Tuesday, November 10, 2015

2016 Carbide Insert Catalog Now Available

Premium Quality Tooling at Competitive Prices

Our 2016 Carbide Insert catalog is now available.  Milling and grooving inserts have been added along with several new chip breakers and coatings.  It doesn't matter if you are a one person shop or a large scale production facility we will save you money with our inserts.  We have a near 100% success rate when we test against any one of the big brands carbide companies out there.  Not only do we perform equal to or greater than your existing tools, we are almost always less expensive.  Whether you are looking at cost-per-part or cost-per-insert we can help drive down your total production costs.  Engman-Taylor has partnered with some of the best manufacturers in the industry and carbide inserts are no exception.

Contact us today to request a catalog or to arrange a trial.

Don't get us wrong, we represent many of the world's premier carbide manufacturers and they are often the first choice for turning and milling operations.  There are a lot of choices out there and we are here to recommend the best insert for the job no matter how the package is labeled.  Every job, material, and machine presents a unique challenge; we will help you determine which inserts are, or are not, good candidates to try.  We rely on our cutting tool applications specialists and so should you.

We know that every job is a balance between cost and performance and we strive to always provide the right tool for the job.  Whether or not you make a profit often comes down to this choice and we realize that you may not always need, or want to pay for, indefinite tool life.

We carry all popular styles, sizes, chipbreakers, and grades.  From CCGT to VCMT we have you covered.   Browse our online catalog and don't let the prices fool you; these are premium quality cutting tools without the big brand markup.  Call today to learn more 800-236-1975.


Carbide Inserts

View the complete catalog here (pdf)

View a cross reference / grade comparison chart here (pdf)

Shop Online here




Round Tooling


View the complete catalog here (pdf)

Shop Online here

Monday, November 2, 2015

Compression Cutter for Composite Materials

This week we took an in-depth look at Harvey Tool compression cutters.  This one was an easy choice; first off we have had a few requests lately for tools specifically designed for composites and secondly Harvey Tool provides some excellent technical articles on their website.  If you do any machining at all you are already familiar with Harvey tool but on the outside chance that you are unfamiliar contact Engman-Taylor - we would be delighted to ship or deliver a catalog you.

Composite Materials

First of all let's explain "composite" materials.  Composites are materials, and the machining of, are growing in popularity mostly because of the aerospace industry and in performance automobile manufacturing.  These materials though are also appearing in bicycles, bathtubs, guitars and other commonly produced products.


Composites are a group of materials made up of at least two unique constituents, that when combined produce mechanical and physical properties favorable for a wide array of applications. These materials usually contain a binding ingredient, known as a matrix, filled with particles or fibers called reinforcements. Composites have become increasingly popular in the Aerospace, Automotive, and Sporting Goods industries because they combine the strength of metal, light weight of plastic, and rigidity of ceramics. Many times a composite is used in cases where an extremely high strength to weight ratio is needed. A composite is also often layered with varying fiber and tape orientations, which help to increase strength in the material.

Composite materials are generally machined using standard metal cutting end mills. These unidirectional helix mills bring a few issues to the machining process such as lifting, fiber pullout, and de-lamination in layered composites.

Machining composites can be difficult because of two primary factors.  First of all composites are very abrasive, and can prematurely wear most cutting tools including carbide tools.  Secondly, composites tend to de-laminate during milling and drilling operations.  Sharp edges and space -age coating can increase tool-life but tool geometries can help here too.

Harvey Tool Compression Cutters 

To combat these machining challenges, the compression cutter has both an up and down-cut helix. The top half of the flute, closest to the shank, has right hand cutting teeth with a left hand spiral, forcing chips down. The bottom portion of the flute, closest to the end, has right hand cutting teeth and a right hand spiral, forcing the chips up. When cutting, the opposing flute directions generate counteracting up and down-cut forces. The opposing cutting forces stabilize the material removal, which causes a superb finish on both the bottom and top of the workpeice, limits fiber pullout, and stops de-lamination.

Choosing the Right Diamond

Another factor to consider when machining composites is the abrasiveness of the material. Glass and carbon fiber filled materials have the tendency to wear down the edges of carbide cutting tools. To account for the rough nature of composites, the compression cutter is offered coated with Amorphous Diamond, a PVD coating with DLC properties, and CVD Diamond, a diamond coating that is chemically grown onto the carbide. Each coating is better suited for different materials. The Amorphous Diamond is a thin layer of diamond that does not experience edge rounding from the thickness of the coating, making it suitable for materials that contain less than 30% of abrasive fill. Since these materials are more matrix than fill, they will create a chip when machined. When cutting materials with a higher concentration of fill, the CVD diamond coating is found to be very beneficial. The CVD coating is five times thicker, and has superior abrasion resistance to the Amorphous Diamond. At the micro-level, the cutting action is similar to that of a grinding operation, which makes the coating best suited for heavily filled composites that will produce a powder-like chip when machined.





Example of Milling Carbon Fiber: https://youtu.be/6-RjLwMOQBk

Sources:
http://www.harveytool.com/cms/TechnicalResources_266.aspx
https://en.wikipedia.org/wiki/Composite_material

Let us know some of the challenges you face in machining composites or show your composite material finished products.