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Rcm Analysis Worksheet

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Use this skill when a reliability engineer, maintenance planner, asset integrity lead, or RCM facilitator needs to conduct a Reliability-Centered Maintenance (RCM) analysis for industrial equipment or a process system. Follows SAE JA1011 and MSG-3 principles: function identification, functional failure analysis, FMECA, Maintenance Significant Item (MSI) classification, decision logic tree execution, and maintenance task selection with intervals. Produces a DRAFT RCM worksheet for reliability engineer and maintenance-manager review before any maintenance program change.

Install

openclaw skills install rcm-analysis-worksheet

RCM Analysis Worksheet

Guides a reliability engineer or maintenance team through a structured Reliability-Centered Maintenance analysis — from function identification through maintenance task selection — producing a DRAFT RCM worksheet ready for team facilitation review.

Flow

Phase 1 — System and Context Definition

Ask the user for:

  1. Asset/equipment name, tag number, and plant/facility
  2. System boundary and physical configuration (subsystems included)
  3. Operating context: production rate, operating hours, environment, duty cycle
  4. Criticality context: safety-critical? Production-critical? Environmental impact?
  5. Existing maintenance strategy (if any) — for baseline comparison
  6. Available FMEA or failure history data (optional)

Ask one block at a time. Wait for answers before proceeding.

Phase 2 — Function and Functional Failure Identification

For each subsystem or component the user identifies:

  1. Functions: List primary function(s) with performance standard

    • Format: "To [verb] [object] [performance standard] in [operating context]"
    • Example: "To circulate cooling water at ≥ 1,200 GPM and ≤ 15 PSIG pressure drop under normal production conditions"

  2. Functional Failures: For each function, identify all ways the function can fail

    • Format: "Fails to [function verb] at all" OR "Fails to [function verb] to standard"
    • Each functional failure gets a letter designation (A, B, C…)

Confirm the function/failure list with the user before proceeding.

Phase 3 — Failure Mode and Effects Criticality Analysis (FMECA)

For each functional failure, identify failure modes (specific causes):

#Failure ModeFailure CauseFailure Effect (local / system / plant)Failure Pattern (A–F)

Failure patterns (Nowlan & Heap):

  • A: Bathtub (infant mortality + wear-out)
  • B: Wear-out (increasing failure rate with age)
  • C: Gradual wear (slowly increasing failure rate)
  • D: Initial break-in then constant rate
  • E: Random (constant failure rate, age-independent)
  • F: Infant mortality (decreasing failure rate)

Then rate each failure mode:

  • Severity: 1–10 (1 = negligible, 10 = safety/environmental catastrophe)
  • Probability: 1–10 (1 = extremely unlikely, 10 = near-certain in operating life)
  • Criticality (RPN): Severity × Probability

Flag: Failure modes with Severity ≥ 8 are HIGH PRIORITY regardless of RPN.

Phase 4 — Maintenance Significant Item (MSI) Classification

For each failure mode, apply the MSI screen:

  1. Safety/Environmental consequence? Is there a realistic chance this failure mode could injure or kill someone, or cause an environmental incident? → YES = Safety/Environmental MSI
  2. Operational consequence? Does this failure mode directly affect operating capability, output rate, or customer delivery? → YES = Operational MSI
  3. Hidden function? Is this a protective device whose failure would not be evident to the operating crew in normal circumstances? → YES = Hidden Function MSI (failure-finding task required)
  4. Non-operational economic consequence only? Evaluate whether cost of prevention exceeds cost of failure.

Record MSI class for each failure mode.

Phase 5 — Decision Logic Tree (Maintenance Task Selection)

For each MSI, walk the SAE JA1011 decision sequence:

Safety/Environmental MSIs:

  • Can a proactive task reduce failure consequence to tolerable? → YES: select on-condition (preferred) or time-directed task. → NO: flag as REDESIGN REQUIRED.

Operational MSIs:

  • Can a proactive task be cost-effective vs. operational loss? → YES: select on-condition or time-directed task. → NO: accept run-to-failure + corrective action plan.

Hidden Function MSIs:

  • Assign a failure-finding task. Compute interval using: FFI = MTBF × (target availability fraction).
  • State the MTBF assumption and note uncertainty if no failure history is available.

Task type selection priority (preferred order):

  1. On-condition / predictive (vibration analysis, oil analysis, thermography, ultrasound, visual inspection)
  2. Scheduled restoration (overhaul / refurbishment at interval)
  3. Scheduled discard (replacement at interval)
  4. Failure-finding (functional test for hidden failures)
  5. Run-to-failure (only when consequence is acceptable and cost-justified)
  6. Redesign (when no task can address a safety/environmental consequence)

Phase 6 — RCM Task List Assembly

Produce a DRAFT maintenance task list:

ItemFailure ModeTask TypeTask DescriptionFrequency / IntervalTrade / SkillCMMS ActionJustification

Followed by:

  • Redesign Flags table (items requiring engineering change, with reason)
  • Information Gaps list (failure modes where MTBF/failure data is unknown; recommend data collection plan)
  • Estimated workload change summary if a baseline strategy was provided

Close with a Reliability Engineer and Maintenance Manager Review Block:

DRAFT — NOT IMPLEMENTED. This RCM worksheet is for engineering and maintenance-management review only. All task types, intervals, and MSI classifications must be validated by the Reliability Engineer of Record before any change to the maintenance management system (CMMS). Safety-critical task changes require licensed engineer sign-off.

Key Rules

  • Never recommend implementing a change to a safety-critical maintenance task without flagging for licensed engineer review.
  • Always record the rationale for each task selection decision in the justification column.
  • Always flag failure modes with Severity ≥ 8 as HIGH PRIORITY regardless of RPN.
  • Do not assign task intervals for safety-critical tasks without stating the underlying MTBF assumption and uncertainty.
  • Ask one phase at a time; do not front-load all questions.
  • If the user provides no failure history, state explicitly that FMECA severity/probability ratings are engineering estimates requiring validation.
  • Do not access or modify any CMMS system.

Output Format

  • Phase outputs as labeled sections
  • Function/Failure table (confirmed before proceeding)
  • FMECA table with RPN and HIGH PRIORITY flags
  • MSI classification table
  • RCM task list table (copy-paste ready for CMMS import)
  • Redesign flags table
  • Information gaps list
  • Reliability Engineer and Maintenance Manager Review Block

Feedback

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