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FDA Compliance

Food Processing: Automatic Scraper Strainers Protect Critical Membrane Systems

Preventing damage caused by large, suspended particles

Published: Wednesday, July 13, 2022 - 11:03

The use of membrane technology as a processing and separation method in the food industry is gaining wide application for demineralization, desalination, stabilization, separation, deacidification, purification, and reducing microbial load.

Perhaps the most obvious application for membrane filtration is reducing dissolved or suspended solids from process water or liquid ingredients. However, membrane filtration can be used to remove microorganisms to prolong shelf life and provide a healthier option than utilizing additives and preservatives.

Membrane separation can also be combined with cold pasteurization and sterilization techniques to create products and ingredients with favorable characteristics. Since membrane separation eliminates the need for heat temperature treatment of products, it can preserve the natural taste of food products and the nutritional value of heat-sensitive components. Also, less energy is required.

Membrane processing plays a key role in wastewater treatment, as well. Wastewater derived from food production varies depending on the type of food (animal processors/rendering plants, fruit/vegetable washers, or edible oil refiners). By implementing membranes, the separated substances and clean water are recoverable.

The challenge for food processing facilities is that membrane systems are delicate and can be easily damaged or subject to excessive maintenance due to large particulates in the water. A prefiltration step eliminates this risk by removing oversized suspended solids to prevent damage, eliminate unnecessary maintenance, and reduce the cost of premature membrane replacement.

Among the prefiltering options available, automatic self-cleaning scraper strainers are increasingly popular because they are affordable, require minimal maintenance or attention, and can remove solids down to 75 microns. The strainers allow for continuous, uninterrupted flows even during blowdown cycles. When compared to filters that must be manually cleaned, or even conventional backwash systems, automatic scraper strainers can save substantial costs on maintenance and membrane replacement.

With the automatic scraper strainer, cleaning is accomplished by a spring-loaded blade and brush system managed by a fully automatic control system.

Industrial water treatment and membrane systems

Although various filtration methods use membranes, the most mature is pressure-driven membrane filtration, which relies on a liquid being forced through a filter membrane with a large surface area. Depending on the size and type of the particles involved, the process could be categorized as reverse osmosis, nanofiltration, ultrafiltration, or microfiltration.

Automatic scraper strainers like those from Acme Engineering Products can provide continuous removal of suspended solids to comprehensively protect membrane systems.


In general, reverse osmosis is used to produce potable water or deionized water. Ultrafiltration and microfiltration are increasingly used in water and wastewater treatments.

In industrial applications, water treatment is also vital to protect downstream equipment from fouling, scaling, corrosion, and other forms of damage or premature wear due to contaminants in the source water. For these reasons, cooling tower and boiler-feed water is generally pretreated.

Membrane filtration is also utilized to treat nonpotable water sources such as gray water and reclaimed/recycled “purple pipe” water.

Because the membranes are made of thin, porous sheets of material, failing to sufficiently prefilter any large, suspended particles from the water can cause severe damage and fouling—leading to premature replacement and unnecessary maintenance, according to Robert Presser, vice president of Acme Engineering Products, a North American manufacturer of industrial self-cleaning strainers.

“Most membrane filter manufacturers recommend that all influents be prescreened from 100 to 500 microns to maintain membrane filter efficiency,” says Presser, whose company is an ISO 9001:2015 certified manufacturer of environmental controls and systems with integrated mechanical, electrical, and electronic capabilities.

He adds that automatic scraper strainers are typically installed before the intake plenum of membrane filters, after the supply pumps.

Extending membrane life

As an alternative to sand filters, centrifugal separators, and basket-type strainers, automatic scraper strainers provide superior membrane protection while drastically reducing required maintenance.

Automatic scraper strainers like those from Acme Engineering can provide continuous removal of suspended solids to comprehensively protect membrane systems. The automatic units are motorized and designed to continually remove suspended particulates in industrial process water and wastewater to the specific size required, down to .003-in. (75 microns).

Conventional manual strainers can become clogged quickly due to limitations in straining area. When that occurs, cleaning or media replacement is required, which increases maintenance costs. The other alternative for fine straining is automated backwash-style strainers of various designs. As particle sizes grow larger, however, large contaminants can jam up the backwash system or remain in the body of the strainer, requiring manual removal and interruption of the process flow.

With the automatic scraper strainer, cleaning is accomplished by a spring-loaded blade and brush system managed by a fully automatic control system. Four scraper brushes rotate at 8 RPM, resulting in a cleaning rate of 32 strokes per minute. The scraper brushes get into the wedge-wire slots and dislodge resistant particulates and solids. This approach enables the scraper strainers to resist clogging and fouling when faced with large solids and high solids concentration. It ensures a complete cleaning and is very effective against even organic matter “biofouling.”

With this type of system, manual maintenance for cleaning is eliminated. Blowdown occurs only at the end of the intermittent scraping cycle when a valve is opened for a few seconds to remove solids from the collector area. Liquid loss is well below 1 percent of total flow.

With so much to gain, food processors should consider selecting an automated, self-cleaning system that is essentially “set-and-forget,” where automatic scraper strainers comprehensively protect delicate membranes and allow personnel to focus on other aspects of the facility.

For more info, visit Acme Engineering Products at acmeprod.com.


About The Author

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Del Williams

Del Williams is a technical writer based in Torrance, California. He writes about business, technology, health, and educational issues, and has a master’s degree in English from California State University-Dominguez Hills.