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Additive Manufacturing Jobs in Minnesota (NOW HIRING)

Product Manager - Additive Manufacturing Position Summary The Product Manager supports the development, launch, and lifecycle management of additive manufacturing products and materials. This role ...

Our capabilities span the world of Additive Manufacturing/3D printing and the entirety of the manufacturing process from design ideation to product engineering to manufacturing and services in the ...

Aerosol Jet Solutions Architect

Saint Paul, MN · On-site

$62.50 - $82.50/hr

Description Optomec is seeking a customer-focused Aerosol Jet (AJ) Solutions Architect to support revenue growth and expand adoption of our advanced additive manufacturing technology. This role works ...

Develop and optimize laser material processes including welding, cutting, drilling, additive manufacturing, and marking applications * Conduct R&D activities to improve laser processing capabilities ...

Stratasys is leading the global shift to additive manufacturing with innovative 3D printing solutions for industries such as aerospace, automotive, consumer products and healthcare. Through smart and ...

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Additive Manufacturing information

See Minnesota salary details

$13

$24

$33

How much do additive manufacturing jobs pay per hour?

As of Jul 13, 2026, the average hourly pay for additive manufacturing in Minnesota is $24.43, according to ZipRecruiter salary data. Most workers in this role earn between $19.76 and $28.27 per hour, depending on experience, location, and employer.

What is the difference between Additive Manufacturing vs CNC Machinist?

AspectAdditive ManufacturingCNC Machinist
CredentialsTypically requires technical training or certification in 3D printing technologiesRequires machining certifications or technical training in CNC operations
Work EnvironmentWorks in labs or manufacturing facilities with 3D printers and related equipmentWorks in machine shops or manufacturing plants operating CNC machines
Industry UsageUsed in prototyping, custom parts, and complex geometriesUsed for precision manufacturing of metal and plastic parts
Search & Comparison IntentOften compared for manufacturing processes involving digital fabricationCompared for traditional subtractive manufacturing skills

While both roles are involved in manufacturing, Additive Manufacturing focuses on building parts layer-by-layer using 3D printing technologies, whereas CNC Machinists operate subtractive machines to carve parts from raw materials. Understanding these differences helps in choosing the right career path or job search focus within the manufacturing industry.

What skills do you need for additive manufacturing?

Additive manufacturing professionals need strong technical skills in CAD software, 3D modeling, and familiarity with various 3D printing technologies such as FDM, SLA, or SLS. Knowledge of materials science, precision measurement, and post-processing techniques is also important, along with problem-solving abilities and attention to detail. Certifications in additive manufacturing or related fields can enhance job prospects.

Is additive manufacturing a good career?

Additive manufacturing is a growing field that involves designing and operating 3D printing equipment, often requiring skills in engineering, materials science, and computer-aided design. Careers in this area can offer opportunities in industries such as aerospace, healthcare, and automotive, with roles typically requiring technical training or certifications. The industry is expected to expand as technology advances, making it a viable career choice for those interested in innovative manufacturing processes.

How much do additive manufacturing technicians make?

Additive manufacturing technicians typically earn a median annual salary of around $50,000 to $60,000, depending on experience, location, and certifications. Skilled technicians familiar with 3D printing technologies and CAD software may earn higher wages, especially in advanced manufacturing environments.

What Is Additive Manufacturing?

Additive manufacturing (AM) is the process of creating products by adding material using one or more techniques. This is the opposite of subtractive manufacturing, which produces products by removing material. Many products are produced using a combination of these two techniques. To manufacture a plastic shape, you may use additive manufacturing to layer plastic materials then use subtractive manufacturing to cut and shape the plastic. In recent years, AM has started to focus on advanced techniques like 3D printing, where complex products are created layer by layer, using one or more materials. The main job in AM is that of an additive manufacturing engineer, although rapid prototyping may utilize this process to create a small model of a potential product.

What is additive manufacturing?

Additive manufacturing, often referred to as 3D printing, is a process of creating objects by adding material layer by layer, based on a digital model. Unlike traditional manufacturing methods that remove material from a solid block, additive manufacturing builds products directly from raw materials such as plastics, metals, or composites. This technology enables complex designs, rapid prototyping, and customization that would be difficult or impossible with conventional manufacturing processes.

What are the key skills and qualifications needed to thrive in Additive Manufacturing, and why are they important?

To excel in Additive Manufacturing, a solid understanding of engineering principles, 3D modeling, and materials science is typically required, often supported by a degree in engineering or a related field. Familiarity with CAD software, 3D printers, and quality assurance systems, as well as certifications like SME Additive Manufacturing Certification, is highly beneficial. Strong problem-solving, attention to detail, and effective communication skills help professionals innovate and collaborate in dynamic production environments. These competencies are essential for ensuring precision, efficiency, and the successful implementation of advanced manufacturing technologies.

What are some typical challenges faced in an Additive Manufacturing role, and how can they be addressed?

Professionals in Additive Manufacturing often encounter challenges such as ensuring part quality, optimizing print parameters, and troubleshooting equipment malfunctions. Working closely with engineering teams and using advanced simulation software can help address issues related to design for additive processes. Regular calibration of machinery and staying updated on the latest material advancements are also key strategies for overcoming common hurdles. Collaboration and ongoing training play a significant role in maintaining production efficiency and quality standards.

What are the highest paying jobs in manufacturing?

In additive manufacturing, high-paying roles include additive manufacturing engineers, senior process engineers, and manufacturing managers, often requiring specialized skills in 3D printing technologies, CAD software, and quality control. These positions typically offer higher salaries due to technical expertise, experience, and leadership responsibilities within advanced manufacturing environments.
What are the most commonly searched types of Additive Manufacturing jobs in Minnesota? The most popular types of Additive Manufacturing jobs in Minnesota are:
What cities in Minnesota are hiring for Additive Manufacturing jobs? Cities in Minnesota with the most Additive Manufacturing job openings:
Sr. Manufacturing Engineer - Additive

Sr. Manufacturing Engineer - Additive

rms Company

Coon Rapids, MN • On-site

$100K - $140K/yr

Full-time

Medical, Dental, Vision, Life, Retirement, PTO

Re-posted 24 days ago


Job description

Overview
About rms Company
rms is a state of the art facility with the latest technology in precision machines to produce components for the medical device and aerospace industries. Our Manufacturing Engineers provide engineering support to rms teams with particular emphasis on developing capable manufacturing processes, implementing cellular manufacturing techniques and certifying processes to provide superior products to our customers.
Position Summary
We are seeking a highly motivated and technically accomplished Senior Additive Manufacturing Engineer to lead the development, industrialization, and optimization of advanced metal additive manufacturing technologies for medical device applications. This role combines responsibilities across R&D, process development, project engineering, and manufacturing engineering to support the full product lifecycle from concept through commercialization.
The ideal candidate will possess deep expertise in metal additive manufacturing, orthopedic implant development, materials engineering, and scalable production systems. This individual will interface cross-functionally with customers, operations, quality, regulatory, facilities, manufacturing, and executive leadership to translate innovative concepts into validated, manufacturable medical products.
This position requires strong technical leadership, project management capability, and hands-on engineering experience within regulated medical device manufacturing environments.
Responsibilities
Essential Job Functions
  • Lead development and implementation of advanced metal additive manufacturing processes for orthopedic and medical device applications.
  • Design, validate, and optimize production-ready AM workflows including build strategy, support design, post-processing, inspection, and quality controls.
  • Develop Design for Additive Manufacturing (DFAM) strategies for complex implant geometries and lattice structures.
  • Establish and improve additive manufacturing capabilities including equipment selection, lab setup, process validation, and manufacturing scale-up.
  • Support material characterization activities including mechanical testing, microstructural analysis, chemistry analysis, and process capability studies.
  • Drive continuous improvement initiatives focused on throughput, quality, scrap reduction, cycle time, and manufacturability.
  • Lead cross-functional engineering projects from concept through commercialization.
  • Develop and execute engineering studies, validation protocols, and testing plans in compliance with FDA, ISO 13485 and internal quality requirements.
  • Translate R&D concepts into manufacturable and scalable production solutions.
  • Participate in customer-facing technical discussions, DFM reviews, and project milestone meetings.
  • Understand and comply with the Cretex professional competencies, company policies, and the employee manual
  • Collaborate with Quality Engineering to develop validated and capable manufacturing processes.
  • Support root cause investigations, CAPA activities, and non-conformance resolution.
  • Ensure appropriate documentation practices for protocols, work instructions, validation reports, and engineering records.
  • Adhere to all safety policies; including wearing personal protective equipment when required
  • Support and comply with the company's QMS (Quality Management System), ISO 9001 and 13485 standards, GMP's (Good Manufacturing Practices), and GDP's (Good Documentation Practi

Qualifications
Minimum Requirements, Education & Experience (incl. KSA's and certifications)
  • Bachelor's degree in Mechanical Engineering, Biomedical Engineering, Materials Science, Metallurgical Engineering, Manufacturing Engineering, or related field. Advanced degree preferred.
  • 7+ years of engineering experience in additive manufacturing and medical device manufacturing environments.
  • Strong, hands-on experience with metal additive manufacturing technologies including L-PBF and EB-PBF powder bed fusion systems.
  • Experience developing manufacturing processes for orthopedic implants or regulated medical devices.
  • Strong understanding of AM materials, microstructures, and production workflows.
  • Experience with process validation, manufacturing scale-up, and production support.
  • Knowledge of ASTM standards related to additive manufacturing and implant materials including ASTM F3001 preferred.
  • Proficiency with CAD software such as SolidWorks, Creo, NX, or equivalent.
  • Proficiency with Additive Manufacturing software such as 3DXpert or Materialise MAGICS.

Desirable Criteria & Qualifications
  • Experience building or expanding additive manufacturing capabilities from the ground up.
  • Knowledge of machining processes (AM Machines, CNC, inspection methods, and properties of materials)
  • Experience with root cause analysis, Lean Manufacturing, and continuous improvement methodologies.
  • Experience developing FDA-cleared lattice or porous implant structures.
  • Experience with ISO 17025 laboratory systems and materials testing methodologies.
  • Familiarity with automation, digital manufacturing, and advanced inspection systems.
  • Experience interfacing with surgeons, regulatory agencies, and external customers.
  • Experience transitioning R&D technologies into full-scale production environments.
  • Experience with Colibrium Spectra M Equipment.
  • Proven ability to translate R&D innovation into scalable, manufacturable medical products.

rms Company Benefits
As a Cretex Medical company, rms offers a full benefit package to its employees. Benefits include medical, dental, vision and life insurance options. rms also offers a 401(k) retirement plan with employer match, profit sharing, short- and long-term disability insurance, paid time off, holiday pay, and an onsite medical clinic.
rms Company also offers company specific benefits, such as:
  • Onsite Clinic
  • Paid Parental Leave
  • Monthly Social Events
  • Annual Employee Appreciation Week
  • Volunteer Opportunities
  • Training and Development Opportunities
  • Tuition Reimbursement
  • Wellness Program

Cretex Companies use cutting oils, solvents, and other chemicals in the manufacturing process. Testing is conducted on a periodic basis to ensure that all chemicals are kept well below the OSHA permissible exposure levels.
#LI-JW1
Pay Range
USD $100,000.00 - USD $140,000.00 /Yr.
Company Benefits
All Employees:
Our 401k retirement savings plan with a company match contribution; onsite health clinics, discretionary holiday bonus program (based on years of service), Cretex University, 24/7 employee assistance program with access to five confidential visits with a licensed counselor at no cost, wellness program with incentives, an employee death benefit, and employee sick and safe leave are available to all Cretex employees.
20+hours:
Cretex's medical benefit package includes: comprehensive medical insurance with access to virtual providers; dental insurance (Little Partners Dental benefit covers services 100 percent for children 12 and younger when seen by a Health Partners in network provider); vision insurance; a pre-tax health savings account, healthcare and dependent care pre-tax reimbursement accounts; paid holidays, paid time off; and our discretionary profit sharing program are available to employees working 20+ hours/week.
30+ hours:
Parental Leave, accident and critical illness benefits, optional employee, spouse, and child life; short and long term disability; company provided life insurance; and tuition assistance programs are available to employees working 30+ hours per week.
(Some benefits are subject to eligibility criteria.)
Applicants will receive consideration for employment regardless of their race, color, creed, religion, national origin, sex, sexual orientation, gender identity, disability, age, veteran status, marital status, family status, status with regard to public assistance, or any other protected status as required by law.
Our company uses E-Verify to confirm the employment and eligibility of all newly hired employees. To learn more about E-Verify, including your rights and responsibilities, please visit www.dhs.gov/E-Verify.