deep penetrating, effective sealing and high strength structural retaining wall repairs, two methods have emerged as frontrunners: Polyurethane and Epoxy injection.

This overview explores the intricacies of both methods, comparing their advantages, applications, and effectiveness to guide you in making an informed decision for your retaining wall repair needs.

Retaining Wall Repair
with Leak Sealing Polyurethane Water Stop Foam Injection

Retaining walls serve as crucial components in construction projects, especially when dealing with slopes or elevated terrains. Their primary function is to combat soil erosion and bolster the stability of structures by resisting the pressures of soil and water. Yet, like all structures, retaining walls are prone to wear and tear, often manifesting as water leakage and subsequent erosion.

Enter polyurethane injection, a game-changer in the realm of retaining wall repairs. This method stands out not only for its efficacy but also for its cost-efficiency. Unlike traditional repair methods that might involve extensive excavation, the use of heavy machinery, or prolonged construction periods, polyurethane injection offers a swift and minimal-disruption solution. The essence of this method lies in the foam grout injected, which forms a resilient waterproof barrier, crucial for walls constantly exposed to moisture and hydrostatic pressure.

At its core, polyurethane injection foam is engineered to expand upon water contact. Typically, this foam is introduced into cracks or voids within a structure. Upon encountering water, a chemical reaction is triggered, causing the foam to swell and occupy the space. This unique expanding property is invaluable for tasks like leak sealing, ensuring that the foam aptly fills gaps and halts further water penetration.

The combination of low viscosity, fast expansion and curing, flexibility, good chemical resistance and adhesion, make polyurethane injection foam grout an effective choice for leak seal and water stop injection applications.

Here are some advantages of using PUR foam for stopping water migration through retaining walls:

Cost-effective — Polyurethane injection is a cost-effective solution for repairing a leaking retaining wall. It requires less labor, time, and materials compared to traditional methods of repair, such as excavation and replacement
Water Stop Leak Sealing and Waterproofing — The injected polyurethane resin expands on contact with moisture and creates a waterproof compression seal that prevents further water infiltration into the retaining wall
Minimal-Invasive — Polyurethane injection requires minimal disruption to the surrounding area, making it a convenient solution for homeowners and business owners. It does not require excavation, heavy machinery, or lengthy construction timelines
Quick — Polyurethane injection can be completed quickly compared to traditional methods, minimizing the time that the retaining wall is out of commission and minimizing disruptions to daily activities
Durable — The injected polyurethane resin creates a strong and flexible bond with the concrete surface, making it a durable and long-lasting solution for sealing a leaking retaining wall

Summary

Polyurethane injection is a cost-effective, waterproof, minimal-invasive, quick, durable, versatile, and eco-friendly solution for sealing a leaking retaining wall. If you are facing a leaking retaining wall, consider using this method for an efficient and effective repair solution.

Retaining Wall Repair
with Epoxy Resin Injection For Structural Strength

Retaining walls play an indispensable role in both landscape and infrastructure, acting as bulwarks against soil erosion and providing essential structural support. Yet, like all structures, they are vulnerable to the elements, facing challenges like natural degradation, water-induced damage, and the relentless pressure from the soil. Over time, these factors can result in cracks, voids, and other structural concerns. Left unaddressed, these issues can jeopardize the wall’s stability and safety. This is where epoxy resin injection comes into play, offering a robust solution to restore and reinforce a retaining wall’s strength.

Here is a closer look at the benefits of using epoxy resin injection for retaining wall reinforcement:

Structural Strength Repair — Retaining walls can lose their structural strength due to natural wear and tear, crack development, water damage, and soil pressure. Epoxy resin injection can fill and reinforce the damaged areas, restoring the retaining wall’s strength and stability. Epoxy resin, known for its high compressive and tensile strength, can fortify damaged areas, resisting both compressive and tensile forces. Its ability to prevent crack propagation and bear significant pressures and loads makes it a prime choice for restoring walls facing soil and water pressures
Durability — Epoxy resin injection is a durable solution for retaining wall repair. Epoxy resin is resistant to water, many chemicals, and typical ambient heat. It also resists wear and tear, making it a long-lasting solution that can withstand the test of time
Cost-effectiveness — Opting for epoxy resin injection can be a financially savvy decision. When compared to the steep costs associated with wall replacement—which often involves excavation, demolition, and rebuilding—epoxy injection emerges as a cost-effective alternative
Minimal-Invasive — Epoxy resin injection is a minimal-invasive solution for repairing retaining walls. It does not require excavation, heavy machinery, or lengthy construction timelines, minimizing the disturbance to the surrounding area
Quick — Time is of the essence in repair projects. Epoxy injection offers a faster turnaround than many traditional methods, ensuring the retaining wall is swiftly restored to functionality, with minimal disruption to daily routines

Summary

Epoxy resin injection is a reliable and efficient solution for structural retaining wall repair, offering a range of advantages such as durability, high compressive and tensile strength, cost-effectiveness, and minimal-invasiveness.

For any structural repair project, it is highly recommended to seek guidance from a professional engineer to assess the suitability of epoxy injection. Additionally, it is important to hire a skilled and experienced epoxy injection contractor who can perform the repair in accordance with the specifications. This ensures that the repair is conducted safely and effectively, and that the structure is restored to its optimal condition. It is crucial to prioritize safety and quality when it comes to structural repairs — expert advice and hiring competent professionals can help to achieve these goals.

Conclusion

Retaining Wall Repair – Polyurethane or Epoxy Injection

Polyurethane foam injection can be applied effectively in a wet environment where active water leaks are present. When the foam is injected, it expands and creates a water-resistant barrier that forms a permanent, flexible or semi-flexible seal upon contact with water. In most cases, there is no need to surface seal cracks before injecting the foam. Injection packers can be installed in wet environments and injection is not impacted by active water flow. While water-bearing cracks can lead to structure deterioration and erosion over time, they often do not compromise the structural integrity of the building if recognized early and sealed promptly
While structural epoxy injection can effectively restore a retaining wall’s strength and integrity, it is most effective in a dry environment. Epoxy is not well-suited to stop active water leaks. The injection area requires more preparation work, and it is recommended to surface seal cracks before injecting the epoxy. Surface ports do not adhere well in very wet environments. This repair method is more time-consuming and labor-intensive compared to polyurethane foam injection, and it can be more expensive

In summary, both polyurethane foam injection and structural epoxy injection are effective repair methods for retaining walls. Polyurethane foam injection is a highly effective method for preventing water infiltration, stopping active water flow, and efficiently and permanently sealing cracks. Structural epoxy injection is most suitable for application in environments that are not actively leaking and require additional support for significant structural damage in the wall.

Ultimately, the choice of injection repair method will depend on the specific project requirements.

It is always recommended to consult with a qualified professional to determine the best approach for your retaining wall repair needs.

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