Abrasive-cutting processes are widely used to obtain semi-finished products from metal bars, slabs, or tubes. Thus, the

abrasive cutting-off process is applied when requiring precision cutting and productivity at a moderate price. Cut-off tools

are discs composed of small abrasive particles embedded in a bonding material,

called the binder. This work aims to compare the cutting performance of

cutting disc
s with different composition, in dry cutting of steel bars. To do that, disc wear was measured and disc

final topography was digitalized in order to determine both disc surface wear patterns and if the abrasive particles bonding

into the binder matrix was affected. In addition, X-Ray inspection gave information about the abrasive grit-binder bonding.

Therefore, the method here presented allows identifying discs with a superior abrasive-cutting capability, by combining

profilometry and tomography to define micrometrical aspects, grit size, and binder matrix structure. Results led to the

conclusion that discs with high grit size and protrusion, high grit retention by bond material, and closer mesh of fiberglass

matrix binder were the optimal solution.


    Plenty of manual cutting applications call for a hand-held grinder and cutting wheel. Cutting sheet metal, sizing a piece

for fabrication, cutting out a weld to refabricate it, and cutting and notching in pipeline work are just a few examples of

what can be accomplished using a grinder and cutting wheel.


    Resinoid-bonded cutting wheels are a popular choice to achieve these types of cuts because they offer portability and

allow you to cut in many different angles and orientations. The bonding agent, in this case resinoid, holds the wheel

together so it can cut effectively. The bond wears away as the abrasive grains wear and are expelled so new sharp grains are

exposed.


    By following a few best practices, you can extend wheel life, promote safety, and improve productivity and efficiency

within the process.


    The Basics of Cutting Wheels


    The main considerations in using resinoid-bonded wheels include the cutting application, the tool being used—such as a

right-angle grinder, die grinder, or chop saw—desired cutting action, the material being cut, and space. Wheels typically

provide a fast cutting action, long life, and tend to be cost-effective.


    The two main types of resinoid-bonded abrasive cutting wheels are Type 1, which are flat, and Type 27, which have a

raised hub. Type 1 wheels generally are used for straight-on cutting on electric or pneumatic right-angle grinders or die

grinders and chop saws, among other tools. Type 27 wheels are required when there is some type of interference and the

metal cutting disc needs to be raised up from the

base of the grinder, but personal preference also plays a role in the decision. They are most commonly used with electric or

pneumatic right-angle grinders.


    Resinoid-bonded abrasive cutting wheels are available in various sizes and thicknesses. The most popular range is 2 to 16

inches in diameter, and common thicknesses are from 0.045 in. to 1?8 in. Thinner wheels remove less material during the cut.


    Some types of wheels cut faster than others. The abrasive material used in the wheel is one influencer on cut rate and

consumable life. Wheels come in several grain options, such as aluminum oxide, silicon carbide, zirconia alumina, ceramic

alumina, and combinations of these materials.


    While not as sharp as other grains, aluminum oxide provides toughness and good performance for cutting on

steel. Silicon carbide, on the other hand, is a very sharp grain but not quite as tough, making it suitable for cutting

nonferrous metals. Zirconia alumina is a self-sharpening, tough, durable grain that holds up well in a range of

demanding applications. Ceramic alumina also is designed to self-sharpen as it “breaks” at predetermined

points to maintain a consistent cut rate and long life.


    When selecting a resinoid-bonded abrasive wheel, consider that products made with a mixture of zirconia or ceramic

alumina with a harder bond typically cost more but offer durability and longer consumable life.


    Make sure to refer to the manufacturer’s recommendations, product descriptions, and RPM ratings to select the proper

wheel size and bonded abrasive material for your application. Matching the size and RPM rating of the tool to the size and

RPM rating of the wheel is critical for safe and effective usage. Choosing the tool with the greatest amperage or amount of

torque while staying within size and RPM requirements of the wheel will increase performance.


    The kind of tool and the tool guard that you use also are factors that play a role in the type of wheel that can be used

for an application. A larger-diameter wheel works best if you’re cutting deep into metal or need to cut a piece with a large

diameter, for example, because it eliminates the need to rock the wheel back and forth during the cutting process. Look for a

wheel with the diameter designed for the size and thickness of material being cut.


    Thin wheels, such as aluminum cutting disc,

on the other hand, tend to remove less metal during the cut and have shorter life spans, but provide a quicker cut. There are

some exceptions to this as different versions of thin wheels are lasting longer, so be sure to do your research before you

make a final decision to ensure the wheel you select maximizes efficiency.


    Specialty cutting wheels are also available that are designed for use with certain materials, such as stainless steel and

aluminum.


    Proper Positioning and Other Tips


    In addition to paying attention to designations for RPM rating, size, and material, you should also follow these tips

when using resinoid-bonded abrasive cutting wheels.


   
       
            Use the cutting wheel at a 90-degree angle, perpendicular to the work surface.
       
   
   
       
            Apply the proper amount of pressure—not too much, not too little—to allow the cutting wheel to do the work.

Always avoid pushing too hard on the wheel, which can cause the grinder to stall or kick back or give you a much less

efficient cutting action. It also increases the chances that you will slip or lose control of the tool, which can cause

damage or injury.
       
   
   
       
            Choose a grinder with the highest torque or amperage available for the application, as this will help the wheel

to do more of the work. For example, instead of using a 4.5-in. Grinder cutting wheel on a 6-amp grinder, use a 4.5-in. wheel on a 10-amp grinder. The RPM rating

remains the same, but the tool will provide more torque to cut into the metal.
       
   
   
       
            Choose a tool and consumables that offer quick, consistent cutting, which typically provides the most efficient

performance.
       
   
   
       
            Remember, the thinner the cutting wheel, the more susceptible it can be to side loading, which is a term that

describes when the wheel bends while moving side to side in the cut. This can turn dangerous if you lean too hard on a wheel,

which can cause the wheel to break or jam in the cut. It can also reduce the efficiency of the wheel and increase the cut

time.
       
   
   
       
            Store the wheel in a clean, dry environment, and avoid placing it in water or mud. This helps minimize

environmental effects that could degrade its performance or cause it to crack or wear prematurely. The performance of

resinoid bond tends to deteriorate when the wheel is stored for extended periods of time, so be sure to use FIFO (first in,

first out) when using wheels.
       
   
   
       
            Inspect the wheel and consumable before each use to check for signs of damage or wear. Cutting wheels, including

angle grinder cutting discs can become

harder to control as they wear down. If you can no longer make a safe cut because the wheel’s diameter is worn so thin, then

the best course of action is to replace it.
       
   


    A grinding disc is defined by the type of abrasive material,

bonding material, grain size, structure of the wheel, and grade of the wheel used for the machining of a component. These

factors decide the grinding efficiency of the grinding wheel

and surface finish quality of the machined component. A wide range of abrasives are being used in modern era to

overcome necessities in machining of various make of components. Abrasives ranging from the economic verses of aluminium

oxide to the likes of super-abrasives such as cubic boron nitride and the expensive diamond grains are used for machining as

well as surfacing purposes. Over the years, research has depicted that no distinct abrasive material can meet all the

requirements of grinding applications. The mechanical and physical properties of a particular abrasive material make it

suitable for a certain application.



    Wire Brushes


    A wheel wire brush is an abrasive tool that has

stiff bristles made from a variety of rigid materials designed to clean and prepare metal surfaces. The filaments of wire

brushes are small diameter pieces of inflexible material that are closely spaced together as a means for cleaning surfaces

that require aggressive and abrasive tools. The means of applying the brush can be either manual or mechanical depending on

the type of brush and the surface to be treated.


    The short video below explains the manufacturing of a unique type of wire brush called a wire drawn brush, which is a

very sturdy and durable brush that is made by a process that ensures filament retention.


   




   


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