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Reducing compressed-air usage.

In a previous article (Nov. 2010), we discussed the first step to optimizing energyintensive compressed-air usage--which is to plug wasteful leaks. The second step of a compressed-air optimization program is to reduce usage where possible. For many plants this is the most important and cost-effective step. Reducing usage minimises the demand, reduces generation costs, and allows correct sizing of the system.

Many manufacturing sites, not only in plastics processing, operate on the assumption that compressed air is free. Usage is totally uncontrolled, and they fail to realize that open air lines cost real money: For example, a 3-mm open air line at 100 psi will cost you around $1300 per year--the same as a leak. In many cases, also, compressed air is used for applications where almost any other type of power would be cheaper.

THE COMPRESSED-AIR MAP

An important tool in reducing usage is a "compressed-air map" of the site (see Fig. 1 below). This is a survey of the complete usage of compressed air and an assessment of both the cost and the real need for using it. A compressed-air map will inevitably reveal many areas where the process can be easily changed to reduce compressed-air usage and costs.
FIGURE 1: Example of a Compressed-Air Map

Bowl Feeder CURRENT Can Be
 No. Cost/yr Re-engineered?

Bowl: 6 x 2 mm diameter 6 $3600 Yes
Bowl: 8 x 3-mm diameter 8 $9600 Yes
Track 1:4 x 2-mm diameter 4 $2400 Yes
Track 2:4 x 2-mm diameter 4 $2400 Yes
 $18,000

Bowl Feeder Cost of RE-ENGINEERED
 Re-engineering No. Cost/yr

Bowl: 6 x 2 mm diameter $1000 2 $1200
Bowl: 8 x 3-mm diameter $2500 2 $2400
Track 1:4 x 2-mm diameter $300 1 $600
Track 2:4 x 2-mm diameter $800 1 $600
 $4600 $4800

Bowl Feeder Savings Payback,
 per yr yr

Bowl: 6 x 2 mm diameter $2400 0.42
Bowl: 8 x 3-mm diameter $7200 0.35
Track 1:4 x 2-mm diameter $1800 0.17
Track 2:4 x 2-mm diameter $1800 0.44
 $13,200 0.35


Use of compressed air for actuators, cylinders, and slides often consumes a very low volume of air because these are "closed" applications where very little air is discharged to atmosphere--i.e., only the volume of the cylinder or actuator. The real energy hogs are when compressed air is used for "convenience" applications where a quick fix was needed in the past but has now become part of the operating environment. Examples found in real-world plants are an open 3-mm air line used to move plastic bottles across a conveyor (cost: $1300/yr per line) and two 3-mm open air lines used to pre-bend PS foam egg cartons (cost: $2600/yr). Open air lines are effectively "leaks."

The compressed air map should include any and all open air lines used for the following, where compressed air costs more than simple alternatives:

* Cooling (of product, motors, or tooling);

* Moving (product or raw materials);

* Cleaning;

* Testing;

* Hand tools.

The compressed-air map can be used to quantify the cost of compressed air for each application, the possibilities for re-engineering the process, and the potential costs of the re-engineered process. It often comes as a surprise to quantify the true cost of using compressed air, and that simple calculation often drives reduced usage.

Applications in the compressed-air map should be categorized as either "optional" or "vital." All optional uses should be closely examined for re-engineering to eliminate that use altogether. It is rarely difficult to justify the cost of re-engineering when the cost of the current compressed-air usage is calculated. (Note: Reducing the use of compressed air will also reduce noise in the plant as an added benefit.)

RE-ENGINEER THE PROCESS

Re-engineering is often a simple matter of examining (in detail) the specific application and applying good engineering practice. A flow chart for reducing compressed air usage is shown in Fig. 2.

The size of the gains is often astronomical. We have worked with plants having substantial assembly operations (always an energy hog), and the standard target that we set for compressed-air usage is a 50% reduction within 12 months. In fact, with good techniques and dedicated engineers, this is generally achieved within nine months.

[FIGURE 2 OMITTED]

Next installment: Optimize the generation of compressed air.

ABOUT THE AUTHOR

Dr Robin Kent is founder and managing director of Tangram Technology Ltd. in Hitchin, Herts., U.K. Tangram provides consulting and training in plastics engineering and design. Kent has 36 years' experience in injection molding and extrusion as technical director for several processing companies in Europe. Articles in this series are adapted from Energy Management in Plastics Processing (2008, 265 pages, pidbooks.com). Contact rkent@tangram.co.uk or visit tangram.co.uk.

By Robin Kent, Tangram Technology Ltd.
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Title Annotation:#10 in a series
Author:Kent, Robin
Publication:Plastics Technology
Date:Jul 1, 2011
Words:799
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