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Industrial Mixer

Written by Maki Onari and Eric Olson | Sep 16, 2025 5:09:04 PM

Preventing Vibration Part 1 of 3

What is an acceptable vibration level for the mixer used as an example in this blog?

An overall value as properly measured that is:

  • Lower than 0.17 inches per second (ips) RMS per ANSI/Hydraulic Institute Standard 9.6.4 this is the value for a similar vertically suspended pump) or
  • Lower than 0.13 ips RMS for machines (above 15kW) ISO 10816 – 3 or
  • Lower than a value set by the specifying engineer. For example, 0.12 ips RMS

Reducing Mixer System Vibration Risk

Overview and The Specification

Mixers are critical components in Wastewater Resource Recovery Facilities (WRRFs), playing a key role in optimizing digester performance. Mixers are critical components in Wastewater Resource Recovery Facilities (WRRFs), helping optimize digester performance. Due to their importance leading Architect/Engineering (AE) firms now specify independent system-level vibration risk reduction measures, not only after installation with the Vibration Acceptance Test (VAT) activity, but during the plant design and construction phases.

Why Proactive Vibration Risk Reduction Matters

The most expensive and disruptive vibration problems are caused by resonance, which can occur when a natural frequency of the mixer system is excited. In these cases, vibration can be amplified tenfold or more, potentially damaging equipment, delaying projects, and increasing warranty and maintenance costs over the plant’s lifetime. Many WRRF operators already have successful experience with independent vibration assessments on new or modified pump system projects. Manufacturers also benefit—one pump manufacturer noted that their warranty costs approach zero when the Engineer of Record (EOR) requires independent vibration risk reduction analysis. The same proactive approach to risk reduction also makes sense for mixer systems.

This blog and the companion one-page PDF document explain important terms such as:

  • Natural Frequency
  • Resonance
  • Amplification Factor
  • Separation Margin

A key point is that, in general, structural and acoustic natural frequencies depend on the entire as-assembled system, including the soil, foundation, machinery, connected piping, ambient conditions, performance requirements, and fluid characteristics.

Why Early Testing and Analysis Matters

Eliminating vibration issues before commissioning benefits all parties involved, including plant owners, contractors, AE firms, and equipment suppliers. The optimal time to begin is early—ideally during the Request for Proposal (RFP) stage—by including requirements for vibration analysis and testing in the specification.

Figure 1 (below) addresses the question: “At what point in a project timeline should vibration expertise be applied to reduce the risk of vibration issues in new or modified plant designs?   This three-part blog covers:

Part 1: The Specification

Part 2: The Dynamics Analysis

Part 3: The Vibration Acceptance Test (VAT)


Figure 1. Answers the question: “At what point in a project timeline should vibration expertise be used to help reduce risk for a successful new or modified plant design?” This three-part blog discusses the Machinery System Dynamics Analysis and post-installation vibration testing (shown on the right). The case history at this link covers the earlier Plant Design Dynamic Assessment phase (shown on the left).

  

Three Parts to Vibration Risk Reduction

Reducing vibration risk in rotating machinery systems—such as mixers, pumps, centrifuges, blowers, compressors, and turbines—requires a proactive approach integrated into the plant specification, analysis, and testing phases. By addressing vibration risk early, owners and operators can avoid costly resonance-related failures, reduce warranty claims, and enhance system reliability.

Separation margin is the percentage difference between an excitation source (e.g., running speed) and the system’s natural frequencies. Key terms—such as natural frequency, resonance, amplification factor, and separation margin—are explained in this one-page document.

  1. The Specification Wording

The first step is to ensure that the specification sets clear requirements. The ANSI/Hydraulic Institute Guideline 9.6.8, Rotodynamic Pumps Guideline for Dynamics of Pumping Machinery, provides an excellent framework for pump systems, and its principles can be adapted for other rotating equipment. Effective specifications should:

  • Define acceptable overall vibration levels.
  • Require a separation margin to prevent resonance excitation.

AE firms are now including clauses that require an Experimental Modal Analysis (EMA) or impact test to verify separation margins. This ensures that vibration risks are addressed at the system level, not just the component level. MSI is available to assist with specification wording.

  1. The Dynamics Analysis

The second step is to conduct a dynamics analysis during the design stage. While no tool can perfectly predict future vibration issues, analysis provides the next-best assurance by estimating separation margins. Confirming that a sufficient margins exists helps ensure that a system’s natural frequencies will not coincide with running speed over the plant’s lifetime. Later, this analysis can be validated during the Vibration Acceptance Test (VAT). Part 2 of this blog will explore the dynamics analysis process in detail.

  1. VAT, including an EMA (Impact) Test

The third and final step is performing a Vibration Acceptance Test (VAT) after installation. Modern mixer specifications often require VATs that include an Experimental Modal Analysis (Impact) test to confirm that separation margins near critical natural frequencies are adequate.

Relevant standards include:

  • ANSI/HI Standard 9.6.4: Rotodynamic Pumps for Vibration Measurement and Allowable Values
  • ISO 10816: Mechanical vibration standards
  • API Standards: For rotating equipment in the oil & gas and petrochemical industries

The specification for the mixer that is the subject of this blog required an allowable overall vibration of 0.12 in/s RMS or less at each bearing housing based on post-installation field testing. Factory tests may also be performed, but they cannot fully account for site-specific factors such as foundations, piping, and soil conditions, or other factors related to the actual installation.

Why Separation Margin Matters

Although ANSI/HI 9.6.4 does not explicitly require separation margin testing, leading AE firms now include it in purchase specifications for pumps, mixers, centrifuges, and blowers. Understanding the natural frequency separation margin and amplification factor provides valuable insight into how the system will behave over its lifetime, helping to prevent resonance-related vibration problems before they occur.

Looking Ahead

Part 2of this blog will discuss the analysis phase used to identify and correct potential pump system vibration issues. Part 3 will outline best engineering practices for performing a Vibration Acceptance Test, including an Experimental Modal Analysis (Impact) test, to confirm separation margins near critical natural frequencies.

Please contact MSI if you would like a vibration risk reduction tutorial or support in drafting specifications, performing dynamics analysis, or conducting field testing to minimize post-installation vibration risks in rotating machinery systems. 
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