Appreciating the Value of Secondary Cleaning Processes

Cleaning can often be the deciding factor in production of an acceptable part.

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Often considered non-value-added steps, post-process operations such as cleaning, deburring and even gaging can become low-priorities, leaving a shop rushing through them or ignoring opportunities to improve the way they are carried out for the sake of shorter lead times and lower costs. But this approach can be dangerous, as such processes typically have an effect on the final appearance, quality and performance of the part.

In some critical applications such as medical and aerospace, the importance of the finish is obvious. In others, it might not be so clear. In either case, when the parts go out the door, the customers better be happy with what they receive. The further into the production schedule that flaws are found, the more costly they become, and if they’re found while in the customer’s hands, the greatest expense may be the loss of future business.

Higher Quality is the Goal

If a company is aware of a quality issue with its products, of course it will take the proper measures to resolve the problem. Sometimes the issue may be the result of a particular step of the production process that is flawed in some way. Sometimes the issue is an inherent part of the product, regardless of who is producing it, and an entirely different method must be developed or a step added to compensate for the shortcoming.

Aluminum die castings are a critical part of the auto industry. Engine blocks, transmissions, air conditioning systems and other components use aluminum die castings. But these castings have a problem with porosity that can be partially controlled, but not eliminated. Castings, by nature, go from a liquid to a solid. During this densification process, the casting shrinks, and as it cools at different rates, it develops porosity.

This porosity can lead to leakage in the casting unless other steps are taken to counteract the effect. The auto industry has been fighting this issue for years, even as it has continued to improve castings. The biggest influencer on casting quality—atmosphere—is something that cannot be controlled, and humidity and moisture have a significant, yet widely ranging effect on porosity.

Generally, after the casting process, the part is machined, and it is either leak tested to identify leak paths from one side to another or it is impregnated to close the porosity. If porosity is not controlled, leaks will occur.

Delivering on a Need

Imtech of California Inc. in Santa Fe Springs is a full-service job shop offering parts cleaning, impregnating and final leak testing tailored to customer needs. Imtech’s large autoclaves and specialized impregnation techniques are designed to handle a wide range of part sizes and quantities.

According to President Peter Gebhard, it would be quite difficult to get through a day without touching something that companies like his didn’t have a part in producing. “Every car, truck, aircraft, water treatment facility and pump has an impregnated part. The list is endless,” he says. In this location since 1988, the company serves many different markets. Gebhard explains that by resolving the problem of the subsurface porosity, the ultimate result of the surface finishing, whether painting, plating, anodizing and so on, is better and the number of rejects is substantially reduced. In the case of aluminum castings, he says that companies often lose up to 10 and 20 percent of production without impregnation. The cost of impregnation is generally less than 5 percent of the cost of the casting itself, so it easily offsets those potential losses from rejected parts.

 

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The Serec airless system uses solvents in a controlled atmosphere and recovers them for reuse.

 

The Need for Clean

Of course preparing a part’s surface for final finishing operations goes beyond impregnation. Dealing with a variety of manufacturers such as automotive and aerospace, Imtech’s cleaning line has delivered on significant demands. About half of the parts that the company processes go through its vapor degreasing system. The more difficult the porosity-associated issue is, whether it’s a finishing or a pressure-tightness problem, the more likely it is to be cleaned.

According to Gebhard, people don’t always realize vapor degreasing is still a viable option, but with the right control processes in place, it can indeed serve as the best option in many applications. “When dealing with the porosity in castings, water-based cleaning has very specific limitations,” he says. “You start with water—the cleaning media—and it has a surface tension in the mid-70 dynes. To get it to clean, you have to lower that surface tension with detergents, just like when washing dishes. Adding a surfactant helps to break down the dirt in an electrochemical reaction.”

But there is still a limitation because even after adding the chemistry to the cleaning water and adding ultrasound energy or impingement energy (a spray), or some sort of washing energy such as tumbling, the surface tension continues to be kind of high, and the water itself cannot enter the pores that it needs to. Oils and other contaminants have a much lower surface tension somewhere in the teens (dynes). “To deal with these contaminants, the perchloroethylene solvent that we use is down around 2 dynes, and when it’s at temperature it’s below 1,” Gebhard explains. “It easily gets into the porosity and displaces the contaminants. Then we take it out through an evaporation process and we have a clean part.”

The System

Imtech has been using a Serec airless vapor degreasing system in its facility since 1998, with a new system being added about two years ago. Gebhard helped develop the original system in 1990 in response to the Clean Air Act. While this legislation did not ban halogenated solvents, it placed strict guidelines on their use. This vapor degreasing system uses the solvents without losing them like the open-top degreasers did.

According to Bill McCormick, president at Serec, roughly 80 percent of the systems sold by the company are customized to fit the customers’ applications. Such is the case with the system at Imtech, designed for a variety of metals and part sizes.

The system is an airless vacuum machine—a closed-loop system with built-in distillation, heated vacuum solvent recovery. It features low emissions and greater than a 97 percent recovery from the waste stream. Processing under vacuum, there is no solvent/air interface. With no air in the chamber, it is able to perform deep cleaning and drying on complex features.

Getting it Done

Cleaning can be an expensive step in the production process, but it is valuable—a value determined based on the losses that would be incurred without it. Shops that take cleaning seriously are the ones that have fewer reject rates and are the top performers in the industry. Gebhard says, “You can tell when you walk in the doors, by the way a shop is set up and the way they work, that they are serious about cleanliness. These are the shops that will be in business down the road.”

One Imtech customer had been struggling with a cast titanium ring with an interior diamond coating. Experiencing multiple failures with the part, the company thought impregnation may be the solution. By running UV light inspections, Imtech determined that these parts, worth thousands of dollars and previously thought to be “cleanroom quality,” had fingerprints on the coatings. While impregnation was useful for these parts, the real impact was the addition of proper cleaning, which is critical for the success of the parts. “Anyone having adhesion problems should first look at their cleaning procedures,” says Gebhard. “If the material surface is not prepared appropriately, they’ll never have success. It’s an old issue, but people still don’t pay enough attention to it.” 

Originally published in the November 2015 issue.

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