Evaluate cleaning strategies to improve productivity

Reliability, safety can increase with a clean plant environment.


In every type of manufacturing environment and industry, industrial equipment and parts need to be cleaned-from A consistent cleaning regimen is part of any successful maintenance program, but often can get overlooked when developing a maintenance strategy. All images courtesy of Omegasonics.precision aerospace instruments to carburetors to equipment that manufactures pharmaceutical products-and the degree of cleanliness and how it's achieved varies widely. Today's industrial environment is marked by highly accurate machining and finishing processes and precision manufacturing methods. The result is manufacturing tolerances, or permissible limits in a product's variation in physical dimension or measured value, are tighter than ever. Therefore, any contamination or debris left behind on parts is sure to be problematic and must be removed for the parts to function reliably.

Reliability takes on a slightly different meaning when talking about items that will come in contact with the human body, such as pills from forming machines or medical testing or surgical instruments. In these instances, it is imperative to remove dirt, debris, and abrasive contaminants, as well as molds and toxic chemicals that can make humans sick.

This is an issue especially prominent in the pharmaceutical industry where manufacturers actually need to validate their cleaning method per FDA requirements. All residue must be removed from the equipment prior to manufacturing the finished product.

In addition, if parts need to go to a plating or coating stage, they need to be exceptionally clean for the coating to stick. Finished parts generally cannot go to end users with cutting fluids on them.

Equipment that's not properly cleaned can become unreliable and affect the reliability of the part it's producing. Without industrial cleaning to keep manufacturing equipment free of dirt and grime, parts wear faster, breakdowns occur more often, and efficiency and productivity suffer.

The flow of fluids, lubricants, heat, and air all suffer when parts become dirty. Increased friction means greater heat buildup, which may lead to premature equipment failure.

For equipment that undergoes routine maintenance, more thorough cleaning can extend the time between scheduled maintenance, which keeps machines running longer and eliminates downtime. If a machine or component is not cleaned well enough during routine maintenance, then it will need to be cleaned more often, shortening the time between scheduled maintenance.

The result is lost productivity due to a production line that is frequently down. Furthermore, today's manufacturing plants are made up of many complicated systems in motion at all times. This includes employees and equipment. As all good business people know, production flow is critically tied to revenue, so interruptions to production-especially chronic disruptions-can severely impact revenue.

Different cleaning systems

Industrial cleaning equipment is most often found at the end of a parts manufacturing process or in settings where parts must be regularly cleaned to function at peak efficiency. An industrial washer is a machine that removes contaminants from the surfaces of a part or component before it's sent to the next step in the manufacturing process.

Depending on how the part is made, the foreign materials can include machine oil, casting sand, metal shavings, polishing compound, and even human skin and oil. To expedite the process and manage labor costs effectively, manufacturers often use an industrial washer to clean the parts rather than spend the time and money to clean each one by hand.

In some industries, a clean plant operation is important. For those in the food and pharmaceuticals, it is regulated, putting a stronger emphasis on such practices. All images courtesy of Omegasonics.Different types of industrial cleaning equipment remove contaminants with varying effectiveness, depending on the intricacy of the part.

For example, almost any type of system can clean a smooth, highly polished surface, whereas complex and intricate parts require a more sophisticated cleaning process. If a part has blind or drilled holes, internal passageways, sharp inside corners, or rough surfaces, removing contaminants for improved reliability can be problematic.

Since any contaminant can cause reliability issues, starting with the cleanest possible surface is imperative, and choosing the right industrial cleaning equipment becomes paramount.

Spray washers
or power washers operate much like a dishwasher, with revolving high-pressure water jets that spray the parts to remove foreign materials. This type of industrial cleaning unit is used for general cleaning and removing gross contaminants, such as heavy dirt or rust, from large, smooth, and/or flat-faced surfaces.

A good example of an effective use of a spray washer is for the external surface of a large steel mold or the external surface of a car engine to remove grease and dirt. A spray washer will not perform any precision cleaning and is best suited for raw external surfaces.

For example, a spray washer is not a good choice for cleaning the internal exhaust ports of an engine because the streaming water can't necessarily get into those hidden areas.

Immersion cleaners soak parts in cleaning solutions to dissolve the contamination from the surface. Immersion cleaning is a better option for cleaning irregular shapes that have surfaces that are difficult to reach with spray washers. Typically, the parts are placed in a basket or barrel and the process can include agitation.

Solvent cleaners
are a specific type of immersion industrial washer. Parts are bathed in solvents like acetone, naphtha, or mineral spirits. This type of cleaner is very effective at removing oil and grease, and sometimes requires a special enclosure to control the dangerous vapors and hazardous waste materials it generates.

Manual cleaning
involves cleaning done by hand, often using toxic chemicals and an endless variety of implements, including rags, toothbrushes, wire brushes, cotton swabs, air compressors, fingertips, and more. Not only is hand labor the most time intensive industrial cleaning method, potentially wasting many hours of manpower, but the cleaning itself often is hit or miss-nooks and crannies that cannot be seen or reached don't get cleaned.

Sometimes, even parts cleaned in immersion tanks don't come out clean enough and require additional hand cleaning. Manual cleaning may be the best option for manufacturers that have a very low volume of parts to wash. A cost-benefit analysis can help determine at what volume an industrial washer would make sense.

Outsourcing parts cleaning to a third-party is a route that some manufacturers take when they find that manual cleaning is uneconomical within their operations. Outsourcing has some disadvantages as well, though, chiefly that manufacturers must accumulate parts before sending them out to qualify for a bulk discount. The time it takes to accumulate enough parts can impact lead times and cause production delays, not to mention the personnel time spent on, and cost of, shipping, packaging, and paperwork.

Ultrasonic cleaners are used when a part is very complex, it needs to be super clean, or the manufacturer wants to save on labor and energy costs. Unlike spray washers, immersion cleaners, or using solvents, industrial ultrasonic cleaners decontaminate at a near-microscopic level and can clean threads, drilled and blind holes, sharp inside corners, rough surfaces, and inaccessible internal cavities not reachable by other types of industrial washers.

<< First < Previous Page 1 Page 2 Next > Last >>

Top Plant
The Top Plant program honors outstanding manufacturing facilities in North America.
Product of the Year
The Product of the Year program recognizes products newly released in the manufacturing industries.
System Integrator of the Year
Each year, a panel of Control Engineering and Plant Engineering editors and industry expert judges select the System Integrator of the Year Award winners in three categories.
June 2018
2018 Lubrication Guide, Motor and maintenance management, Control system migration
May 2018
Electrical standards, robots and Lean manufacturing, and how an aluminum packaging plant is helping community growth.
April 2018
2017 Product of the Year winners, retrofitting a press, IMTS and Hannover Messe preview, natural refrigerants, testing steam traps
June 2018
Machine learning, produced water benefits, programming cavity pumps
April 2018
ROVs, rigs, and the real time; wellsite valve manifolds; AI on a chip; analytics use for pipelines
February 2018
Focus on power systems, process safety, electrical and power systems, edge computing in the oil & gas industry
Spring 2018
Burners for heat-treating furnaces, CHP, dryers, gas humidification, and more
April 2018
Implementing a DCS, stepper motors, intelligent motion control, remote monitoring of irrigation systems
February 2018
Setting internal automation standards

Annual Salary Survey

After two years of economic concerns, manufacturing leaders once again have homed in on the single biggest issue facing their operations:

It's the workers—or more specifically, the lack of workers.

The 2017 Plant Engineering Salary Survey looks at not just what plant managers make, but what they think. As they look across their plants today, plant managers say they don’t have the operational depth to take on the new technologies and new challenges of global manufacturing.

Read more: 2017 Salary Survey

The Maintenance and Reliability Coach's blog
Maintenance and reliability tips and best practices from the maintenance and reliability coaches at Allied Reliability Group.
One Voice for Manufacturing
The One Voice for Manufacturing blog reports on federal public policy issues impacting the manufacturing sector. One Voice is a joint effort by the National Tooling and Machining...
The Maintenance and Reliability Professionals Blog
The Society for Maintenance and Reliability Professionals an organization devoted...
Machine Safety
Join this ongoing discussion of machine guarding topics, including solutions assessments, regulatory compliance, gap analysis...
Research Analyst Blog
IMS Research, recently acquired by IHS Inc., is a leading independent supplier of market research and consultancy to the global electronics industry.
Marshall on Maintenance
Maintenance is not optional in manufacturing. It’s a profit center, driving productivity and uptime while reducing overall repair costs.
Lachance on CMMS
The Lachance on CMMS blog is about current maintenance topics. Blogger Paul Lachance is president and chief technology officer for Smartware Group.
Electrical Safety Update
This digital report explains how plant engineers need to take greater care when it comes to electrical safety incidents on the plant floor.
Maintenance & Safety
The maintenance journey has been a long, slow trek for most manufacturers and has gone from preventive maintenance to predictive maintenance.
IIoT: Machines, Equipment, & Asset Management
Articles in this digital report highlight technologies that enable Industrial Internet of Things, IIoT-related products and strategies.
Randy Steele
Maintenance Manager; California Oils Corp.
Matthew J. Woo, PE, RCDD, LEED AP BD+C
Associate, Electrical Engineering; Wood Harbinger
Randy Oliver
Control Systems Engineer; Robert Bosch Corp.
Data Centers: Impacts of Climate and Cooling Technology
This course focuses on climate analysis, appropriateness of cooling system selection, and combining cooling systems.
Safety First: Arc Flash 101
This course will help identify and reveal electrical hazards and identify the solutions to implementing and maintaining a safe work environment.
Critical Power: Hospital Electrical Systems
This course explains how maintaining power and communication systems through emergency power-generation systems is critical.
click me