This article provides comprehensive information about sandblast cabinets. You will learn how these sandblast cabinets are made and their materials of construction as well as applications, advantages, and drawbacks.
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Sandblast cabinets are specialized systems or equipment designed to project abrasive media onto a part’s surface for purposes such as cleaning, surface modification, or abrasion. Various types of blast media, including sand, metal shot, and other abrasives, are propelled using methods such as compressed air, pressurized water, or a blast wheel.
These cabinets are also referred to by several other names, including abrasive blast cabinets, dry blast cabinets, wet blasting cabinets, micro-abrasive blast cabinets, micro-blasters, micro-jet machines, and shot peening cabinets.
To answer the question, "How do sandblasters work?", it is essential to understand the technology that powers these devices. The characteristics of the blasting media, including its shape and hardness, as well as the use of media, are critical factors in the blasting process.
The technology used to energize, propel, or project the blast media is a key factor in defining the types of sandblast cabinets.
The propulsion technologies utilized in blast machinery for cleaning, peening, or modifying surfaces include:
Air Blast or Dry Blast Cabinets – These cabinets use compressed air to move the blast media. Pneumatic or compressed air blast systems are categorized into two types: suction and direct pressure.
Suction or Siphon Blast Cabinet – Suction blast cabinets use the venturi siphon effect to draw abrasive into a pressurized stream of air, fluid, or water.
Venturi devices create a constriction in the moving stream of fluid to produce a pressure differential or vacuum, causing the blast media to be drawn into the air or water stream at the point of constriction.
Venturi devices are utilized across various industries. Venturi generators create vacuums for mechanical holding purposes, while ejectors and eductors are employed to move fluids, powders, or solids in chemical processing industries.
Suction blast cabinets or portable siphon blasting pots are generally less expensive than pressure blast systems. Economy blasters are typically suction sandblasters, as they do not need a pressure vessel and use about half the pressurized air compared to pressure blast cabinets. However, suction blasters need higher air pressure levels to sustain media flow.
Suction blast cabinets are less aggressive, resulting in a longer cleaning time. They are often used for short runs, light production, maintenance, and field applications.
The less aggressive nature of suction or siphon blasters means that parts take longer to clean. However, this reduced aggressiveness leads to lower wear rates on the blaster's parts, which can extend their lifespan and reduce maintenance costs.
Small handheld sandblasters may feature a cup above the blast gun to gravity-feed abrasive material into the gun's venturi point. Gravity blasters are a type of suction blaster as they still use the venturi siphon effect.
Direct Pressure or Pressure Blast Cabinets – Direct pressure abrasive blast equipment uses a pressure vessel to propel the abrasive media. A metering valve on the vessel releases pressurized fluid and media into a blast hose, where it travels to the blast cabinet and gun.
Direct pressure cabinets can expel blast media at much higher flow rates or speeds compared to suction blasters. The impact or kinetic energy (K) of the media is calculated as K = ½ mv2, where m is the mass of the media and v is its velocity.
Increasing flow or velocity increases impact energy and cleaning efficiency exponentially.
Direct pressure systems can clean parts up to four times faster than suction machines. They also offer more precise control over cleaning and surface modification due to adjustable pressure levels.
Direct pressure systems can handle heavy media like steel shot and grit, unlike suction blasters. Doubling the mass of the media doubles the impact energy. Heavier media is generally more effective for cleaning and profiling than lighter media.
Due to their higher speeds, ability to handle heavy media, and better control, direct pressure sandblasters are preferred for high-volume and automated applications. They can operate effectively at greater distances from the part.
Pressure blasters use two to three times the volume of compressed air compared to suction blasters. Maintenance and safety of pressure vessels are crucial as vessel failure can pose risks to operators and equipment. Pressure vessels must comply with ASME Boiler and Pressure Vessel Codes.
Wet Abrasive Blast Cabinets – Water can replace air as the fluid used to propel the blast media. Wet abrasive blast or water blasting can reduce the dust generated during abrasive blasting by over 90%, which can be important when stripping or cleaning a part containing heavy metals and hazardous materials. While some suppliers refer to wet abrasive blasters as dustless blast equipment, no abrasive blasting system suppresses 100% of the dust generated.
Wet blasting can also keep parts cooler, reducing warping or distortion, and suppresses static discharges and ignition risks in explosive dust environments.
Wet blasting may use up to 50% less media than dry blasting and provides thorough cleaning without embedding abrasive media. These systems often include recyclers, oil separators, and filtration systems to convert dust into disposable sludge.
In dry blasting, dust is removed with air or washing. Wet blasting integrates cleaning and dust suppression. Detergents can be added to the water to enhance cleaning and rust inhibitors can prevent rust formation. Without inhibitors, steel should be dried, oiled, or painted post-blasting. Bacteria and microbes can grow in blast water, necessitating antimicrobial agents.
Various types of water blasters and abrasive water blasters are available.
Slurry Sandblast Cabinets – Dry blasting units can be upgraded to perform wet blasting as well. These systems, also called air abrasive water blasters, use a water injection nozzle or water ring (halo) connected to the air blasting gun to mix water with the blast media stream. This setup reduces dust by 50% to 85%. Water ring or halo nozzles offer less dust suppression compared to water induction or injection nozzles.
Slurry blasters offer great flexibility as they can perform dry blasting, wet blasting, rinsing, and drying of parts.
However, a major drawback is the cleanup of the muddy residue produced, especially in field settings. The equipment can be cumbersome for operators due to the heavy water hose that is part of the system.
Wet Venturi Sandblast Cabinets – Wet venturi blasters function similarly to dry suction blasters, but they use a venturi vacuum created by compressed air to draw in a mixture of abrasive and water. Some manufacturers refer to these systems as modified sandblasters. Although venturi blasters are effective at reducing dust, they demand high blast pressure for optimal performance, which leads to increased water and blast media usage. Additionally, flow control options are limited.
Vapor Abrasive Sandblast Cabinets – Vapor abrasive blast machines premix abrasive and blast media in a pressurized vessel. Also known as mist blasters, dustless vapor blasters, or dust-free blasters, these systems offer up to 95% dust suppression.
The abrasive slurry is delivered through a blast hose to the slurry blasting nozzle. Additional compressed air can be introduced to adjust the intensity of the wet blasting process. This regulating air creates a mist of wet abrasive particles, allowing independent control of air pressure and blast media consumption.
Vapor abrasive blasters use significantly less water and media compared to venturi and slurry blasters.
With a broad operating pressure range and precise control over the wet abrasive blasting process, vapor sandblasters are more versatile. They function effectively at very low pressures (30 psi) for paint removal and at very high pressures for white metal blasting and corrosion control.
Ice Blast Cabinets – These cabinets use frozen media like dry ice (solid carbon dioxide) or water ice (H2O) for cleaning. Both dry ice and water ice are considered non-aggressive media.
Ice blasting cabinets need to be constructed to manage the lower temperatures of the media and address condensation on lines, cabinet walls, pots, and vessels. Construction materials must avoid plastics or metals that become brittle in colder conditions.
Dry ice is less abrasive compared to plastic media. It comes in two forms: pellets and shaved or snow-like flakes. NASA engineers have utilized dry ice, or carbon dioxide snow-like crystals, to clean particle contaminants from the surface of space telescope mirrors without causing scratches or altering the surface profile.
Both dry ice and water ice blasters offer clean-up benefits over traditional methods. Water ice grits evaporate after use, while dry ice sublimates into gaseous carbon dioxide. The sublimation process of dry ice absorbs heat from the part’s surface, which can assist in paint removal and cleaning.
Sandblast cabinets can be complete blasting machines or preconfigured abrasive blast packages with the necessary components. They may also be modular, allowing customization for specific applications by selecting various parts from a supplier’s catalog. Components include blast guns, wear-resistant nozzles, pressure vessels, valves, deadman handles, blast cabinets, blast rooms, and blast hoses.
Sandblast cabinets vary significantly in size and configuration based on the application, end-use, function, and environment (such as lab/shop, production line, or field/remote sites) in which they are employed.
Benchtop Micro Blasters and Pencil Blasters – Micro-abrasive blasters, or micro blasters, feature small nozzles ranging from 0.018 to 0.125 inches in diameter. These nozzles are sometimes made of sapphire or single crystal alumina. Media sizes from 10 to 350 microns are used for surface blasting. Microblast cabinets can be benchtop or floor-mounted, and handheld pencil blasters, which often have a small gravity-fed media cup, are a type of micro blaster.
Micro-abrasive blasting systems are commonly used for cleaning, stripping, and etching small parts in dental, jewelry, and electronic (PCBs) applications. They are also used for deburring stainless cannula, microtubes, and hypodermic needles.
Manual Blast Cabinets or Cabinet Blasters – Manual blast cabinets feature two holes with rubber blasting gloves that extend into the cabinet, allowing the operator to handle parts and hold the blast nozzle at the proper distance. This setup enables the operator to create a focused blast area and move it across the surface for cleaning or etching.
These cabinets include a window and internal lighting to help the operator view the parts and nozzles without direct exposure to the blast. Some cabinets have air blasts across the window to prevent dust accumulation and maintain visibility.
After blasting, the used media falls through the cabinet's steel or fiberglass grate and collects in a hopper. From there, the media is transported to a separator where the abrasive is recovered. Budget-friendly blast cabinets might skip this step and reuse the spent media directly. Without separating, dust and smaller media particles may be reintroduced, which can lower efficiency and harm filters.
In an ideal setup, both the blast media and dust are contained within the cabinet and its filtration system. However, as blast cabinets are used over time, seals can degrade, leading to leaks. Door seals are a frequent issue, as they might not always be securely fastened around the entire edge, causing potential leakage.
Titan Abrasive Systems, a leading manufacturer, has introduced a patent-pending innovation for "leak or warp" resistant blast cabinet doors. These doors feature dual panels and two sturdy steel channels. Additionally, they are equipped with an enhanced closing mechanism that clamps the door more securely along its edge. A knife-edge design ensures a tight seal each time the door is closed.
Blast cabinets can be designed with front, top, and side-opening doors, and some models come with multiple doors. Cabinets with double doors facilitate the insertion of a dirty part while simultaneously removing a cleaned one. The doors of blast cabinets can be configured to swing open, lift up, or slide. Pass-through cabinets are specifically designed for etching glass sheets or metal plates. These systems include a narrow gap with specialized brush or rubber flap seals to minimize abrasive leakage. Parts are inserted into the gap and moved through the cabinet on rollers.
Manual blast cabinets are well-suited for use in machine shops, garages, body shops, light production settings, short production runs, touch-up work, prototyping, and custom projects.
Sandblast cabinets are assembled from a variety of components including cabinets, pressure vessels, hoses, guns, and nozzles. These parts are typically produced using techniques such as sheet metal fabrication, casting, welding, mechanical fastening, machining, and other specialized methods.
Blast cabinets are fundamentally metal boxes fabricated by cutting, bending, and shaping steel sheets and plates to create the sides, legs, and doors. The components of these cabinets can either be welded or fastened together. Fastening facilitates easier removal for maintenance and replacement, while welded cabinets tend to be more sealed, minimizing the escape of blast media and dust. However, replacing worn parts like cabinet sides or bottoms can be challenging with welded designs. Over time, the abrasive blast stream erodes the cabinet's bottom and sides, and seals and windows will also deteriorate and need replacement.
Dry or air blasting cabinets are typically constructed from steel coated with powder or industrial paint. Wet blasting cabinets are often made from more corrosion-resistant materials, such as stainless steel.
In specific applications like cleaning surgical instruments and medical implants, stainless steel construction may be chosen to prevent iron contamination of the surfaces.
For blasting stainless steel parts, stainless steel shot or grit, or non-metallic abrasives, are used. Using steel components or steel shot on stainless steel can transfer metal to the surface, potentially affecting passivation and leading to rust formation.
To minimize wear on blast machines, wear-resistant steel liners are installed within blast chambers. These liners are made from alloys such as manganese steels (e.g., Manganal) and nickel-chromium white cast irons (e.g., Ni-Hard alloys).
Sandblast cabinets experience significant wear due to the abrasive nature of the blasting media. Components of blasters are consumable and will degrade over time with the flow of abrasive media.
The blast media itself is also consumable. Certain media types, like steel shot, ceramics, and aluminum oxide, can be recycled through the blaster numerous times, whereas materials like soda, dry ice, sand, and coal slag are single-use.
Regular inspection of parts in abrasive blasters, wheel blasters, and shot peeners is necessary to ensure proper function. Changes in the nozzle's inner diameter or the geometry of the throwing blades can affect blasting efficiency.
Key parts of sandblasters include:
Blast nozzles are made of extremely wear-resistant materials are:
Depending on the type of blast media used, nozzles made of cemented tungsten carbide or SiAlON can last 10 to 20 times longer than those made from ceramic or alumina. Boron carbide is known for its exceptional hardness and wear resistance among nozzle materials. Although boron carbide is approximately three times more expensive than cemented tungsten carbide, it can last 3 to 25 times longer. However, it lacks the toughness and impact resistance of cemented tungsten carbide. Nozzles made from binderless tungsten carbide generally have twice the lifespan of those made from boron carbide.
Steel nozzles are suitable for use with air blow guns, washout guns, and for blasting very soft media like soda, dry ice, walnut shells, and plastic media. These nozzles are resilient and do not break easily if dropped. Budget-friendly and non-industrial sandblasters for DIY projects or home use often include these cost-effective steel nozzles.
When considering wear resistance alone, boron carbide and binderless tungsten carbide nozzles can last up to seven times longer than cemented tungsten carbide nozzles. However, if a boron carbide or silicon nitride nozzle is struck against a part, grate, or cabinet wall, it is more prone to cracking compared to a cemented tungsten carbide nozzle.
The lifespan of a nozzle is also influenced by the type of media used. Nozzles will experience more rapid wear when used with sharper, angular steel grit compared to spherical cast shot.
Materials such as aluminum oxide and silicon carbide can cause nozzles to wear out faster than materials like garnet or coal slag. For equipment that blasts plastic media, soda, corn cobs, or walnut shells, the nozzles could last virtually indefinitely.
Aside from the consumable wear parts, various sandblasting accessories and auxiliary equipment can enhance the efficiency and effectiveness of the blasting process:
Blast hose back pressure tester
Blast nozzle wear gage
Sandblasting and shot peening operations necessitate the use of personal protective equipment (PPE) specifically designed for abrasive blasting:
Sandblast cabinets alter the surfaces of parts or structures through various methods based on the type of media and blasting settings. Softer abrasives used at lower pressures can delicately strip coatings, while very hard media projected at high pressures can aggressively etch, pattern, or carve surfaces.
Optimizing your production operations can involve several end-use or surface modification functions provided by sandblasters:
Cleaning / Stripping – Sandblast Cabinets are widely used for impact or mechanical cleaning. Abrasive blasting effectively cleans surfaces, removing rust, oxide scale, mineral deposits, corrosion, grease, dirt, coatings, sealants, carbon deposits, and varnish.
Unlike wire brush wheels, abrasive belts, and discs, which quickly load up when dealing with paints, coatings, grease, and contaminants, abrasive blasting turns surface contamination into dust. This dust and media are then managed with dust collectors, industrial vacuums, and separators.
Cleaning aggressiveness can be adjusted by selecting the appropriate blast media, pressure, flow rates, and type of blast machine.
Abrasive blasters can remove graffiti, paints, and coatings gently, without affecting the base material. They can also thoroughly blast a steel surface to achieve a NACE/SSPC “white metal” cleanliness grade by removing all rust, scale, or adherents.
Blending, Smoothing, and Surface Finishing – This involves removing marks or lines from machining and grinding processes. Spherical media like steel shot and glass beads are ideal for blending and refining surface finishes.
Blasting with round-edged media creates a brighter, matte finish by leveling higher points on the surface. In contrast, sharp, angular abrasives produce a duller, satin finish that enhances bonding characteristics.
Enhancing the surface finish or reducing the surface profile can improve fretting fatigue strength by 20% to 200%. Initially, a larger diameter or heavier cast shot is used to create a deep residual stress layer. Subsequently, the surface is peened with small spheres or microbeads to achieve a refined finish.
If the part has a rough (high roughness average, Ra) surface finish like an as-cast or as-forged surface, then peening can modestly refine the surface finish. If the part has been ground or machined to a smooth or low Ra finish, then shot peening will result in a rougher surface finish.
Deflashing – Excess material, known as flash, forms where the two halves of a mold meet in processes like plastic molding, rubber molding, sand casting, or die casting. This flash on molded metal, plastic, or rubber parts needs removal, followed by blending the remaining parting line. Plastic and rubber parts are cryogenically frozen with liquid nitrogen at -300°F (-184°C), making the flash become brittle and easy to blast away.
Deburring– Slivers, attached swarf or metal chips, and sharp overhanging edges can form on parts during sawing, machining, drilling, cutting, shearing, grinding, and other metal removal operations. Burrs and slivers can easily cut worker’s or customer’s hands and represent a handling hazard. Sandblasting can quickly remove burrs from edges even in recesses where mechanical deburring blades and chamfering tools cannot reach.
Drilling / Carving – Micro abrasive blasters are capable of drilling small holes in printed circuit boards and carving 3D shapes and 2D patterns into materials like glass, wood, and stone.
Patterning / Marking – Abrasive blasting can be used to create patterns or mark surfaces with images, part numbers, and text. Masking tapes, films, and compounds protect areas from the blast, as these materials are typically soft or rubbery. In some applications, micro-abrasive blasters with narrow blast patterns can mark or pattern without the need for masking.
Peening / Surface Engineering – Surface engineering involves modifying a part's surface to provide unique characteristics that enhance its performance in specific applications.
Peening uses spherical media such as steel, stainless steel, glass, or ceramic to impact the surface. It strains and hardens the part while imparting compressive residual surface stresses. The commonly used media is ‘cast steel shot’ with a Rockwell C hardness between 40 and 55.
The compressive residual stress from shot peening can boost the fatigue strength of parts by 30% to 500%. Enhancing fatigue strength and resistance to stress-corrosion cracking is crucial for components like fasteners, gears, axles, dies, molds, shafts, springs, aircraft landing gear, and other rotating and structural parts.
The residual stress from shot peening can also be utilized to peen form and straighten shafts to bring them back into tolerance. Additionally, shot peening hardens the surface, increasing both hardness and wear resistance, and can close surface porosity. It is also effective in locating and removing hidden sub-surface corrosion in parts and around fasteners.
Shot peening can create a textured surface with specific patterns of dimpling or depressions. A dimpled texture helps in retaining lubricants, grease, inks, or other fluids more effectively. It can also modify the gripping and frictional properties of surfaces.
Etching / Surface Profiling – This process involves texturing, roughening, and creating a specific surface profile. Coatings, paints, and adhesives adhere better to a rough surface than a smooth one. An abrasive-blasted surface forms an anchor profile with undercuts, providing more surface area for coatings and adhesives to adhere to.
A sandblasted surface on a stainless steel handrail improves grip, and etching modifies the frictional characteristics of surfaces, which can be advantageous in mechanical power transmission applications.
Surface Preparation – This involves both surface cleaning and creating an anchor profile or modifying roughness. Surfaces are prepared before processes like coating, painting, galvanizing, oiling, welding, brazing, sealing, soldering, adhesive bonding, and rubber-to-metal bonding.
Paints, coatings, and adhesives require clean surfaces free of grease, oil, dust, or dirt for proper bonding. Surface contamination can act as a release agent or non-stick coating. Cleaning is essential to ensure chemical bonding and adhesion.
Rust and corrosion layers must be removed, particularly for protective coatings that meet the National Association of Corrosion Engineers (NACE) and Society of Surface Protective Coating (SSPC) standards. Abrasive blasting is used for three main reasons:
Paints and coatings do not adhere well to low roughness or smooth surfaces due to a lack of anchor points. A blast-roughened surface creates mechanical interlocking between the coating and the substrate.
Is it advisable to use the coarsest and sharpest blast media available for surface preparation before coating?
No, because excessive roughness can prevent thinner protective coatings from fully covering the surface, leading to pinholes and corrosion of the underlying material. Shot, bead, and abrasive blasting can smooth out some of the high peaks in a surface profile to enhance the performance of corrosion protective coatings.
Aggressive coarse grit abrasive blasting is effective for bonding thermal spray deposits, high build coatings, and polymeric lining systems. For thinner coatings and paints, a less aggressive profile with fewer high peaks is preferable, which can be achieved using round steel shot, glass beads, or other spherical media.
Aerospace – Plastic media is utilized to remove old paint from aluminum aircraft parts without damaging the underlying composite or soft aluminum metal. Blasting is also employed in the refurbishment of jet engine components and for NDT inspection of aircraft structural elements.
Additive Manufacturing / 3D Printing – Abrasive blasting removes support material from 3D-printed objects and can smooth surfaces while blending in striation lines created during the printing process.
Automotive Aftermarket – Sandblasters are vital tools in auto body shops and repair garages, used for rust removal, body and engine repairs, and antique car restoration.
Adhesive Bonding / Sealant Application – Surface cleaning and creating an anchor profile enhance the bond strength of adhesives and sealants.
Coating and Paint Application – Surface cleaning and profile generation improve the adhesion of paints and protective coatings. Sandblasters are crucial for preparing surfaces to accept coatings.
Corrosion Control Industry – Stripping damaged coatings, paint layers, rust, corrosion, grease, dirt, adhesives, and sealants is essential for recoating or repair. NDT inspection or corrosion assessment requires precleaning of the surface. Standards and cleanliness grades from the International Standard Organization (ISO), National Association of Corrosion Engineers (NACE), Society of Surface Protective Coating (SSPC), and American Society of Testing and Materials (ASTM) guide proper surface preparation before applying protective coatings.
Electronics – Micro abrasive blasters are invaluable for electronics repair, capable of selectively removing solder where reflow desoldering is impractical. They can strip conformal coatings that resist heat or chemicals and drill holes or vias in printed circuit boards (PCBs).
Foundries and Forges – Abrasive blasters, including centrifugal wheel blasters and pressure blasting equipment, are crucial in foundry and forge cleaning rooms. After shakeout, castings are blasted with metal shot or grit to remove mold sand, ceramic investment material, and surface oxide scale. Forged parts require blasting to eliminate die lubricant and oxide layers.
Glass Fabricators – Decorative glass items such as panes, bowls, and cups can be frosted or patterned using stencils or masks. Microblasting is also used for etching or engraving words and graphics onto glass. Sandcarving uses abrasives to deeply etch glass, creating 3D relief patterns or images. Typically, glassware is blasted with 180 grit silicon carbide.
Machine Shops / Manufacturing – Most machine shops, fabricators, and manufacturers use blast cabinets for cleaning, degreasing, deburring, and preparing machined or fabricated parts. Tools like dies, molds, drills, end mills, and saw blades are blasted to remove burrs and debris from cutting edges or teeth. Shot peening enhances the fatigue strength and lifespan of machined or ground shafts, tools, and structural components.
Medical / Dental – Cleaning, coating preparation, etching, and polishing of medical devices and dental restorations. For example, the investment or mold material on cast crowns or bridges can be gently removed with a small benchtop sandblaster or micro-blaster. Hip, shoulder, dental and other bone, and joint implants are blast cleaned to meet stringent FDA cleanliness requirements.
Nondestructive Testing (NDT) – Coatings, rust, corrosion, grease, and other surface contaminants must be removed before inspecting structural components for surface and subsurface cracks and defects. Clean surfaces are required for effective evaluations using ultrasonic, eddy current, penetrant testing, magnetic particle, and visual methods.
Plastic / Rubber Molding – Deflashing of molded parts and cleaning excess resin from molds or forms are essential processes. Dry ice blasting is commonly used to clean plastic and rubber molds, as rubber becomes brittle at low temperatures and can be easily abraded. Cryogenic blasting is employed to deflash rubber and plastic parts that have been chilled to cryogenic temperatures.
Remanufacturing – Engines, blocks, heads, brakes, and transmissions that are used or damaged are cleaned and refurbished by remanufacturers. Sandblast cabinets are used to remove rust, grease, gaskets, and coatings from these automotive components. Mating surfaces are ground to eliminate warpage, cylinders are reground or relined, and the remanufactured engine is reassembled for either return to service or resale.
Thermal Spray Coating – The formation of an anchoring surface profile using abrasive blasting of surfaces on jet engine blades and other critical components is essential attaining thermal spray deposit bond strength. Thermal spray coating will delaminate from smooth, unblasted surfaces.
Welding, Brazing & Soldering – Abrasive blasting is used prior to welding, brazing, and soldering to clean surfaces and ensure proper joint formation. After the joining process, additional blasting removes slag, rosins, oxide patinas, weld spatter, or splatter before applying protective coatings.
Woodworking / Cabinetry – Paint or wood sap is removed from wooden cabinets, furniture, and trim before painting. Sandblast Cabinets are also used for wood carving and sign etching.
Begin by considering the size, shape, and annual production volumes when choosing the type of blasting equipment. What is your production volume (parts per year), the size of the parts, or the surface area being blasted?
What media options are available to achieve the necessary cleanliness, profile, or surface engineering (residual stress)?
Review the different blast media options. If possible, arrange a trial at a supplier’s facility to assess various blasting processes and media.
Confirm the blasting process parameters with an additional test or trial.
Estimate the annual costs for operating and consumables, including compressed air, water, and electrical power.
What are the costs for consumables like blast media, wear part replacements, and system maintenance?
How many operators are needed to operate the blast system? Is specialized training for safety and automation systems required?
Include any additional questions to clarify training requirements as well as the annual estimated costs for operating, maintenance, and consumables.
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