Choosing an appropriate tool and using it correctly can have a positive effect on the grinding process. However, knowing how to select a tool and what solutions are available to dress conventional grinding wheels is very useful. #Basics
Production grinding relies on several components working together to achieve desired results. Whether that result is a size, shape, finish, or combination of these, the system works best when all its components are optimized and being used correctly.
The focus is on the abrasive and using the best grinding wheel available, but there is more to the system than just the abrasive wheel. Coolant also has a substantial effect on the grinding operation. However, the most overlooked component of the grinding system is the truing and dressing tool.
Often, a premium abrasive product will be installed at a premium price, and it is then expected to perform optimally while truing and dressing it with the least expensive tool possible. It is akin to putting regular fuel in a high-performance car.
Choosing an appropriate tool and using it correctly can have a positive effect on the grinding process.
Whether using a rotary device or a stationary tool, in many systems the dressing tool is almost completely forgotten about until a finish, form or geometric issue occurs and an investigation ensues.
Choosing an appropriate tool and using it correctly can have a positive effect on the grinding process. However, knowing how to select a tool and what solutions are available to dress conventional grinding wheels is very useful.
Truing and dressing is often thought of as being the same process, with the terms sometimes used interchangeably when discussing the truing and/or dressing procedures. This is likely since, with the exceptions of some resin or metal bonded products in which the wheels are trued offline and then remounted and dressed, the two operations are usually done at the same time.
However, they are two different processes.
Truing operations deal with the form or profile of the grinding wheel. When truing a new abrasive wheel, the grinding face is altered to allow the abrasive product to do what it needs to do. Routine truing during the grinding process corrects the wheel profile and compensates for form loss as the wheel breaks down under regular use. A properly trued wheel will impart the correct profile on the part being ground and ensure the form geometry and dimensioning are to spec and ready for use.
Although the term “dressing” is often used to describe the truing and dressing, dressing operations only restore or alter the condition of the wheel face. Grinding wheels are dressed to restore or change their ability to remove stock or generate a specific finish. If the wheel is being used to remove stock, the grinding face is dressed to expose new and sharp cutting points, allowing the wheel to cut with a higher material removal rate. However, the tradeoff is that the finish may be unfavorable. A wheel dressed in this condition is said to be “open.”
If the wheel is being used to generate a specific finish, the grinding face will be dressed to dull or blunt the cutting points, allowing the wheel to rub more and create the finish necessary. The tradeoff here is that although the finish is good, the stock removal rate will be much lower. A wheel dressed in this condition is said to be “closed.”
It is also important to know how to choose the correct diamond tool for the operation.
There are three considerations when selecting the appropriate tool:
Abrasive wheels are, in the most basic sense, stones. To generate a form on that stone, or create a specific surface condition on it, a harder stone is needed. Diamonds are used to true and dress grinding wheels since diamonds are the hardest known material.
The first consideration helps determine the required diamond tool size in carats. Whether the tool will be a single diamond or multiple diamond design, knowing the size, bond and abrasive type of the wheel being trued and dressed will help determine how big the diamond needs to be.
Although the diamond tool will be harder than the grinding wheel it will be used on, the abrasive grains will eventually erode the diamond. The amount of diamond wear is a function of the amount of time the diamond is in contact with the wheel, so a larger wheel will need a larger diamond.
This chart (left) provides the suggested total size of the diamond or diamonds required, whether that is a single diamond or multiple diamonds based on wheel size.
It is recommended that one size larger diamond should be used if:
Just as there are several different wheel profiles that can be trued into a wheel face, there are also several different types of stationary tools that can be used to generate or restore them. Knowing which of the available tools are most appropriate or capable will help narrow the options. The second consideration is based on the form or profile required on the wheel.
A stationary tool may be as simple as a diamond on a stick such as a single point tool, or a more complex tool as in the case of precision lapped chisel tip tool. The diamond tool may be a few thousandths wide where it contacts the wheel, or it could be much wider.
Understanding the characteristics and limitations of each tool is important to help determine which one can do what it is needed it to do. A straight or taper profile can be achieved with nearly any tool, while more complex profiles may only be generated with a much shorter list of available tools.
The illustration (right) shows commonly available tools and types of wheel faces they can generate or are typically used to restore.
The third and final consideration in selecting a stationary tool is based on the price and overall life of the tool, which is determined by the quality of the diamond.
Although there is no standard for industrial diamond quality, it is generally agreed upon that the higher quality diamonds have a longer life. A high-quality diamond will have fewer inclusions, cracks and imperfections, while a higher quality diamond will have more defined points. All the diamonds pictured (below) are ½ carat in size, and the higher the quality the better defined the shape and points are. Selecting a tool with the highest AA quality will also allow a resetting or relapping program to be established.
Resetting is where the used diamond is removed from the tool and reset with the next best point exposed. Relapping is a mechanical process used to restore the geometry or profile of the tool to its original print dimensions. Both take the initial price of the high tool and spreads it out over time, making the overall cost to use the tool much lower. Using lower quality diamonds (D quality) doesn’t allow for resetting, although they are usually less expensive and intended to be disposable.
The only other considerations are mechanical. Considerations include shank size and style (length, diameter, taper), and diamond profile (radius, relief).
These attributes will ultimately be determined by the machine being used and many manufacturers can make custom tools. Although there are several different stationary tools available, here some of the more common stationary truing and dressing tools, and some quick tips on how to correctly use the most common ones.
Both the single point and chisel point tool should be mounted on a slight angle at the center line of the grinding wheel as seen below.
Multi-Point and cluster tools need to be mounted with the tool face oriented horizontally and square to the wheel face at the centerline of the wheel. Tool shank should be on a slight angle.
It is very difficult to make quality parts if the grinding wheel is not maintained properly, and that cannot be done without using a high-quality dressing tool.
With a better understanding of stationary dressing and truing tools, and how to select them, hopefully the most overlooked grinding system component will get the attention it deserves.
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