Note: This article was originally published Jan. 24, 2024, on practicalmachinist.com.
Q: Metal turnings shredders, horizontal and vertical axis crushers, bundle breakers, rolling ring crushers, and hammer mills all seem to achieve the same basic output: they modify metal scrap to create smaller, flowable chips and reduce its overall volume. So, what are the unique benefits and limitations of these individual components?
A: Let’s tackle this in two groups. In the first group, we have shredders, horizontal axis crushers and bundle breakers, which have one thing in common: they modify low-volume quantities of metal turnings to create flowable chips that are ready for additional downstream processing.
And while all those systems achieve the same outcome, they each do it differently. Shredders shear the material. Bundle breakers tear the material apart. Horizontal axis crushers rip and grind the material until flowable chips are produced. This reduction is necessary not only to protect the downstream equipment during further processing, but also promote consistent and efficient results.
Bundle breakers modify bushy wads of metal scrap so that augers and steel belt conveyors can successfully transfer material that would otherwise bounce around an in-feed hopper. Shredders and horizontal axis crushers, on the other hand, need the metal scrap to be semi-flowable for augers/conveyors to consistently feed the material into the system for modification. The trade-off is that shredders and horizontal axis crushers can provide continuous volume reduction right at the source (though they can also be utilized as free-standing units).
Bundle breakers can also free solid parts and bar ends that may be trapped in the bundle. Shredders and horizontal axis crushers alone are not recommended for processing material containing solids such as bar ends and parts pieces.
Shredders, horizontal axis crushers, and bundle breakers typically operate at low speeds with high torque — their drives usually only need to be 2-10 horsepower. This can help keep energy costs down.
In the second group of metal scrap modification systems, we have vertical axis crushers, rolling ring crushers, and hammer mills, which provide more heavy-duty processing compared to the components in the first group. Each of these units offer continuous positive feed operation, which enables them to process high volumes of metal scrap that are too large for conveyors. The end result of these units are flowable, thumbnail-sized metal chips, or in some instances, fine powders. In contrast, shredders, horizontal axis crushers, and bundle breakers produce chips more in the range of 2 to 6 inches in size.
These high-volume systems are lower torque but operate at higher speeds. Vertical axis crusher motors are usually around 20 HP, while motors for rolling ring crushers need to be upwards of 50 horsepower. Of these heavy-duty units, vertical axis crushers are on the lower end of the throughput spectrum — although if floor space allows, multiple units can usually be installed to process higher volumes. Rolling ring crushers and hammer mills are capable of processing high volumes of material.
Regardless of whether you need a light-duty or heavy-duty metal scrap processing solution, both levels of volume reduction will help decrease storage needs, lower costs for transporting metal scrap, and maximize value from a recycler.
Q: What are some considerations when it comes to updating equipment to recover cutting fluids from metal scrap?
A: There are two advanced players used in the downstream recovery of metalworking fluids from scrap: chip centrifuges (also known as chip wringers) and briquetters.
Chip centrifuges dry chips by using centrifugal force to spin cutting fluids off the metal scrap. They can be used as stand-alone units or incorporated into a chip processing system and typically reclaim the highest percentage of fluid.
Briquetters compress the metal scrap into pucks and squeeze the cutting fluid out of it, producing the densest form of metal scrap that recyclers value. Just because pucks sometimes command higher prices from recyclers, doesn’t automatically mean a briquetter is the right option for your operation. Other factors to consider whether to spin or briquette chips, include:
If an operation’s primary goal is to reclaim cutting fluids and lower fluid replacement expenses, a wringer is usually the answer. But if the volume of scrap is high and transportation cost is an issue due to hauling longer distances, then minimizing the size of the material through briquetting would likely maximize value. Aluminum pucks on average weigh about 125 lb./cu. ft. (depending on the briquetter manufacturer, unit model, the size of the briquette produced, and the density of material before briquetting). Nevertheless, pucks are nearly ten times denser than loose chips, and they enable shops to optimize container fill and save on storage.
When it comes to chip centrifuges/wringers, there are three main styles to consider: those that are designed similar to top-loading washing machines, those where the bowl is oriented more like a front-loading washing machine, and those with a diagonal-shaft orientation (think of a top-loading washing machine tilted downward about 45 degrees).
In models with a top-loading orientation, it can be difficult to evacuate all the material from the system after operation. This can lead to spent fluid and small metal fines wearing seals out prematurely.
Q: What should shops consider to get the most value from chip processing equipment and optimize ROI?
A: Securing the capital for waste stream processing equipment can be a real hurdle, especially for a complete chip processing system. Naturally, stand-alone components (such as a shredder, crusher, or centrifuge) are less expensive than systems that integrate those components into an end-to-end chip processing solution. But in the long run, integrated systems offer several benefits:
Additionally, wear abatement strategies are important considerations. Physics and experience dictate where and how a particular part will erode over time. Various wear-resistant materials provide specific advantages but may have drawbacks in other functional areas.
Finally, knowing exactly what material the equipment will be running is the key to a durable installation. Simulating processing goals by having your material test-run through the equipment being considered is the best way to validate its capabilities. Whether the test is conducted in-person or remotely, it will provide valuable insight into its effectiveness in your specific application.
About the Author
Mike Hook is the Director of Sales & Marketing at PRAB and has more than 15 years of mechanical design and application experience.