The Ultimate Guide to Commercial Sandblasting: Techniques, Tools, and Safety Measures 

From intricate historic restorations to large-scale industrial refinishing, no other technique matches efficiency with precision quite like commercial sandblasting, a technology highly committed to safety that works for surface preparation, delivering more effective results than traditional methods. 

Imagine massive steel beams stripped of rust with pinpoint accuracy, antique architectural elements freed of stubborn paint without losing detail, or worn concrete floors transformed into pristine surfaces ready for fresh coatings. All of these sound exactly like what appropriate commercial sandblasting could do.

Through compressed air force and abrasive materials, commercial sandblasting has a level of precision and versatility that has led countless industries to embrace this process for its ability to streamline projects, reduce labor costs, and minimize environmental impact. Not just that, it’s also a method that can be adapted to virtually any setting—controlled indoor environments or open-air job sites.

To better understand commercial sandblasting, we need to examine its advantages, the critical equipment required, key advice on selecting the right media, and safety measures that will keep the whole process running smoothly and responsibly.

What Is Commercial Sandblasting? 

First thing is first: what is it? Commercial sandblasting—or, more accurately, abrasive blasting—is a technique that uses compressed air to propel abrasive particles at high speeds against a target surface. 

The origins of sandblasting trace back to the late 19th century, inspired by the natural erosion that desert sands inflicted on glass windows. General Benjamin Chew Tilghman is credited with the first patent for a sandblasting process in the 1870s. He observed how windblown sand could etch patterns into glass and recognized that the principle could be harnessed for industrial applications. 

Building on Tilghman’s idea, Thomas Wesley Pangborn introduced compressed air into the process around 1904, improving its efficiency and control. With these developments, what began as a fairly rudimentary concept evolved today into a highly sophisticated surface preparation method used across many different industries.

Commercial sandblasting involves a steady stream of abrasive media through a nozzle where contaminants—such as paint, rust, old coatings, mill scale, and debris—are stripped away, leaving behind a clean, uniform finish. But it’s not just about cleaning. Depending on the selected abrasive and the applied pressure, this process can also shape surfaces, etch delicate designs, or create the perfect texture for new coatings to adhere.

Key Advantages of Commercial Sandblasting

Commercial sandblasting has been a great ally for different industries, presenting several compelling benefits. Let’s see some of them:

• Efficiency & speed: Compared to manual scrubbing or chemical stripping, abrasive blasting is faster and more thorough, saving both time and labor costs.
• Versatility: Commercial sandblasting can handle metals, concrete, and wood. Whether removing decades-old paint or creating a specific surface profile for better adhesion, it’s all about adaptability.
• Environmental friendliness: Using non-toxic, eco-friendly abrasives and controlling dust keeps operations safer and greener. Media recycling systems, dustless technology, and careful abrasive selection minimize waste and pollution.
• Cost savings: With faster turnaround times and fewer steps, overall project costs are often lower. The added benefit of less maintenance downtime and extended equipment life makes it financially attractive for many businesses.

So, why is it called sandblasting? While “sandblasting” is the term still widely used, it’s somewhat of a misnomer today. 

Historically, sand was indeed the primary abrasive material. Over time, however, mounting health and environmental concerns led to the adoption of safer, more efficient alternatives. In modern commercial sandblasting, crushed glass, aluminum oxide grit, steel shot, and other specialized media have replaced actual sand.

In the early years, using sand seemed logical. It was abundant, inexpensive, and effective at stripping surfaces. Yet, as the process matured, the industry discovered serious drawbacks. Breathing in fine silica dust from sand can lead to silicosis—a dangerous lung disease—as well as an increased risk of lung cancer. 

The health of workers became a top priority, prompting regulators and companies to reconsider their material choices. As research and innovation advanced, safer and more predictable abrasives took protagonism. Today, abrasives like crushed glass are highly recommended for their eco-friendly profile and minimal health risks. Such alternatives have helped preserve the process’s high effectiveness while ensuring a healthier work environment.

What remains is the name “sandblasting”—an old habit of language. The term stuck around as the industry evolved and replaced sand with a variety of safer and more efficient abrasives. In practice, “sandblasting” and “abrasive blasting” are pretty much the same and often used interchangeably, though the latter more accurately reflects the diverse materials now in use.

Modern Abrasive Media Options

There’s not just one abrasive media option, actually, there are many. Different surfaces, levels of contamination, and desired finishes call for specific materials: 

• Crushed glass grit: A top recommendation for safer, more eco-friendly blasting, it effectively removes coatings and contamination without presenting health issues.
• Aluminum oxide grit: Extremely hard and reusable, it’s an excellent choice for preparing surfaces that need a very clean profile before recoating.
• Aluminum silicate (coal slag): Often used in shipyards, it’s a cheap and disposable option but can be environmentally taxing.
• Soda (baking soda): Gentle and low-pressure, soda blasting is ideal for removing rust or delicate contaminants without damaging the underlying surface.
• Steel grit & shot: High-impact abrasives that excel at stripping tough coatings, mill scale, and heavy rust. These steel abrasives are often used in more demanding industrial settings.
• Staurolite: Effective at removing rust and thin coatings, staurolite is commonly applied in steel fabrication and construction.
• Other specialty media: Walnut shells, corn cobs, silicon carbide, and glass beads each have their niche. For instance, walnut shells and corn cobs provide gentle cleaning on sensitive surfaces, while silicon carbide’s hardness makes it perfect for very aggressive blasting jobs.

The versatility of commercial sandblasting makes it invaluable across many industries. Metalworking shops use it to remove rust, mill scale, and old coatings from structural steel, automotive frames, and machinery parts. The automotive industry uses it to refurbish classic car components or prep surfaces for paint, while in construction and marine settings, abrasive blasting can restore bridges, ships, and tanks, removing decades of built-up corrosion.

Beyond heavy industry, it’s also used in manufacturing plants for routine maintenance, in woodworking for shaping and texturing timber, and in the preservation of historic buildings, where old paint and grime must be carefully stripped away without harming underlying stone or brick.

More Than Just a Sandblaster: What Tools Do You Need

Commercial sandblasting is often simplified in people’s minds as a single tool—the sandblaster—propelling abrasive media onto a surface. But it’s not just that. Commercial sandblasting is a nuanced operation thanks to a variety of specialized equipment and accessories. 

Having the proper tools ensures more effective and consistent results, but it also improves operator safety, efficiency, and environmental control. So, selecting the right setup can make the difference between a smooth, productive workflow and one plagued by slow progress, rework, and potential risks—something commercial sandblasting specialists know very well.

That being said, what equipment or tools do you need for commercial sandblasting? Let’s dive deep into each one of them so that by the end of this, you can have your checklist ready to be checked. 

Cabinets and portable blasters

Two fundamental categories of sandblasting equipment are blast cabinets and portable blasters:

• Blast cabinets are enclosed systems with a sturdy enclosure, blasting system, recycling mechanism, and dust collector. Operators remain outside, using glove holes and a foot pedal for control. These are ideal for smaller, delicate projects. They recycle abrasives to reduce waste and maintain a cleaner, safer environment.
• Portable blasters, in contrast, bring the process directly to the worksite. Suited for larger jobs or where the object can’t be moved indoors, they’re effective in construction, industrial, and shipyard settings. Operating in dry or wet modes, devices like Dustless Blasting’s DB800 cut down on hazardous dust. With rugged valves and adjustable abrasive flow, these units handle varying surfaces and conditions while preserving safety and efficiency.

Air compressors, blast pots, and nozzles

The heart of any sandblasting setup includes the indispensable air compressor, delivering the high-pressure air needed to propel abrasive materials. Usually, the air compressor should have: 

• Pressure ranges around 90-100 PSI to ensure consistent blasting power.
• For industrial projects, a volume and flow rate required of 50-100 CFM (cubic feet per minute) for efficient operation
• Matched horsepower and capacity to project needs to ensure reliability and cost-effectiveness

Next in line is the blast pot (or pressure blast tank), a pressurized vessel that meters abrasive into the airstream. The blast pot should cover the following:

• Media regulation, with adjustable valves to fine-tune abrasive flow
• Consistent output to maintain a steady supply of media to avoid uneven blasting results

At the delivery end, the nozzle directs the abrasive mixture onto the surface. Some key nozzle considerations include:

• Different nozzle materials and sizes, which influence blast patterns, from narrow beams for detailed work to wider sprays for large areas. 
• Durable nozzle materials (like tungsten carbide) withstand abrasive wear, extending equipment life.

Specialized environments: Blast rooms and recovery systems

When dealing with large workpieces such as aircraft components, construction equipment, or automotive parts, a blast room can bring a dedicated space to manage extensive blasting operations. 

These rooms come equipped with ventilation, dust collection, and media recovery systems that help maintain visibility and cleanliness. Blast recovery systems continuously retrieve and recycle abrasives, filtering out impurities that could affect performance or contaminate the surface.

For specialized applications, additional systems like cryogenic deflashing and wet blast equipment come into play. Cryogenic deflashing uses very low temperatures to embrittle and remove flash from diecast, plastic, or rubber parts. Wet blasting combines water with abrasive media, reducing friction heat and resulting in a gentler, less dusty finishing method.

Personal Protective Equipment (PPE) and operator safety

The human element is central. Without proper PPE, even the best equipment can suffer from risks. 

Operators should wear sandblasting hoods (respirators) with durable fibers and OSHA-approved clean air sources to prevent inhalation of dust and contaminants. These hoods protect the face and head from blowback and allow for clear visibility through viewing windows. 

Gloves, protective clothing, and hearing protection round out a comprehensive safety ensemble, while deadman switches—which immediately halt the flow of air and abrasive in emergencies—empower operators to work confidently.

Choosing the right abrasive

Though not a “tool” in the mechanical sense, abrasive media selection is a very important part of effective sandblasting. Hard, aggressive abrasives like aluminum oxide or steel grit can remove tough coatings from metal surfaces. 

Meanwhile, softer media like crushed glass or soda are gentle enough for delicate materials without causing damage. Pairing the right abrasive with the right blasting equipment ensures optimal results, improved surface preparation, and minimized risk.

A successful sandblasting setup resembles a well-orchestrated system; everything comes together at this point. The compressor provides the pressurized air; the blast pot delivers and regulates the abrasive; hoses and nozzles manage the flow and direction of the blast stream; cabinets, blast rooms, or mobile systems contain and control the process; and PPE keeps operators safe. 

Incorporating moisture traps and separators further refines the process by removing water from the air supply, preventing clogs, and ensuring consistent media flow.

Ultimately, commercial sandblasting involves more than just toolsl. It’s a combination of cabinets, portable systems, compressors, pots, nozzles, safety gear, and careful abrasive selection, each contributing to a smoother, safer, and more efficient operation. 

This evidentiates how important it is to invest in quality equipment, proper maintenance, and the right protective measures for successful, high-quality finishes across a diverse range of projects and industries.

Contact us here if you would like to find the best painting contractor for your residential or commercial painting needs.

7 Sandblasting Techniques for Pros (And Not So Pros)

Sandblasting techniques will focus on the methods and approaches used to carry out the sandblasting process itself—how the equipment is handled, the patterns applied, the specific blasting strategies depending on the material, and the process adjustments made to achieve certain finishes.

But what are the methods of sandblasting? In commercial sandblasting, techniques involve best practices for preparing surfaces, controlling air pressure and abrasive flow, choosing the right angle and distance from the surface, and selecting the appropriate blasting media based on project goals. 

Sandblasting is part of a broader family of blasting techniques designed to shape, clean, or strengthen surfaces by projecting countless abrasive particles at high speed. While the previous sections have focused on tools and equipment—more than just a sandblaster—, here we delve into the methods themselves:

1. Sandblasting (dry/air type): Traditionally propelled by compressed air, sandblasting uses a wide variety of abrasives—no longer just sand—to remove contaminants and prepare surfaces. It’s versatile and can be fine-tuned for smoother, less invasive finishing. Some of its pros include flexible abrasive choices like alumina, glass, or walnut shells and high-precision pressure adjustments. However, abrasives and dust can scatter, necessitating containment and PPE.
2. Blower blasting (dry/air type): Using a fan instead of a compressor, blower blasting propels particles at lower pressure for gentler surface treatments over large areas. On the plus side, it saves energy and costs by eliminating the need for a high-powered compressor. On the downside, its weaker processing power makes it less effective for heavy-duty tasks such as deburring or removing thick coatings.
3. Suction blasting (dry/air type): In suction blasting, airflow created by a fan draws abrasives into the stream, enabling controlled cleaning without heavily pressurized air. This approach reduces costs and can handle internal surfaces like pipes. However, because the abrasive force is weaker, it’s not ideal for intense material removal or high-precision shaping.
4. Dry ice blasting (dry/air type): Dry ice pellets are propelled at the surface, sublimating upon impact to leave no abrasive residue. It offers a clean, environmentally friendly option for delicate cleaning tasks and eliminates the need for abrasive disposal. The limitations include limited material removal capabilities and the added cost and complexity of dry ice handling.
5. Shot blasting (dry/mechanical type): Instead of compressed air, shot blasting uses a rapidly spinning impeller to fling metal pellets (steel, stainless steel, etc.) at the workpiece. This provides robust cleaning and surface hardening over large areas. The strengths lie in its ability to induce compressive stress and efficiently treat large metal surfaces. However, shot blasting is less adjustable for fine detail work and is generally limited to heavier abrasives.
6. Wet blasting (wet/eir type): Sometimes called “liquid honing,” wet blasting blends water with abrasives and then uses compressed air to deliver a controlled slurry. This reduces dust and allows for very fine abrasives, providing smooth, clean finishes. The method excels at simultaneous cleaning and finishing but is unsuitable for materials that cannot be exposed to moisture, and it also requires proper wastewater handling.
7. Wet shot blasting (wet/mechanical type): A developing technique that merges the wide-area effectiveness of shot blasting with dust reduction and finer control of wet blasting. It’s energy-efficient (no compressor needed) and can handle both fine and heavy processing. However, it’s still in development, data is limited, and any moisture-sensitive parts would not be ideal candidates for this approach.

Choosing The Right Technique

Selecting the best blasting technique depends on various factors:

• Material type: Hard metals may need shot blasting or corundum blasting for stronger impact; delicate substrates might benefit from bead or wet blasting.
• Desired finish: If one needs a smooth, polished surface, bead blasting or wet blasting with fine abrasives may be ideal. Grit-based sandblasting might be best for a rougher surface that promotes paint adhesion.
• Environmental and health considerations: Wet blasting reduces dust. Dry ice blasting eliminates residual media. Commercial sandblasting must ensure compliance with regulations to protect workers from silica dust and environmental impact.
• Project scale and precision: Large structures may call for shot blasting or blower blasting for efficiency. High-precision, small-scale work may lean toward controlled sandblasting or even ultrasonic variants.

Applications of These Techniques

The application will definitely depend on the method used, but let’s see how these can be used for different purposes:

• Rust removal: Quickly strips oxidation from steel, aluminum, and copper with no chemical treatments required.
• Die cleaning: Removes mold-release agents and residue from complex-shaped dies.
• Satin finish & texturing: Creates uniform textures to enhance adhesion, aesthetics, or wettability.
• Deburring & paint stripping: Eliminates sharp edges, protrusions, and unwanted paint layers without chemicals.
• Oxide scale removal: Cleans away “black scale” formed during heat treatments.
• Shot peening (strengthening): Introduces compressive stress and refines the microstructure of metal parts.
• Polishing: With the right media, blasting can even achieve polished, mirror-like finishes.

Blasting techniques offer several great advantages, including their ability to work on any material, create non-directional surface patterns, and provide a wide range of effects by varying particle type, size, shape, and impact energy. 

Additionally, blasting is a purely mechanical process, eliminating chemical hazards and enhancing environmental safety. However, these techniques also come with drawbacks: only the surfaces directly impacted by the abrasive particles are processed, making it challenging to treat complex geometries. 

Furthermore, equipment wear is inevitable as abrasive particles erode hoses, nozzles, and enclosures over time, needing regular maintenance and part replacements. Lastly, the generation and disposal of sludge or dust require additional maintenance efforts and environmental considerations, increasing the overall complexity and cost of blasting operations.

Safety Measures in Sandblasting

Both the workers and the environment should be protected from the hazards that surface preparation on commercial sandblasting involves. Ensuring safety in sandblasting operations requires understanding health risks, implementing engineering and administrative controls, providing appropriate PPE, and adhering to regulatory standards. 

Abrasive blasting, whether using dry or wet methods, generates hazardous conditions that can adversely affect workers’ health and safety. The primary hazards associated with sandblasting include respiratory hazards from silica dust and toxic metals, noise pollution, and other physical injuries to the eyes and skin.

Here, we outline the critical safety measures needed for safe and compliant sandblasting practices, according to OSHA.

Engineering controls

Engineering controls are the first line of defense in minimizing exposure to hazardous substances and reducing the overall risk in sandblasting operations. These controls involve modifying equipment or the work environment to reduce or eliminate hazards.

1. Substitution:
   • Use less toxic abrasives: Replacing hazardous abrasive materials like silica sand with safer alternatives such as crushed glass, aluminum oxide, or organic media like walnut shells and corn cobs will reduce the health risks associated with traditional sandblasting.
   • Water-based abrasives: Incorporating water into the blasting process (wet blasting) suppresses dust generation. Wet blasting reduces airborne particles, thereby minimizing respiratory hazards.
2. Isolation and containment:
   • Blast rooms and cabinets: As mentioned above, one might utilize enclosed systems such as blast rooms or blast cabinets to contain dust and debris within a controlled environment. These structures prevent the spread of hazardous particles to other areas of the workplace.
   • Barriers and curtain walls: Install physical barriers to isolate the blasting area from other workers and reduce the risk of exposure to airborne contaminants.
3. Ventilation:
   • Exhaust ventilation systems: Implement robust ventilation systems within blast rooms or cabinets to capture and remove dust and fumes at the source. High-efficiency particulate air (HEPA) filters can effectively trap fine particles, ensuring cleaner air within and outside the blasting area.
   • Local exhaust ventilation: Using localized ventilation near the blasting nozzle will capture dust and contaminants before they disperse into the broader workspace.

Administrative controls

Administrative controls involve implementing policies and procedures to reduce exposure to hazards and ensure safe work practices. These controls complement engineering measures by managing how tasks are performed and who is involved.

1. Work scheduling:
   • Limit exposure time: Companies should schedule blasting operations to minimize the number of workers exposed to hazardous conditions. Also, stagger shifts and rotate tasks to reduce individual exposure durations.
   • Optimal timing: They should conduct blasting during off-peak hours or when fewer workers are present to limit the number of people exposed to potential hazards.
2. Good hygiene practices:
   • No eating or drinking: Prohibiting eating, drinking, or using tobacco products in blasting areas will prevent ingestion of hazardous particles.
   • Wash stations: Companies should provide accessible wash stations for workers where they can clean their hands and faces before breaks and at the end of shifts. Also, encouraging thorough washing to remove any contaminants that may have settled on the skin.
3. Routine cleanup:
   • Wet methods and HEPA vacuuming: It’s key to perform regular cleanups using wet methods or HEPA-filtered vacuums to minimize the accumulation of toxic dust and sludge. Also, it should be avoided to use compressed air for cleanup, as it can disperse dust into the air.
   • Decontamination of equipment: Cleaning and decontaminating blasting equipment, tarps, and other tools will prevent the spread of contaminants.
4. Worker training:
   • Comprehensive training programs: Educating workers on the hazards of abrasive blasting, safe operating procedures, and emergency response protocols will keep everyone safe. Training should cover the proper use of equipment, PPE, and hygiene practices.
   • Hazard communication: Workers should have access to safety data sheets (SDS) for all blasting materials and understand the associated health risks and protective measures.

Personal Protective Equipment

PPE is essential for protecting workers from the physical and respiratory hazards of sandblasting. Proper selection, use, and maintenance of PPE reduces the risk of injuries and health issues.

1. Respiratory protection:
   • NIOSH-approved respirators: Using respirators approved by the National Institute for Occupational Safety and Health (NIOSH) will help protect against inhalation of dust and toxic particles. Types include:
     • Type CE NIOSH-Certified blasting airline respirators: Workers should have comprehensive coverage and positive pressure to prevent dust ingress.
     • Half-face and full-face respirators: Depending on the level of exposure, workers may need different types of respirators for adequate protection.
2. Eye and face protection:
   • Sandblasting hoods: Also mentioned above, durable hoods with clear viewing windows protect the face and eyes from abrasive particles and blowback. Workers should have hoods properly fitted and maintained.
   • Safety goggles: It’s always good to provide additional protection for the eyes, especially in environments where full-face protection is not feasible.
3. Protective clothing:
   • Leather gloves and aprons: These will protect hands, forearms, and the torso from abrasive particles and potential burns.
   • Coveralls: Full-body coveralls shield the skin from dust and abrasives. They should be made from materials resistant to tearing and abrasion.
4. Hearing protection:
   • Earplugs or earmuffs: Hearing protection devices mitigate the risk of noise-induced hearing loss from blasting equipment and compressors.
   • Hearing conservation programs: These programs include regular hearing assessments and the provision of appropriate hearing protection.
5. Safety footwear:
   • Steel-toed boots: Sturdy footwear protects feet from heavy falling objects and abrasive materials.

Regulatory compliance

Compliance with regulatory standards is essential for legal operation and the protection of workers. OSHA provides comprehensive guidelines and regulations that govern abrasive blasting operations.

1. OSHA standards:
   • Respiratory protection (29 CFR 1910.134): Mandates the use of appropriate respirators and the implementation of a respiratory protection program.
   • Hazard communication (29 CFR 1910.1200): Requires employers to inform and train workers about the hazards of chemicals used in blasting.
   • Occupational noise exposure (29 CFR 1910.95): Sets permissible exposure limits for noise and requires hearing conservation programs.
2. Permissible exposure limits (PELs):
   • Silica: Strict limits on airborne silica particles to prevent respiratory diseases.
   • Toxic metals: Regulations on exposure levels for metals like lead, arsenic, and chromium to minimize long-term health effects.
3. Workplace safety programs:
   • Hearing conservation: Implement programs to monitor and protect against noise-induced hearing loss.
   • Personal hygiene: Enforce practices such as washing hands and face before breaks and prohibiting eating or drinking in blasting areas to prevent ingestion of hazardous particles.

Safety measures in sandblasting are multifaceted, requiring a combination of engineering controls, administrative policies, personal protective equipment, comprehensive training, and strict adherence to regulatory standards. 

Environmental and Sustainability Considerations in Sandblasting

Last but not least, let’s understand the environmental and sustainability considerations in sandblasting. While this practice is an exceptionally effective method for surface preparation, it’s crucial to address its environmental and sustainability implications to ensure responsible and compliant operations. 

Understanding the environmental impact of sandblasting and implementing strategies to minimize these effects protects the environment and enhances workplace safety and operational efficiency.

Despite its industrial benefits, sandblasting can have several adverse environmental impacts if not properly managed:

• Air pollution: The process generates consequential amounts of dust and fine particles that can become airborne, contributing to air pollution. This dust poses health risks to workers and nearby communities, especially when abrasive materials containing silica or other hazardous substances are used.
• Waste generation: Abrasive materials used in sandblasting often become contaminated with paint, rust, or other surface residues, turning them into waste. Managing this waste is challenging, particularly when it contains hazardous substances like lead or silica, requiring specialized disposal methods.
• Noise pollution: The machinery and compressors used in sandblasting operations produce substantial noise levels, contributing to noise pollution. Prolonged exposure to high noise levels can affect both human health and local wildlife.
• Water usage: In wet blasting methods, large quantities of water are used, which can strain local water resources and lead to wastewater management issues if not properly treated before disposal.

So, how can we minimize the environmental impact of sandblasting? Well, there are several effective strategies to reduce the environmental footprint of sandblasting activities significantly:

• Using eco-friendly abrasives: The best choice is opting for environmentally friendly abrasives such as recycled glass, aluminum oxide, or organic materials like walnut shells and corn cobs. These alternatives reduce the ecological impact while minimizing health risks associated with traditional sandblasting media.
• Proper waste disposal: Responsible waste management practices such as segregating and recycling reusable abrasives are a very important part of the process. For hazardous waste, one may ensure disposal through approved channels that comply with environmental regulations. Partnering with certified waste disposal services can streamline this process and ensure compliance.
• Employ dust control measures: Utilizing dust collectors, ventilation systems, and containment methods like blast cabinets or enclosed blast rooms can capture and manage airborne particles. Wet blasting techniques can also significantly reduce dust generation by mixing water with abrasive media, thereby limiting the spread of dust.
• Noise reduction strategies: This means incorporating noise barriers, operating equipment during designated hours to minimize disturbance, and investing in low-noise machinery. Regular maintenance of equipment can also help reduce noise levels by ensuring machinery operates smoothly and efficiently.
• Regular equipment maintenance: Maintaining sandblasting equipment not only enhances operational efficiency but also reduces environmental impact. Well-maintained compressors and blasting machines operate more efficiently, lowering energy consumption and minimizing the generation of waste and emissions.
• Energy-efficient practices: Implementing energy-saving measures such as using energy-efficient compressors, optimizing blasting pressure settings, and scheduling maintenance to prevent energy waste. Investing in energy-efficient equipment can lead to long-term cost savings and reduced environmental impact.
• Training and awareness: Educating operators and staff on best practices for environmentally responsible sandblasting. Proper training ensures that techniques are applied efficiently, waste is minimized, and safety protocols are followed to protect both workers and the environment.

Prioritizing environmental and sustainability considerations in sandblasting ensures responsible operations that protect both the environment and worker health. 

How to Choose the Right Commercial Sandblasting Service?

Selecting the right commercial sandblasting service will determine the success of a project. It requires evaluating several key factors to ensure you partner with a reliable and proficient provider.

If you ask us, you should look for a company that demonstrates extensive expertise in various sandblasting techniques and has a proven track record across multiple industries. Assess their commitment to using eco-friendly and safe abrasive materials, as well as their adherence to stringent safety protocols and regulatory standards.

At Koehn, we know exactly how to achieve great commercial sandblasting results, all tailored to our client’s specific needs. Our team of seasoned professionals uses the latest techniques and environmentally responsible abrasives to achieve exceptional surface preparation and finishing. 

We prioritize safety and sustainability in every project, ensuring not only superior outcomes but also the well-being of our workforce and the environment. 

Discover the Koehn Painting difference  – contact us today for a free estimate and step into a vibrant, freshly painted home!