Physical-Characteristics-of-the-Vibratory-Bowl-and-How-They-Affect-Processing-Efficiency

Physical Characteristics of the Vibratory Bowl and How They Affect Processing Efficiency

By : Bill Nebiolo ,

Physical Characteristics of the Vibratory Bowl and How They Affect Processing Efficiency

William P. Nebiolo, REM Chemicals, Inc., Southington, CT  06489

A look at how design characteristics affect machine performance and which characteristics to consider when ordering a machine.

Vibratory bowls are outfitted with hot-poured polyurethane liners and their durometer hardness is an oft-cited characteristic. But what is durometer hardness and how is it useful?

Physical-Characteristics-of-the-Vibratory-Bowl-and-How-They-Affect-Processing-Efficiency

Durometer hardness is the measure of an object’s ability to resist indentation by a probe that is pressed into its surface using a prescribed load. The technique, developed by Albert Shore, is used to quantify the hardness of assorted elastomers, rubbers and plastics. Durometer hardness is to elastomers, rubbers and plastics what Rockwell hardness is to metals.

Durometer hardness is measured using durometer tester.

durometer tester

Image of a durometer tester3

Activating a durometer tester depresses a spring loaded indenter pin which deflects the target’s surface. The meter measures this deflection.1 Differences in surface deflections are compared to known measurement standards.

 

Since hardness values of elastomers, rubbers and plastics vary, indenter pins of varying widths and shapes are employed.  For example, a sharp-pointed pin, would be unsuitable for a gel-like substrate as it would penetrate; rather than deflect its surface.3

 

durometer indenter tips

Image of assorted durometer indenter tips

The unit of measure for the hardness reading is known as Shore Hardness; honoring inventor Albert Shore. The most commonly used Shore Hardness scales are:

Shore 00 Scale for gels & elastomers

Shore A Scale for rubbers

Shore D Scale for plastics

 

 

 

The durometer characteristics of common, well known items appear in Table 1.1

Table 1

Polyurethane Liner Wear

Polyurethane liners are subject to wear during use but wear is accelerated with the use of abrasive media.3  Polyurethane liner thickness is manufacturer specific and an important purchase detail.  Typically liner thickness is 0.8 inches, however thickness of just 0.5 inches are common on more economically priced equipment.3

 

At some time during ownership the equipment will require a reline.  This is expensive with a price tag of $3,000 – $10,000 depending upon size and channel complexity.3  Additionally, relining is done off-site which incurs shipping costs and production downtime.3

 

It is therefore beneficial to run the equipment in a practical fashion to complete the job at hand while understanding the consequential liner degradation that is occurring.  Use of the least abrasive media possible will extend liner life. Table No. 2 compares media used to liner cost and durability.

Table 2

 

 

 

 

 

 

 

 

Ribbed vs. Smooth Bowl Lining

Ribbed liners are typically utilized in applications where flat parts are being processed or flat media must be used.3

physical characteristics Vibratory ribbed vibe bowl wall

Image of a ribbed vibe bowl wall3

With a flat liner wall, small flat-shaped parts or small, flat-shaped media will adhere to the O.D. wall due to liquid surface tension.3  Adhering parts are removed from refinement action during processing.

 

physical characteristics Vibratory flat-based media

Image flat-based media adhering to smooth wall

 

In applications where small flat parts; such as coin blanks, or where small, flat media is required a ribbed wall liner will break surface tension keeping parts in the mass.3

 

Rubber vs. Polyurethane Liners

Heavy, highly-polished, 300 lbs. per cubic foot steel media is used in peen-polish processing.

 

physical characteristics Vibratory assorted steel media shapes

Image of assorted steel media shapes3

 

During peen-polishing surface asperities aren’t cut away with an abrasive media but are pounded flat and laminated onto the part’s surface.  The final finish is cosmetically attractive and the soft alloys are more favorably peen-polished.

surface asperities on a zinc die casting

Image of surface asperities on a zinc die casting

peen-polished, laminated asperities

Image of peen-polished, laminated asperities

peened copper plumbing

Image of peened copper plumbing tees4

Steel media presents a unique complication in the vibratory bowl. Table 1 shows that a 90 durometer Shore A hardness is typical for a supplied polyurethane liner.3 When this hard liner is matched to the polished steel media, the media can gain little traction; imagine a hockey puck on clean ice.

 

Therefore, vibe bowls intended for steel peen-polishing, are typically supplied with a Shore A 60 durometer hardness rubber liners.3  The weight density of the media mass above the lowest layer of media in the vibe bowl channel will indent the softer durometer rubber liner, to momentarily form a cup-like depression beneath the steel media.3  The momentary cup formation gives the steel media stable traction to initiate vertical rolling motion.

Ramped-Channel Vibratory Bowls 

Ramped-channel bowls greatly facilitate part unloading. Imagine one thread around the circumference of a bolt and you can envision this affect. Flat-channel bowls are more commonly hand or magnetically unloaded. A bowl ramp spirals around the hub to a crest where parts fall over the edge to the channel bottom. Parts at the ramp bottom then become impingement damage targets. Parts weighing one pound or more are impingement endangered in ramp-bottom bowl processing. 

Ramped Bowl Precautions 

Falling Part Impingement Damage: Parts cresting the ramp and falling atop other parts is an invitation to part-on-part damage. Ramped bowls are a better consideration for hardened steel parts. 

Changing Media Volume on the Ramp: Media not only refines the parts but it also keeps them separated during processing. As media depth decreases with ramp height, there is less mass present to keep parts separated and impingement can increase. 

Cantilevering of Long Parts: Long-shaped parts cantilever over the crest during processing. Machine vibration bounces the part against sharp media edges, which is another source of part surface damage. 

Separation Deck Damage: If the ramp empties onto a separation deck, then parts bouncing along the deck are subject to mechanical damage. This is a less attractive option for metallurgically soft parts manufactured in zinc, brass or copper. 

Vibratory Bowl Sound Cover 

In vibratory departments where numerous machines operate simultaneously, the noise level may need to be attenuated. This is accomplished using a sound cover lined with sound-absorbing foam. Sound covers come in two varieties — hard covers and soft covers. 

Hard-Style Vibe Bowl Sound Cover: Hard-style vibe bowl sound covers are typically of a clam-shell design manufactured in steel or in lighter weight fiberglass. The cover is lined with sound-absorbing foam and is mounted on a pedestal from which it is raised or lowered into position by means of pneumatic pistons. 

Soft-Style Vibe Bowl Sound Cover: Soft-vibe bowl sound covers (typically known as bonnets) are a circular-shaped tubular frame covered with a nylon shell and lined with sound absorbing foam. The cover is suspended over the vibe bowl by an “L”-shaped flag pole and is raised or lowered by means of a clothes line. More economical in design and cost, the bonnet-style sound cover affords the same degree of sound protection at a more budget-favorable price point. 

Heat Retention from Sound Covers: When sound covers are in use, it should be noted that they will retain frictional heat in the bowl. It may be desirable in such situations to increase the flow rate of the compound being pumped into the vibe bowl. 

References

  1. Albright Technologies, Leominster, MA; Image courtesy of Albright Technologies at info@albright1.com; 2015
  2. Microdynamic Systems Laboratory; Carnegie Mellon University, Pittsburgh, PA; Parts Feeders: Mobile Vibratory Feeder; 2015
  3. Nebiolo, William P.; REM Training Manual Edition No. 9; 2014
  4. Nuttall, Josh; How to Repair a Leaking Copper Pipe Fitting in a Water Line; Image courtesy of E-How at ehow.com; 2015
  5. Sweco, Inc.; Image courtesy of Sweco, Inc., 8029 Dixie Hwy., Florence, KY 41042; 2015
  6. Vibrochimica, SRL, Image courtesy of Vibrochimica, SRL,Via San Paolo della Croce, 2,Liscaste, Milano, Italy; 2015

 

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