GRINDING

Dressing is the process of sharpening the abrasive elements of the wheel. The process breaks down the bond and removes dull abrasive grains to expose new and sharp abrasive particles. Dressing also removes tiny pieces of material from the pores of the wheel face to prevent wheel loading, which can cause vibration and leave burn marks on the workpiece.

Without proper dressing, it's impossible to achieve the best consistency and adherence to specs from even the highest quality abrasive wheel. In fact, when you invest in top-quality grinding wheels, it becomes even more important to dress them properly in order to capture the quality and performance benefits.

Source: Dressed For Success

Dressing and truing grinding wheels prepare them for service and ensure proper accuracy for the grinding operation. Truing involves making the periphery of the wheel run concentric to the axis of rotation, and may require alerting the wheel by forming a special contour into its face. Dressing alters the cutting action of the wheel when the hard diamond point of a dressing tool breaks the bond posts of a vitrified wheel and fractures the grains, removing dull ones and making the new ones sharp. Dressing also picks up tiny pieces of material from the pores of the wheel face, ensuring that they do not slow the grinding process and cause burn or chatter.

Conventional dressing wheels do truing and dressing simultaneously with a light cut, while superabrasives require truing with a tool or roll, and separate dressing with a vitrified dressing stick. Before truing a superabrasive wheel, use a wax crayon over the wheel face — the process should eliminate all crayon marks by the end. Dressing a superabrasive will require direct application of a vitrified dressing stick (often aluminum oxide or silicon carbide, but sometimes high-performance norbide or boron carbide).

Source: Machining 101: What is Grinding?

On its surface, grinding seems simple: a machine takes a rotating tool (usually a wheel) with abrasive grains and applies it to a workpiece’s surface to remove material. Each grain is its own miniature cutting tool, and as grains dull, they tear from the tool and make new, sharp grains prominent.

But there are many variations, approaches and considerations for this type of machining, each of which is particularly effective for certain applications with certain materials.

Source: Machining 101: What is Grinding?

Compared to the more common surface grinding, creep-feed grinding employs a heavier grinding depth combined with a slow traverse rate, generally with a profiled grinding wheel, to generate a given geometric form at a material removal rate (MRR) that is much higher than the finishing passes for which grinding is generally known.

Source: 10 Things to Know About Creep-Feed Grinding

Blanchard grinding is a brand name that has become generic in its use, much like saying Kleenex when referring to facial tissue. What began as a machine developed by the Blanchard Machine Co. in the 1900s is now a moniker generically applied to a number of rotary surface grinding machines including Blanchard, Mattison and others. In 2004, Bourn and Koch Inc. purchased OEM rights to Blanchard and Mattison, building new surface grinders in its facility in Rockford, Illinois, as well as offering retrofit and rebuild services for older equipment.

Rotary surface grinding works like this: A large workpiece is held on a rotary table with a magnetic chuck if the workpiece is ferrous or with custom fixturing if it is not. The machine’s table spins the workpiece under a vertical grinding spindle, and a segmented grinding wheel is lowered face-down into the workpiece, contacting the surface in much the same way as a floor polisher or a street sweeper. The grinding wheel spins counter to the table’s rotation, leaving Blanchard’s signature crosshatch pattern.

Source: Keeping Blanchard Grinding Current

Although it has experienced a steady growth, electrochemical grinding (ECG) is mostly known as a niche process. Developed in the 1930s, it became popular in the US in the 1950s for grinding carbide cutting tools. At the time, the only other way to grind carbide was with an expensive, natural diamond grinding wheel. ECG has the ability to grind difficult-to-cut materials such as carbides, and this process became popular for producing cutting tools. But as disposable tooling inserts and molded near-net tool shapes were developed, ECG dropped off in popularity. Now, it’s mostly known in applications that work with challenging materials and thin-walled, fragile workpieces, including tubing cutoff, medical devices and parts for aircraft engines.

But according to Tom Travia, VP of Business Development at ECG equipment supplier Tridex (a Glebar company), potential applications for the process are again increasing as the technology advances. Today’s ECG provides an increasingly efficient option for machining challenging alloys, and OEMs in sectors such as medical see it as an effective way to machine precise components in these materials.

Source: New Applications for Electrochemical Grinding