Acid Etching vs Mechanical Cleaning of Concrete

January 31, 2025

Acid etching is a common method for preparing concrete surfaces, but whether it is “okay” depends on the specific application and the level of surface preparation required. Below is a detailed comparison of acid etching vs. mechanical methods (sanding or grinding).

Acid Etching for Surface Preparation

How it Works:

Acid etching uses diluted acids (typically muriatic or phosphoric acid) to react with the lime in concrete, dissolving weak surface material and creating a rougher profile for coatings.

Advantages of Acid Etching:

 • Inexpensive & Readily Available – Requires only acid, water, and protective gear.

 • Easier to Apply – Can be done with basic tools like a sprayer and broom.

 • Effective for Light Surface Preparation – Removes laitance (weak top layer of concrete) and some contaminants.

 • Minimal Dust Generation – Unlike mechanical grinding, which creates airborne dust.

Disadvantages of Acid Etching:

 • Inconsistent Results – Does not always create a uniform profile, especially on dense or power-troweled concrete.

 • Limited Surface Profile – May not achieve the necessary texture for thick epoxy coatings (CSP 2 vs. CSP 3+ required for heavy-duty coatings). Please note

 that all Epoxy.com Products fall into the category of thick coatings.

 • Environmental & Safety Hazards – Requires proper handling and disposal of acidic waste to avoid environmental damage.

 • Risk of Excess Residue – If not neutralized and rinsed properly, residual acid or salts can interfere with

Sanding or Grinding for Surface Preparation

How it Works:

Mechanical methods use abrasives (diamond grinders, scarifiers, or shot blasters) to remove surface material and create the correct profile.

Advantages of Grinding/Sanding:

 • Superior Surface Profile – Ensures a roughened surface for stronger epoxy adhesion.

 • Removes Coatings, Stains, and Contaminants – Unlike acid etching, which does not fully remove oil, grease, or sealers.

 • Works on All Concrete Types – Effective even on dense or power-troweled surfaces.

 • No Chemical Residue – No risk of leftover acid affecting epoxy adhesion.

 • Better for Thick or High-Performance Coatings – Creates CSP 2-3+ profiles required for heavy-duty applications.

Disadvantages of Grinding/Sanding:

 • More Labor & Equipment Needed.

 • Higher Cost – Equipment rental or professional services add expense.

Which Method Should You Use?

 • For light-duty coatings (thin epoxies, paints, or stains): Acid etching may be sufficient but must be done carefully.

 • For industrial coatings, high-traffic areas, or polished concrete: Grinding is the superior option for proper adhesion and longevity.

 • For previously coated or heavily contaminated concrete: Grinding is necessary to fully remove previous layers.

Final Verdict:

While acid etching is sometimes acceptable, mechanical grinding is the superior method for ensuring strong, consistent adhesion, especially for epoxy and industrial coatings. All Epoxy.com costing and flooring fall into this category. Acid etching is best reserved for light-duty applications or when mechanical preparation isn’t feasible.

For more detailed information Contact Us Today:

Call:

321-206-1833 (orders)

352-533-2167 (technical support)

Email: sales@epoxy.com

Visit: www.epoxy.com

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Posted by Norm Lambert

The Benefits of Chemical-Resistant Epoxy for Your Workspace

January 18, 2025

Workspaces are often exposed to harsh conditions—spills, chemicals, and heavy equipment can quickly wear down floors and surfaces. Protecting these areas is essential for both safety and longevity. That’s where Epoxy.com’s chemical-resistant epoxy coatings – https://www.epoxy.com/chemical_resistant.aspx – come in. Designed for industrial and commercial environments, these coatings provide unmatched protection and durability. In today’s post, we’ll explore the benefits of chemical-resistant epoxy and why it’s the best solution for your workspace.

Why Choose Chemical-Resistant Epoxy?

Many traditional flooring materials, such as bare concrete or tile, struggle to withstand chemical exposure and constant wear. Over time, these surfaces can deteriorate, leading to costly repairs and safety hazards. Chemical-resistant epoxy provides a long-lasting solution, offering the following benefits:

        1.        Unmatched Chemical Resistance

        •        Epoxy.com’s coatings are engineered to resist damage from acids, alkalis, solvents, and other harsh chemicals.

        •        Ideal for environments such as laboratories, factories, food processing plants, and automotive shops.

        2.        Enhanced Durability

        •        Withstand heavy loads, machinery, and high foot traffic without cracking or peeling.

        •        Protect your workspace from abrasion, impact, and daily wear.

        3.        Seamless and Non-Porous Surface

        •        Create a smooth, seamless finish that prevents liquids from seeping into the surface.

        •        Easy to clean and maintain, reducing downtime for cleaning or repairs.

        4.        Safety Features

        •        Available in anti-slip options to improve safety in areas prone to spills.

        •        Customizable with bright, high-gloss finishes for better visibility in industrial spaces.

        5.        Cost-Efficiency

        •        Long-lasting protection reduces the need for frequent repairs or resurfacing, saving time and money in the long run.

Best Applications for Chemical-Resistant Epoxy

Chemical-resistant epoxy coatings are versatile and can be used in a variety of industries and spaces, including:

        •        Laboratories: Protect surfaces from chemical spills while maintaining a clean and sterile environment.

        •        Factories and Warehouses: Handle heavy equipment and frequent chemical exposure without damage.

        •        Food Processing Plants: Prevent contamination with a seamless, non-porous surface that’s easy to sanitize.

        •        Automotive Garages: Protect floors from oil, grease, and solvents while creating a professional finish.

        •        Healthcare Facilities: Provide a durable, hygienic surface for hospital floors and pharmaceutical labs.

Steps to Apply Chemical-Resistant Epoxy Coatings

        1.        Prepare the Surface:

        •        Clean the area thoroughly to remove grease, dirt, or any previous coatings.

        •        Repair any cracks or uneven surfaces to ensure proper adhesion.

        2.        Apply a Primer:

        •        Use a primer to enhance adhesion and ensure a smooth, even application.

        3.        Mix and Apply the Epoxy:

        •        Follow the instructions to mix the epoxy thoroughly.

        •        Use a roller or squeegee to apply the coating evenly across the surface.

        4.        Allow Proper Curing:

        •        Let the epoxy cure completely before resuming operations. Curing time may vary depending on the product and environmental conditions.

        5.        Optional: Add a Topcoat:

        •        Apply a topcoat for added durability and specific features, such as anti-slip properties or UV resistance.

Why Choose Epoxy.com for Chemical Resistance?

At Epoxy.com, we specialize in high-performance coatings designed for the toughest environments. Our chemical-resistant epoxies:

        •        Offer industry-leading durability for long-lasting protection.

        •        Are easy to apply, with detailed application guides for DIYers and professionals.

        •        Come in a variety of colors and finishes to match your workspace’s aesthetic and safety needs.

Start Protecting Your Workspace Today

Don’t let chemicals and daily wear compromise your workspace. Whether you’re upgrading a factory floor, lab, or automotive shop, Epoxy.com’s chemical-resistant coatings offer the protection and durability you need. Designed for heavy-duty use, our products ensure your surfaces remain safe, functional, and easy to maintain.

Ready to get started?

For more detailed information Contact Us Today:

Call:

321-206-1833 (orders)

352-533-2167 (technical support)

Email: sales@epoxy.com

Visit: www.epoxy.com

Leave a Comment » | Chemical Resistance, Chemical Resistant Epoxy, Chemical Resistant Paint, Epoxy, epoxy concrete repair, Garage Flooring, Novolac, waterproof | Tagged: , , , , , , , , , , , , , , , , , , | Permalink
Posted by Norm Lambert

What is the difference between Epoxy.com Product #630 and Product #633W

August 5, 2024

Epoxy.com Product #630 and Product #633W are both epoxy novolac coatings, but they have some key differences:

Epoxy.com Product #630

  • Composition: 100% solids epoxy novolac.
  • Applications: Ideal for harsh chemical and solvent-resistant applications. It can be used as a troweled mortar, slurry binder, and coating for concrete and steel in extremely corrosive areas.
  • Chemical Resistance: Excellent resistance to strong acids, alkalis, and most industrial chemicals and solvents.
  • Epoxy.com Product #630 and Product #633W are both epoxy novolac coatings, but they have some key differences:
  • Epoxy.com Product #630
  • Composition: 100% solids epoxy novolac.
  • Applications: Ideal for harsh chemical and solvent-resistant applications. It can be used as a troweled mortar, slurry binder, and coating for concrete and steel in extremely corrosive areas.
  • Chemical Resistance: Excellent resistance to strong acids, alkalis, and most industrial chemicals and solvents.
  • Uses: Suitable for use in chemical plants, pulp mills, secondary containment areas, water and waste treatment, and gas and electric utilities12.
    Epoxy.com Product #633W
  • Composition: 100% solids epoxy novolac with high viscosity.
  • Applications: Designed for harsh chemical and solvent environments, specifically formulated for improved film build on vertical surfaces.
  • Chemical Resistance: Similar to Product #630, it offers excellent chemical resistance.
  • Uses: Ideal for secondary containment, storage, pump pads, trenches, and other high exposure areas. https://www.epoxy.com/633.aspx
  • In summary, while both products offer excellent chemical resistance, Product #630 is versatile for various applications, including horizontal surfaces, whereas Product #633W is specifically formulated for vertical surfaces due to its high viscosity.

Epoxy.com Product #633W

  • Composition: 100% solids epoxy novolac with high viscosity.
  • Applications: Designed for harsh chemical and solvent environments, specifically formulated for improved film build on vertical surfaces.
  • Chemical Resistance: Similar to Product #630, it offers excellent chemical resistance.
  • Epoxy.com Product #630 and Product #633W are both epoxy novolac coatings, but they have some key differences:
  • Epoxy.com Product #630
  • Composition: 100% solids epoxy novolac.
  • Applications: Ideal for harsh chemical and solvent-resistant applications. It can be used as a troweled mortar, slurry binder, and coating for concrete and steel in extremely corrosive areas.
  • Chemical Resistance: Excellent resistance to strong acids, alkalis, and most industrial chemicals and solvents.
  • Uses: Suitable for use in chemical plants, pulp mills, secondary containment areas, water and waste treatment, and gas and electric utilities12.
    Epoxy.com Product #633W
  • Composition: 100% solids epoxy novolac with high viscosity.
  • Applications: Designed for harsh chemical and solvent environments, specifically formulated for improved film build on vertical surfaces.
  • Chemical Resistance: Similar to Product #630, it offers excellent chemical resistance.
  • Uses: Ideal for secondary containment, storage, pump pads, trenches, and other high exposure areas34.
    In summary, while both products offer excellent chemical resistance, Product #630 is versatile for various applications, including horizontal surfaces, whereas Product #633W is specifically formulated for vertical surfaces due to its high viscosity. https://www.epoxy.com/epoxy_novolac_chemical_resistant_wall_grade.aspx

In summary, while both products offer excellent chemical resistance, Product #630 is versatile for various applications, including horizontal surfaces, whereas Product #633W is specifically formulated for vertical surfaces due to its high viscosity.

Leave a Comment » | Chemical Resistance, Chemical Resistant Epoxy, Chemical Resistant Paint, Epoxy, Seamless Epoxy Flooring Systems, waterproof | Tagged: , , , , , , , , , , , | Permalink
Posted by Norm Lambert

Surface Preparation for Resin Systems

January 12, 2016

Surface Preparation Guide
For Concrete, Wood, and Metal Substrates

CONCRETE SUBSTRATES

I. GENERAL INFORMATION

Surface preparation is considered to be the most important step of any resinous flooring application. Improper surface preparation could turn what seems to be a simple process into a lengthy, difficult repair. The following conditions will dictate the type of surface preparation:

A. Concrete Placement
1. Slab-on-grade or on the ground

a. A 10 mil minimum vapor barrier is necessary to prevent moisture vapor transmission. An efficient puncture proof barrier is recommended.

b. Proper jointing will minimize cracking which could transmit through the resinous flooring system.

2. Elevated Slabs

a. Pan construction should be vented.

b. Metal deck construction should be properly jointed to minimize cracking.

B. Curing and Finishing Techniques
1. Curing compounds, if used, must be mechanically removed from the concrete surface prior to all resinous flooring applications.
2. Recommended techniques:

a. Wet cure

b. Light steel trowel finish to minimize laitance and provide hard
surface

C. Age of Concrete

Concrete must be a minimum of 28 days old for resinous flooring applications. Primers are now available which can be used on fresh (green) concrete on some installations. Contact the technical department for details.

D. Previous Contamination can affect the bond of the resinous flooring and must be removed. Types of contamination are:
1. Oil, grease, or food fats can usually be burned off with a flame gun or removed with a commercial degreasing compound or solvent. Epoxy.com Product #201 Oil Stop Primer is an important tool in dealing with petroleum oil contaminated concrete.
2. Curing compounds, sealers, and other laitance are best removed mechanically with:

a. vacuum shot-blasting

b. scarifying

c. sand blasting

E. Present Condition
1. Test for moisture: Coating system bond failures on slabs on grade and elevated/lightweight concrete caused by moisture vapor transmission are the industry’s largest single problem and result in extreme frustration from owners, clients, and contractors. Epoxy.com recommends testing for moisture vapor transmission. The recognized methods are:

a. ASTM-F-1869  Standard Test Method for Measuring Moisture Vapor Emission Rate of Concrete Subfloor Using Anhydrous Calcium Chloride: The maximum allowed water/vapor transmission rate is 3 pounds per 1,000 square feet per 24 hours.

b. ASTM F-2170  Standard Test Method for Determining Relative Humidity in Concrete Floor Slabs Using In Situ Probes: This test measures the  relative humidity in the slab below the surface. If taken over a period of time, it will show the rate of drying in the slab. The maximum relative humidity should be below 80%.

c. ASTM-D-4263  Plastic Sheet Test: This test gives an indication that moisture may be present.

2. Moisture related failures can be prevented through:

a. Placing new concrete over an efficient vapor barrier.

b. Testing for moisture vapor transmission as prescribed above prior to resinous flooring application.

c. Applying a moisture vapor transmission reduction system where moisture content is too high for successful resinous flooring applications. See Epoxy.com Product #830 Moisture Vapor Treatment for more details

3. A clean surface is necessary to establish a strong bond between the resinous flooring and concrete.
4. Resinous flooring systems are only as sound as the concrete they areapplied to. All unsound concrete should be repaired or replaced prior to resinous flooring applications. Consult your Epoxy.com Technical Service Department for specific information.
5. Resinous flooring materials should be applied to level concrete substrates. Grind or fill high and low spots prior to application.
6. Repair cracks prior to resinous flooring applications
F. Mechanical Prep vs. Acid Etching

Resinous flooring materials ideally bond to concrete with a rough, sand-paper finish. This finish can be achieved by either acid etching or mechanical methods. The choice of preparation is dictated by the factors above. Other factors which determine the type of preparation include:

1. Ecological restrictions involved with waste removal which could prohibit the use of acid etching and other chemical methods.
2. The type of resinous flooring material: It is recommended that concrete floors be acid etched prior to application of polyester and vinyl ester flooring systems.
G. Acid Etching

The following steps are recommended for acid etching:

1. Dilute commercial muriatic acid with water using 1 part acid by volume to 3 parts clean water by volume. Add the acid slowly taking care to avoid splashing. Workers should be protected with safety glasses, rubber gloves, and boots. If skin or eye contact occurs, rinse affected area thoroughly with clean water and follow Material Safety Data recommendations.
2. Sprinkle acid solution onto the entire surface in order to allow the acid to reach all areas of the concrete. Adequate coverage is
approximately 75 ft²/gallon of acid/water solution. Do not puddle and spread.
3. Scrub the acid solution into the concrete using a stiff bristle broom to remove loose concrete and laitancy.
4. Before rinsing, look for areas where bubbling did not occur. These areas have not been sufficiently cleaned and will require mechanical scarifying and additional acid etching.
5. When the acid solution has stopped bubbling (usually after approximately 15 minutes), rinse the floor thoroughly with water. Do not allow the floor to dry before rinsing because the salts formed by the acid reaction may cause problems with the adhesion and performance of the resinous flooring system. Test pH of the concrete surface to verify that the concrete tests alkaline.
6. Finally, the floor should be dry mopped to remove standing water and dirt remaining after the acid etching. Allow the floor to completely dry prior to the application of any resinous flooring system. Failures can occur in resinous flooring system applications due to moisture remaining
in the substrate.
H. Mechanical Preparation

Contamination and other foreign materials must be mechanically removed to ensure a satisfactory bond. All dust and debris must be thoroughly removed.

II. OLD CONCRETE

Old concrete surfaces must be structurally sound. Any unsound areas mustbe repaired prior to proceeding with the resinous installation. For
proper patching and repairing, use Epoxy.com Technical Service
Department. Remove existing paint, scale and loose concrete by rough
sanding, sandblasting, shot blasting, or grinding. In some cases where
plant conditions allow, a stripper may be used to remove excessive
build-up of paints or sealers.

Structurally sound concrete should be mechanically prepared to remove any contamination. Vacuum shot blasting is the best method for achieving
a good profile for bonding and should be used where possible. Before
installation of any Epoxy.com Product the surface must be examined for moisture vapor transmission using:

ASTM-F-1869 Standard Test Method for Measuring Moisture Vapor Emission Rate of Concrete Subfloor Using Anhydrous Calcium Chloride.

ASTM-F-2170 Standard Test Method for Determining Relative Humidity in Concrete Floor Slabs Using In Situ Probes.

ASTM-D-4263 Standard Test Method for Indicating Moisture in Concrete by the Plastic Sheet Method. This test is only an indication and should not
be used to determine moisture migration.

Other ASTM Tests which are applicable to concrete preparation are:

ASTM-D-4258 Standard Practice for Surface Cleaning Concrete for Coating

ASTM-D-4259 Standard Practice for Abrading Concrete

ASTM-D-4260 Standard Practice for Acid Etching Concrete

ASTM-D-4261 Standard Practice for Surface Cleaning Concrete Unit Masonry for Coating

ASTM-D-4262 Standard Test Method for Ph of Chemically Cleaned or Etched Concrete Surfaces

ASTM-C-811 Standard Practice for Surface Preparation of Concrete for Application of Chemical Resistant Resin Monolithic Surfacing

III. NEW CONCRETE

New concrete must be well cured and dry prior to coating. Allow to cure a minimum of 28 days unless using green concrete primer. No curing
agents or sealing compounds should be used at any time prior to coating. A light steel trowel finish is recommended when finishing the concrete surface.

Any oil, grease, laitance, or other foreign material must be removed. Steam clean with a strong degreaser such as tri-sodium phosphate. Laitance and other foreign material are best removed by mechanical
methods such as vacuum blasting, scarification, or grinding.

All new concrete can be acid etched or mechanically prepared by vacuum shotblasting, sand blasting, scarifying, or grinding. Vacuum shot-blasting provides the cleanest environmentally safe area during
cleaning. It also provides a mechanically rough surface to achieve a
good bond.

When acid etching, use a 3 to 1 dilution of water to acid and follow directions printed above.

Before the installation of any Epoxy.com resinous system, the surface should be examined for moisture. Test for moisture vapor transmission using ASTM F-1869 Standard Test Method for Measuring Moisture Vapor Emission Rate of Concrete Subfloor Using Anhydrous Calcium Chloride. The maximum allowable rate is 3 pounds per 1,000 square feet per 24 hours.

Another procedure that helps determine slab dryness is ASTM-F-2170 Standard Test Method for Determining Relative Humidity in Concrete Floor Slabs Using In Situ Probes. Maximum allowable R.H. for protimeter test is 80%.

WOOD SUBSTRATES

I. GENERAL INFORMATION

Resinous flooring must always be applied directly to exterior grade plywood with extended glue line INTERIOR GRADE PLYWOOD delaminates easily and SHOULD NOT BE USED
as it could result in a failure of the resinous flooring system. MARINE GRADE PLYWOOD contains moisture repellants which could cause a darkening of the resinous flooring system and SHOULD NOT BE USED. All plywood must be completely free of all waxes, varnishes, or other foreign materials.

A. Plywood used to cover existing wood floors
1. Clean and fasten existing wood floor to the floor joists.
2. If the floor is completely sound, fasten ½ Exterior grade plywood “C” plugged with an exterior glue line to the existing floor. Stagger the plywood for strength.
3. ¾” DFPA Exterior or ¾” DFPA Underlayment grade plywood with exterior glue line must be used if the existing floor cannot be cleaned, or is not sound.
4. All plywood must be completely free of all waxes, varnishes, or other foreign materials.
5. Secure plywood with exterior glue.
6. Use Ring Shank or Wood Screws at six (6) inch centers around panel edges and support.
7. Stagger all panel joints, fill joints with epoxy filler, and coverjoints with fiberglass cloth and epoxy resin.
8. Lightly sand the floor surface to insure proper adhesion of the resinous flooring system.
9. Seal all joints and fastener head holes with Epoxy.com Product #2005 – Semi-Flexible Epoxy Gel Adhesive.
10. Prime surface with appropriate primer prior to system application. Surface may require double priming due to porosity of plywood.
B. Plywood used for new construction (plywood is laid directly on the joist)
1.  Exterior grade plywood “C” plugged with an extended glue linemust be used.

All plywood must be completely free of all waxes, varnishes, or other
foreign materials.

2. Use Ring Shank or Wood Screws at six (6) inch centers around panel edges and support.
3. Stagger all panel joints, fill joints with Epoxy.com Epoxy.com Product #2005 For outdoor applications cover joints with fiberglass
cloth and the membrane system being used with the outdoor system.
4. Lightly sand the floor surface to insure proper adhesion of the resinous flooring system.
5. Remove all dust with a vacuum cleaner.
C. Applications with waterproofing:
1. After preparing the floor surface as prescribed above, caulk all joints with Epoxy.com Product #2005 for indoor systems. For outdoor systems use the membrane used with the Epoxy.com outdoor system.
2. Apply the waterproofing membrane as specified.

METAL SUBSTRATES

I. Preliminary Preparation
A. Metal substrates must be structurally sound prior to any resinous system being applied. For best results Sandblast to Commercial Blast (SSPC10 / NACE3) for non-immersion applications and Sandblast to near white metal -(SSPC10 / NACE2) for immersion applications.
B. Remove all foreign materials such as oil and grease with solvents or other degreasing compounds.
C. All scaling and rust must also be removed mechanically by sanding, sandblasting, or abrasion.
II. Treat the blasted/abraded surface with a phosphoric acid solution as
described below in order to prevent rust formation if the surface is
left exposed for some time prior to application of the resin system.
A. Always use a 10% solution of Phosphoric Acid.
B. Mix acid solution in either glass, plastic, or earthen containers (never use metal containers), by adding Phosphoric Acid to water. NEVER VICE-VERSA due to heating or splashing which may occur.
Workers should be protected with safety glasses, rubber gloves, and boots. If skin or eye contact occurs, rinse affected area thoroughly with clean water and follow Material Safety Data recommendations.
C. Apply phosphoric acid solution by either paint brush or rubber squeegee and allow metal surface to AIR DRY.

DO NOT FLUSH METAL SURFACE WITH WATER.

III. Protect surface from contamination until the primer is applied.
IV. Wipe metal surface with MEK solvent immediately before primer
application.

Additional Useful Information for Installing Epoxy

Do with Epoxy
Don’t do with Epoxy

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Posted by Norm Lambert