Sanitary Bulk Material Handling Equipment Cleanability: Value, Risk & Outcome
Can a typical, industrial bulk material handling system in a sanitary processing operation be thoroughly cleaned, even to the microbial level? Probably. But, with every cleaning event of a process-inappropriate bulk material handling system comes increased costs for labor, consumables (such as detergents and water), and energy. And, more importantly, with hard-to-clean equipment in sanitary applications comes a greater risk for inspection failure and product contamination. This post, the third in a series (Part 1 and Part 2) regarding sanitary bulk material handling equipment, will address several structural design features to look for in the construction of application-specific, sanitary bulk material handling equipment. To proactively specify these cleanability design features into sanitary bulk material handling equipment will reduce the costs and time of cleaning events, will aid in improving validation and inspection outcomes, and will ensure optimal compliance contribution (OCC).
Continuous weld seams are ground to a No. 4 finish, hand-burnished to eliminate pits, dimples, and crevices.
• Continuous-weld seams, ground smooth to a No. 4 finish: Weld seams, particularly in product contact areas and adjacent areas, must be free of pits, dimples, and crevices that could harbor contaminants such as material residue, microbes, and allergens. In addition to the No. 4 finish, hand-burnished weld seams will improve gross soil removal and resistance to microbial build-up during operation and cleaning.
Non-obstructing raceway contains unbundled utility lines; reduces material build-up, eases cleaning, inspection.
• Unbundled Utility Lines and Hoses: Counter to the typical, industrial machine design philosophy, the utility lines and hoses should be left unbundled. Unbundled utilities will minimize the accumulation of food, dirt, or other organic matter; and therefore reduce the opportunity for growth of microorganisms. Unbundled does not mean uncontrolled. A non-obstructive raceway contains the utility lines and hoses and enables fast and thorough cleaning, promotes material release, eliminates re-cleaning, and aids validation and inspection.
• Laser-cut, Single-plate Sideframe Construction: Typical, industrial machine design often builds substructures using square-tube framework. However, inherent with square-tube construction is the significant number of internal angles, corners, and welded seams that will often block contaminants from cleaning procedures. Laser-cut, single-plate frameworks provides significant cleanability and sanitary operating advantages over square-tube framework. By eliminating the internal angles, corners, and weld seams, laser-cut, single-plate framework reduces cleaning steps, reduces water and detergent use, improves cleanability, and protects product from contamination.
Sure, process-inappropriate equipment can be put into sanitary processing operations, and it may perform its mechanical operations effectively. But, for the sanitary process operation that is driven by external influences such as regulatory compliance, or internal influences such as HACCP programs, application-specific sanitary equipment construction will provide OCC without compromise to the equipment's mechanical operation.
Sanitary Process Equipment: Product Safety Guidelines and Standards
Processing industries, such as: food, pharmaceutical, chemical, petfood, and many more recognize, everyday, their primary objective is to produce safe product that is free of microbial and physical contaminants. This is no mystery. It's a matter of fact. And, often, a matter of survival. Sure, their objective is clear, and the various industry guidelines, third-party standards, and governmental regulations are in place to, supposedly, assist in achieving the objective. Yet, with all the clarity of objective, and instruction for its achievement, a glance into these processing industries would seem to indicate a willingness to tolerate the integration of functionally inappropriate process equipment -- even at the risk of: [i] creating an unnecessary hindrance to cleanability and validation, [ii] increasing the likelihood of non-sanitary operation, [iii] heightened exposure to contaminates, [iv] incompatibility with sanitary facility design principles,[v] greater hazard for operators, cleaning and maintenance staff, and validation/inspection personnel, and [vi] reduced overall equipment effectiveness (OEE).
Sanitary tote dumper with application-specific, functionally appropriate design and construction provides definitive compliance with industry guidelines, regulatory standards.
Why the risk tolerance? Why the willingness to accept degrees of functionally appropriate equipment? Why the willingness to compromise and trade-off process equipment performance variables? "It's a common misperception within many processing and packaging operations that the necessity for truly sanitary equipment design increases only as material gets closer to the center of process operations," says Tom Krueger, CMC, president of Summit Laboratory. "Unfortunately, as a result, many processing operations have settled for force-fit, general industry bulk material handling equipment. In doing so, they have done little to eliminate the presence of contaminants at the point of material introduction, and possibly put their entire, downstream process operation at risk," says Krueger. "Likewise, without functionally appropriate sanitary bulk container filling and packaging equipment, the introduction into the marketplace of contaminated finished product can become an increased risk."