Finishing Stainless Steel for Food Grade Applications

Designing, fabricating, assembling, finishing, and cleaning equipment for food-grade applications, regardless of the alloy used, has myriad requirements that must be met every step of the way. The term food grade and its many variants refers to surfaces that have, in the federal government’s terminology, a sanitary finish—a finish that is safe for processing food products and can easily and reliably be cleaned and sanitized.

The grinding, sanding, and finishing of food-grade stainless steel must result in surfaces devoid of areas that encourage bacteria growth. The surfaces must be free of lines, grooves, pits, or divots. Additionally, the surfaces must withstand corrosion from the food being handled and the chemicals used to sanitize the equipment. Also note that stainless steel isn’t a single material; many stainless alloys are used in food-oriented applications (see Figure 1).


Judge a Book by Its Cover, and the Story Inside

In the majority of applications, a finish at the high end of No. 4 is considered food grade (see Stainless Steel Finishes sidebar). This finish is achieved using a high-grit abrasive in the range of 150-220 and is identified by short, parallel lines that run the length of the material. The success of the finish can ultimately be determined by a surface roughness average (Ra), measured by height in millionths of an inch (µin.) or microinches. A profilometer determines Ra values by moving a diamond stylus across the workpiece’s surface for a specified distance and using a specified contact force. It measures small surface variations and calculates their average to determine the roughness. In most food-grade applications, 60-36 Ra is achieved with 150-220 grit. Because milk products spoil more quickly and carry more bacteria than other food and beverage items, dairy applications should have a finer finish, No. 4A, which is 40-24 Ra and achieved with a 220-grit abrasive or finer.

Keep in mind that the abrasive’s grit value isn’t the only determinant of the surface finish; other factors are the condition of the abrasive, the particular tool, its speed, and the operator’s technique.

Areas that do not come in direct contact with food don’t need to adhere to the sanitary finish specifications. However, they do need to be cleaned and sanitized frequently, so the surface should be able to accommodate such harsh treatment. In these instances, it is most often easier – and more aesthetically pleasing – to use a consistent finish for all the surfaces. Bear in mind that cleaning and sanitizing are more effective if the system is designed to discourage the bacteria buildup (see Tips for Designing, Assembling a Sanitary Piping System sidebar).

Finishing the inside of a pipe or tube can be a challenge. After welding slag is flushed out, the best finishing tools usually are long arms and elbow grease. For small diameters, mounting a flap wheel to a flexible shaft is a possibility. Long stretches of pipe require a little more creativity. The tool might be as simple as an abrasive mounted to a long dowel or a broomstick.


Choosing Abrasives and Tools

The abrasive and the tool shouldn’t be chosen in isolation; they should be evaluated together to arrive at the best combination for the job.


The Right Abrasive for the Job.

Each project requires several products with various grits to achieve the final finish. Conventional abrasives are composed mainly of aluminum oxide or zirconium. These materials perform well, but ceramic materials are making inroads. Nonwoven abrasives such as fleece provide an even, consistent finish without shadows. Their softness reduces chattering on the surface and resists glazing from soft materials. Another new class, unitized abrasives, also are finding their way into the mainstream. As with other products, the decision to switch to ceramics or unitized abrasives requires careful evaluation of their costs and benefits.


The Right Tool for the Job.

Because most fabricated pieces are unique in design, few if any tools enable mass production of a finish. Therefore, most finishing is done by hand or with a hand tool. Some tools, to use the terminology of Food Network personality Alton Brown, are “unitaskers,” whereas others are “multitaskers.” If you find good old hand abrasives and elbow grease aren’t right for the job, these guidelines can help you select a tool. 

  • Among the tools that essentially do one job, aka unitaskers, are finger belt sanders and wraparound pipe sanders. Finger belt sanders are ideal for getting into angles and tight spaces. Their narrow abrasives fit into small areas where traditional belt sanders are too large. Wraparound pipe sanders finish the circumference of both open and closed pipe constructions (see Figure 2).

  • Tools that can perform many functions, aka multitaskers, include combination finishers/wraparound pipe belt sanders and linear finishing machines. The combination finisher/wraparound pipe belt sander performs several processes on round and flat surfaces. It removes weld seams in straight lines without edges or wavy finishes and longitudinally grinds flat surfaces to remove spot welds and deep scratches. Its sanding belt also follows the individual contours of pipes and handrails to grind, sand, and polish the surface to a smooth, blemish-free finish.

  • A linear finishing system is well-suited to finish long, flat surfaces without shadows, streaks, or transitions. This tool is also adept at finishing in corners. Linear finishers are ideal for graining, polishing, brushing, blending, and deburring. Flap wheels, belt sleeves, and brushes can all be used on this machine.
     

Need a Little Direction?

Choosing the right tool and abrasive are not enough to get the job done; the geometry of every component requires careful consideration. Round pipe is best-suited for circumferential, not lengthwise, finishing. Square pieces are best finished lengthwise, in the same direction, on all four sides. Trying to go around all four sides in one pass will result in an uneven finish with poor grain quality. Flat expanses of material are best taken a section at a time, always working in the same direction. Pay close attention to the areas where the sections join; blend them until the transitions are nonexistent.

Note that when finishing and sealing pieces that will be in direct contact with food, use only chemicals and cleansers certified by the NSF. The NSF Web site provides a listing of all certified chemicals for use in food production facilities. Federal, state, and local agencies can provide documented procedures for cleaning and handling food-grade fixtures. Periodic inspections are performed by local towns and municipalities and certifications are awarded upon satisfactory completion of the inspections. Failure to comply can result in fines and, in some cases, reconstruction and refinishing.


Polish the Approach and the End Is in Sight

Now armed with all of this technical information about food-grade finishing, the next question is, “What can go wrong?”

  • The customer’s expectations are crucial. Finishes that are simple, such as a grain that runs the length of a rail, have a lower time-cost factor than a difficult finish, such as a grain that goes around the circumference of a square tube or pipe.

  • Before assembly, ensure that all pregrained pieces have a consistent pattern. When welding two or more pieces together, make sure the grain patterns are aligned as closely as possible. A mistake early in the process is almost impossible to correct later on.

  • Always choose the correct application-specific tool for the project. This will increase productivity and decrease total costs.

  • Use the finished spot as a starting point, and work toward unfinished areas. Going the other direction leads to mismatches. 

  • Haste makes waste. The best finish is achieved with time and patience. Hurrying can lead to using a material that is too aggressive to start, applying too much pressure, or using tools at a speed that is too high for the application. The result often is a surface that has deep scratches, requiring rework.


Note that designing, assembling, and finishing a food-grade project require substantial technical knowledge, but ultimately the project’s success hinges on compliance with the standards established by the governing authority (see following chart).


Common Stainless Steel Applications

Stainless Steel Alloy

Classification

Typical Applications

430

Ferritic

Used for moderately corrosive applications involving vegetables, fruits, and dry foods. Ideal for table surfaces, equipment trim, and places with little welding or forming.

420

Martensitic

Very durable; excellent corrosion resistance. Used for knife blades, spatulas, and other utensils.

316

Austenitic

Superior durability, ideal for food processing equipment and components. Can withstand corrosive foods and frequent cleaning and sanitizing.

304

Austenitic

Excellent corrosion resistance; often used for items requiring welding and forming, such as vats, bowls, and piping.

303

Austenitic

Less weldable but more machinable than 304. Good corrosion resistance; widely used in trim and other applications not intended for direct contact with food.

1.4539

Austenitic

Suitable for hot or cold corrosive foods that sit for long periods, such as brines and other salty liquids.

1.4462

Duplex

Stronger than 1.4539; ideal for same applications.

6% Molybdenum

Austenitic

Well suited for corrosive foods and high temperatures such as steam heating and hot work areas.