Activity 001: Precision Measurement Skills Lab¶

Activity ID: U8M4-ACT-001 Duration: 40 minutes Objective: Read micrometers and calipers accurately, measure machined parts, and compare results to drawing specifications.

Overview¶

Students practice reading and using precision measuring instruments on a set of machined sample parts. They record measurements, calculate deviations from nominal, and determine whether parts are within tolerance.

Materials & Equipment Needed¶

Outside micrometer set (0-1", 1-2")
Digital calipers (6")
Depth micrometer or depth gauge
Set of machined sample parts (5 parts with known dimensions and intentional tolerance variations)
Gauge block set (for micrometer zero check)
Part drawings with dimensions and tolerances
Measurement recording worksheet
Lint-free cloth for cleaning instruments
Safety glasses

Instructions & Procedure¶

Phase 1: Instrument Familiarization and Zero Check (8 minutes)¶

Micrometer zero check: Close the micrometer gently using the ratchet stop. The reading should be exactly 0.000". If not, adjust using the zero-setting procedure (spanner wrench on the sleeve).
Gauge block verification: Select a 0.500" gauge block. Measure it with the micrometer. Record the reading. It should read 0.5000" ±0.0001".
Caliper zero check: Close the caliper jaws fully. Press the zero button. Verify the display reads 0.000".
Practice readings: The instructor calls out micrometer settings. Students set the micrometer to each dimension and verify against each other's readings.

Phase 2: Part Measurement (20 minutes)¶

For each of the 5 sample parts: 1. Read the part drawing. Identify all dimensioned features and their tolerances. 2. Measure each dimension using the appropriate instrument: - External diameters: outside micrometer - Lengths and widths: calipers for quick check, micrometer for critical dimensions - Depths: depth micrometer or depth gauge 3. Record each measurement on the worksheet. 4. Calculate the deviation from nominal: Measurement - Nominal = Deviation. 5. Determine Go/No-Go: Is the measurement within the stated tolerance? 6. Measure each critical dimension twice to verify repeatability.

Phase 3: Part Acceptance/Rejection (8 minutes)¶

For each part, complete the acceptance criteria:
All dimensions within tolerance → ACCEPT
Any dimension outside tolerance → REJECT (note which dimension failed)
Identify which rejected parts could be reworked (oversized parts can be re-machined; undersized parts are scrap).
Complete the inspection report for all 5 parts.

Phase 4: Discussion (4 minutes)¶

Compare your measurements with other students. How much variation exists between different operators?
Which instrument did you find easiest/hardest to use consistently?
Which parts were borderline (very close to the tolerance limit)?

Discussion Points¶

Why is measuring technique important for consistency between operators?
What is the cost of accepting an out-of-tolerance part?
How does the ratchet stop improve measurement consistency?
When would you use a micrometer vs. a caliper?

Expected Outcomes¶

Students read a micrometer correctly to 0.001" (with vernier to 0.0001")
Students read digital calipers correctly
Students make consistent measurements (±0.001" between repeated readings)
Students correctly accept/reject parts based on tolerance analysis

Assessment Rubric¶

Criteria	Excellent (4)	Proficient (3)	Developing (2)	Beginning (1)
Micrometer Reading	All readings within ±0.0005" of known values	Within ±0.001"	Within ±0.002"	Cannot read micrometer
Caliper Reading	All readings within ±0.001"	Within ±0.002"	Within ±0.005"	Cannot read calipers
Tolerance Analysis	All accept/reject decisions correct	1 error	2-3 errors	Cannot determine acceptance
Instrument Care	Proper handling, zeroed, clean	Minor lapse in care	Left instrument unsecured	Rough handling

Safety Considerations¶

Handle precision instruments with clean, dry hands
Never drop or impact measuring instruments
Do not leave instruments on the machine tool surface where they can fall
Safety glasses required in the shop area even for measurement activities
Gauge blocks have extremely sharp edges—handle carefully

Last Updated: 2026-03-19