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  1. Programs
  3. Industrial Hygiene

Industrial Hygiene

Montana Technological University

Master's Degree

Become a contributor for free to openly demonstrate student outcomes, industry alignment & eligibility criteria.

No description available.

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Program Pathways

Credentials this program stacks toward

No program pathways.

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Program Details

Detailed information about this program

No detailed information available.

Requirements

What you need to earn this credential

No requirements listed.

Financial Aid

Eligible funding programs

No funding information available.

Scholarships

No scholarships listed.

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Locations

Where this program is offered

  • Butte, Montana

    1300 W Park St, Butte, Montana, 59701-8997

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Related Programs

Programs related to this one

No related programs.

Skills & Competencies

Skills developed through this program

Auto-populated·from O*NET via SOC 17-3026.00

Skills

Reading ComprehensionCritical ThinkingActive ListeningComplex Problem SolvingMonitoringSpeakingSystems AnalysisSystems Evaluation

Knowledge

MechanicalEngineering and TechnologyProduction and ProcessingMathematicsDesign

Abilities

Oral ComprehensionProblem SensitivityDeductive ReasoningInductive ReasoningWritten ComprehensionNear VisionOral ExpressionInformation OrderingCategory FlexibilityWritten Expression

Tasks

  • Test selected products at specified stages in the production process for performance characteristics
  • Compile and evaluate statistical data to determine and maintain quality and reliability of products.
  • Study time, motion, methods, or speed involved in maintenance, production, or other operations to es

Technology

Materials requirements planning logistics and supply chain softwareAnalytical or scientific softwareIndustrial control softwareComputer aided design CAD softwareDevelopment environment software

Tools

3-axis computer numerically controlled CNC milling machinesAdjustable hand wrenchesAir conditioning unitsAir heatersAir purifying respiratorsAngle platesAutocollimatorsAutomated vision systemsAutomatic microhardness testersBand sawsBelt conveyorsBench grindersBioreactorsBlow molding machinesBoring tools

Work Values

SupportAchievementIndependenceWorking ConditionsRecognitionRelationships
Career Pathways

Occupations this program prepares you for

Auto-populated·from O*NET + BLS
Occupations matched to this program, with median wage, top wage, growth, and openings
SOCOccupationMethodWageGrowthOpenings
Match confidence: medium17-3026.00Industrial Engineering Technologists and Technicianstitle_inference$64,790 median$97,670 top+1.74%130
What You'll Learn

Key competencies developed through this program

Auto-populated·from NSX Competency Framework

Mastery: advanced (Level 4)(based on Master's Degree)

  • Organization-wide quality and reliability strategy — develop and champion by synthesizing production data, industry standards, and engineering best practices across a multi-line manufacturing enterprise.
  • Industrial engineering technician teams — lead and mentor, setting performance expectations, structuring development plans, and cultivating a culture of precision and continuous improvement.
  • Enterprise-level efficiency initiatives — direct by applying systems evaluation methods to identify systemic waste, redesign workflows, and quantify productivity gains across facilities.
  • Capital investment decisions for production technology — inform by authoring rigorous feasibility analyses that integrate CAD/CAM capabilities, equipment ROI, and process compatibility data.
  • Standardized work measurement and quality assurance frameworks — author and implement at organizational scale, ensuring consistency across departments, shifts, and plant locations.
  • Production planning governance — establish by designing capacity allocation models and scheduling policies that align engineering capacity with long-range business objectives.
  • Cross-departmental quality non-conformance patterns — investigate at root-cause level and drive corrective action programs that integrate operations, engineering, and supply chain stakeholders.
  • Emerging analytical and industrial control technologies — evaluate, pilot, and integrate into existing production ecosystems, translating technology design concepts into operational advantage.
  • Technical documentation and quality reporting standards — define for the organization, ensuring written outputs meet regulatory, customer, and internal audit requirements.
  • Organizational learning in industrial engineering practice — foster by designing training curricula, leading knowledge-transfer sessions, and institutionalizing lessons learned from production improvements.

Some details on this page are auto-populated from public workforce data sources: O*NET (opens in new tab), BLS (opens in new tab), College Scorecard (opens in new tab), DOL Training Provider Results (opens in new tab), NSX (opens in new tab). Provided in partnership with LER.me Career Intelligence.

Student Outcomes

Performance metrics for this program

Auto-populated·from Scorecard + DOL
Completion Rate
30%
Placement Rate
100%