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Robotic Engineering Jobs in Wisconsin (NOW HIRING)

Robotic Weld Engineer

Hartford, WI · On-site

$19.75 - $27/hr

Robotic Welding Engineer Company: Standard Iron Reports To ... Engineering Manager Location: Hartford Wiscosnin (With occasional travel to other plants) You can ...

Robotic Welder

Oshkosh, WI · On-site

$20 - $25/hr

Do you excel at both hands-on welding and the technical challenge of robot programming and setup? If so,our Oshkosh clients needs YOU! Position - Robotic Welder Job Location - Oshkosh, WI Starting ...

Robotic Welder

Hartford, WI · On-site

$19.75 - $27/hr

This position bridges the gap between high-level engineering and daily production by providing expert robotic programming, immediate mechanical repair, and continuous troubleshooting for automated ...

Robotic Welder

Hartford, WI · On-site

$19.75 - $27/hr

This position bridges the gap between high-level engineering and daily production by providing expert robotic programming, immediate mechanical repair, and continuous troubleshooting for automated ...

Robotic Welder

Hartford, WI

$19.75 - $27/hr

A Robotic Welder is a skilled professional responsible for programming, operating, and maintaining robotic welding systems to join and fabricate metal components. The ideal candidate possesses ...

Robotic Welder

Hartford, WI · On-site

$19.75 - $27/hr

A Robotic Welder is a skilled professional responsible for programming, operating, and maintaining robotic welding systems to join and fabricate metal components. The ideal candidate possesses ...

Robotic Welder

Hartford, WI · On-site

$19.75 - $27/hr

A Robotic Welder is a skilled professional responsible for programming, operating, and maintaining robotic welding systems to join and fabricate metal components. The ideal candidate possesses ...

Robotic Welder

Mayville, WI · On-site

$18.75 - $25.75/hr

What you will be doing as a ROBOTIC WELDER: * Responsible for product quality, workmanship and process applications consistent with the company's manufacturing objectives. * Follows safety guidelines ...

Robot Tech

Mauston, WI · On-site

$20 - $30/hr

This position is responsible for supporting robotic paint systems, troubleshooting automation ... Engineering, Maintenance, and Manufacturing Operations • Team-Oriented Environment • ...

Robot Tech

Mauston, WI · On-site

$20 - $30/hr

This position is responsible for supporting robotic paint systems, troubleshooting automation ... Engineering, Maintenance, and Manufacturing Operations • Team-Oriented Environment • ...

Robotic Welder (1st Shift)

Mequon, WI · On-site

$15.75 - $21.75/hr

Utilize and interpret blueprints/engineering drawings for setup, welding, and inspection of parts ... Operate and program Fanuc robot with a Fronius Welding Power Supply * Perform routine Preventative ...

Robotic Welder I

Marinette, WI · On-site

$27.33 - $32.18/hr

Independently operate Robotic Welding Equipment. * Successfully utilize fixtures as required to ... We offer a wide range of capabilities in fabricating stock, custom & engineered-to-order vessel ...

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Showing results 1-20

Robotic Engineering information

See Wisconsin salary details

$15

$28

$45

How much do robotic engineering jobs pay per hour?

As of Jul 15, 2026, the average hourly pay for robotic engineering in Wisconsin is $28.51, according to ZipRecruiter salary data. Most workers in this role earn between $22.31 and $33.22 per hour, depending on experience, location, and employer.

What jobs do robotic engineers do?

Robotic engineers design, develop, and test robotic systems and automation solutions for various industries. They work with sensors, actuators, programming languages, and control systems to create robots that perform specific tasks, often collaborating with multidisciplinary teams and utilizing CAD software. Their roles may include research, system integration, troubleshooting, and maintenance of robotic equipment.

What is robotic engineering?

Robotic engineering is a branch of engineering that involves the design, construction, operation, and maintenance of robots. It combines principles from mechanical engineering, electrical engineering, computer science, and control systems to create machines that can perform tasks autonomously or with human guidance. Robotic engineers work on developing robots for various industries, including manufacturing, healthcare, space exploration, and more. The field is rapidly evolving as technology advances, offering exciting opportunities for innovation and problem-solving.

What engineers make $300,000 a year?

Senior robotic engineers, especially those with extensive experience, advanced degrees, and expertise in areas like AI, automation, or control systems, can earn $300,000 or more annually. High-level roles often require leadership skills, specialized certifications, and work in industries such as aerospace, defense, or advanced manufacturing.

What is the difference between Robotic Engineering vs Mechanical Engineering?

AspectRobotic EngineeringMechanical Engineering
Required CredentialsBachelor's in Robotics, Mechanical, or Electrical Engineering; certifications in roboticsBachelor's in Mechanical Engineering; Professional Engineer (PE) license often preferred
Work EnvironmentDesign labs, manufacturing plants, research facilitiesManufacturing, design studios, research labs
Industry UsageRobotics companies, automation firms, tech startupsAutomotive, aerospace, manufacturing, energy
Common Search/ComparisonRobotic Engineering vs Mechanical Engineering

Robotic Engineering focuses on designing, developing, and maintaining robots and automation systems, often requiring specialized knowledge in robotics and programming. Mechanical Engineering covers a broader range of mechanical systems, including machinery, thermal systems, and structural components. While both fields share foundational engineering principles, Robotic Engineering emphasizes automation and control systems, making it more specialized for robotics applications.

What are the typical collaboration dynamics between robotic engineers and other teams during a project?

Robotic engineers frequently collaborate with multidisciplinary teams, including software developers, electrical engineers, and mechanical designers. During a project, they often participate in cross-functional meetings to ensure that hardware, software, and control systems are seamlessly integrated. Effective communication and problem-solving are essential, as robotic engineers may need to translate complex technical requirements between teams or troubleshoot issues that arise during development and testing. This collaborative environment fosters innovation and helps streamline the creation of advanced robotic solutions.

What are the key skills and qualifications needed to thrive as a Robotic Engineer, and why are they important?

To thrive as a Robotic Engineer, you need a solid background in mechanical engineering, electronics, computer science, and mathematics, often supported by a bachelor’s or master’s degree in robotics or a related field. Familiarity with programming languages (such as C++, Python, or ROS), CAD software, and robotics simulation tools is typically required, along with certifications in robotics or automation. Strong problem-solving skills, creativity, teamwork, and effective communication are essential soft skills that set top professionals apart. These competencies ensure the successful design, implementation, and maintenance of complex robotic systems in diverse industries.

What engineers make $500,000?

Senior robotic engineers, especially those in leadership roles or with specialized expertise in areas like AI, automation, or aerospace, can earn $500,000 or more annually. High compensation often requires extensive experience, advanced degrees, and skills in programming, systems integration, and project management, typically in industries such as aerospace, defense, or high-tech manufacturing.

Do robotic engineers make good money?

Robotic engineers typically earn competitive salaries that vary based on experience, education, and location. According to industry data, the median annual wage for robotic engineers is higher than the average for engineering roles, with opportunities for advancement and specialization in areas like automation and control systems.
What are popular job titles related to Robotic Engineering jobs in Wisconsin? For Robotic Engineering jobs in Wisconsin, the most frequently searched job titles are:
What cities in Wisconsin are hiring for Robotic Engineering jobs? Cities in Wisconsin with the most Robotic Engineering job openings:
Robotic Weld Engineer

Robotic Weld Engineer

Standard Iron

Hartford, WI • On-site

$19.75 - $27/hr

Full-time

Posted 14 days ago


Standard Iron rating

7.4

Company rating: 7.4 out of 10

Based on 5 frontline employees who took The Breakroom Quiz


Job description

Job Opportunity: Robotic Welding Engineer
Company: Standard Iron
Reports To: Engineering Manager
Location: Hartford Wiscosnin (With occasional travel to other plants)
You can streamline the interview process by completing this form> https://go.cultureindex.com/p/24598463d6af6e7cc955
Company Overview
At Standard Iron, we provide top-tier contract manufacturing and fabrication solutions. We pride ourselves on safety, quality, and production efficiency. We are looking for an experienced Robotic Welding Engineer to drive our automated production systems forward.
Position Summary
The Robotic Welding Engineer bridges the gap between weld metallurgy, advanced robotics programming, and production floor efficiency. You will design, develop, integrate, and optimize automated and robotic welding systems. This role leads process improvement initiatives, troubleshoots complex cells, collaborates on fixture design, and ensures compliance with strict AWS quality standards.
Key Responsibilities
Robotic Programming & Optimization
  • Program Systems: Program and clone paths for multi-axis systems (primarily ABB) using teach pendants and Offline Programming (OLP) software.
  • Tune Parameters: Adjust arc parameters, travel angles, travel speeds, voltage, and wire feed speeds to ensure structural integrity and reduce cycle times.
  • Calibrate Sensors: Implement and calibrate Thru-Arc Seam Tracking (TAST), touch sensing, and laser/vision guidance systems.

Tooling, Fixture & Cell Design Review
  • Review Fixtures: Partner with Tooling Engineers to review fixture designs for part repeatability and torch joint access.
  • Specify Equipment: Define technical specs for new robotic arms, power sources, positioners, reamers, and safety enclosures.
  • Manage Integration: Lead commissioning of new robotic weld cells from initial design through production launch.

Quality Control & Troubleshooting
  • Solve Defects: Diagnose mechanical, electrical, and programming faults to resolve issues like porosity, undercut, and lack of fusion.
  • Maintain Calibration: Manage Tool Center Point (TCP) standards and develop recovery protocols to minimize downtime.
  • Ensure Compliance: Execute weld macro-examinations to guarantee alignment with AWS D1.1, D1.3, or customer-specific standards.

Continuous Improvement & Safety
  • Boost Efficiency: Analyze production data to reduce "air-cut" time and improve Overall Equipment Effectiveness (OEE).
  • Champion Safety: Ensure cell compliance with OSHA and RIA/ANSI R15.06 guidelines (light curtains, interlocking gates).
  • Train Staff: Mentor robot operators, technicians, and maintenance staff on basic troubleshooting and safety.

Job Qualifications
Education & Experience
  • Degree: Bachelor's degree in Welding, Mechanical, or Automation/Robotics Engineering is preferred. An Associate degree with equivalent hands-on industrial experience will be considered.
  • Experience: 3-5+ years of direct experience engineering robotic welding applications in heavy manufacturing, automotive, or structural steel fabrication.

Technical Skills
  • Robotics: Proficient in programming major robotic platforms (primarily ABB). Experience with simulation software like RobotStudio or RoboGuide is highly preferred.
  • Welding Expertise: Deep understanding of GMAW (MIG), FCAW, or GTAW (TIG) processes and parameter development.
  • CAD & Prints: Ability to read engineering drawings and utilize CAD software (SolidWorks, AutoCAD, CREO) to review part geometry.
  • Upstream Focus: Knowledge of how laser cutting, stamping, and sheet metal rolling impact part fit-up and automated weld success.

Success Metrics (KPIs)
  • First-Time Through (FTT) Yield: Reduction in post-weld manual rework and repair rates.
  • Cycle Time Reduction: Percentage decrease in cell cycle times through optimized tool paths.
  • Equipment Downtime: Minimizing cell downtime caused by programming errors or fixture tracking alignment issues.

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