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Additive Manufacturing Jobs in Wheat Ridge, CO (NOW HIRING)

Experience with advanced manufacturing methods such as additive manufacturing, CNC machining, or automated production systems * Published technical work (journals, conferences, or significant ...

Hardware Associate

Denver, CO · On-site

$18 - $20/hr

... manufacturing capacity across 10 facilities, Fathom seamlessly blends in-house capabilities across plastic and metal additive technologies, CNC machining, injection molding & tooling, urethane ...

... manufacturing capacity across 10 facilities, Fathom seamlessly blends in-house capabilities across plastic and metal additive technologies, CNC machining, injection molding & tooling, urethane ...

CNC Machine Tool Sales

Littleton, CO · On-site

$20 - $27.50/hr

... additive manufacturing machines, saws, grinders and much more. * Salaried position transitioning to commission * Excellent benefits package - health, dental, vision effective day-1 of employment ...

Strong understanding of materials, tolerancing, and manufacturing processes (CNC, sheet metal, composites, additive manufacturing). * Familiarity with design for manufacturability principles and ...

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Additive Manufacturing information

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$14

$26

$36

How much do additive manufacturing jobs pay per hour?

As of Jul 14, 2026, the average hourly pay for additive manufacturing in Wheat Ridge, CO is $26.51, according to ZipRecruiter salary data. Most workers in this role earn between $21.44 and $30.67 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 cities near Wheat Ridge, CO are hiring for Additive Manufacturing jobs? Cities near Wheat Ridge, CO with the most Additive Manufacturing job openings:
Infographic showing various Additive Manufacturing job openings in Wheat Ridge, CO as of July 2026, with employment types broken down into 100% Full Time. Highlights an 100% In-person job distribution, with an average salary of $55,144 per year, or $26.5 per hour.
Director, Propulsion Engineering

Director, Propulsion Engineering

True Anomaly

Denver, CO

Other

Medical, Dental, Vision, Retirement, PTO

Re-posted 12 days ago


Job description

YOUR MISSION

As Director of Propulsion Engineering at True Anomaly, you will lead the strategy, development, and delivery of next-generation propulsion systems across our spacecraft and missile defense portfolio. You will own the technical vision for propulsion from early concepts through flight while coordinating the future of our propulsion testing strategy. You will also drive the adoption of advanced manufacturing methods, including metal additive manufacturing, to accelerate development timelines and unlock novel design solutions. This is a high-impact leadership role that sits at the intersection of deep propulsion expertise, rigorous test operations, and cutting-edge manufacturing innovation. 

RESPONSIBILITIES

Technical Leadership & Propulsion System Development 

  • Define and own the propulsion technology roadmap across True Anomaly's spacecraft and defense platforms, ensuring designs meet performance, reliability, cost, and schedule requirements. 
  • Drive system-level requirements development, decomposition, and traceability from vehicle-level requirements down to component and subsystem specifications. 
  • Drive make/buy analysis and cost/risk/performance trades for propulsion components including engines, valves, tanks, and fluid systems. 
  • Collaborate on the design, development, test and deployment of the fluid systems that are integral to our propulsion systems. 
  • Champion the integration of metal additive manufacturing (AM) methods into propulsion hardware development - evaluating AM applicability, qualifying printed components, and collaborating with manufacturing teams to mature AM processes for flight use. 
  • Ensure propulsion designs are robust and reliable across the space operating environment. 

Test Facility Oversight 

  • Provide strategic oversight of True Anomaly's propulsion testing efforts, ensuring safe, efficient, and effective execution of hot-fire, cold-flow, and pressure test campaigns. 
  • Own the test facility roadmap - identifying capability gaps, leading infrastructure investments, and scaling test operations to support our accelerating development efforts. 
  • Oversee the development of propellant loading capabilities, vehicle-level propulsion checkouts, and anomaly investigation and resolution during test campaigns. 
  • Drive a culture of test rigor and data-driven decision-making within the propulsion organization. 

Cross-Functional Collaboration 

  • Partner closely with structures, thermal, avionics, GNC, and systems engineering teams to ensure propulsion systems integrate seamlessly at the vehicle level. 
  • Serve as the primary propulsion point of contact in design reviews (SRR, PDR, CDR, TRR) and communicate propulsion status, risks, and recommendations clearly to program leadership and customers. 
  • Interface with government customers, external partners, and suppliers to define requirements, manage deliverables, and resolve technical issues. 
  • Present propulsion strategy, technical status, and test results to internal leadership and external stakeholders. 

Team Building & Management 

  • Build, lead, and scale a high-performing team of propulsion engineers with expertise spanning fluid systems, combustion, structural analysis, test operations, and advanced manufacturing. 
  • Develop and execute a staffing and organizational growth plan aligned with program timelines; partner with Talent Acquisition to attract top propulsion talent. 
  • Establish a strong engineering culture grounded in technical rigor, safety, accountability, and continuous improvement. 
  • Mentor senior engineers and define clear technical career paths within the propulsion organization. 
  • Define team processes, tools, and standards for design, documentation, analysis, and test. 

Program Execution 

  • Own propulsion deliverables against program schedules, budgets, and technical performance metrics. 
  • Proactively identify technical risks and drive mitigation strategies; communicate status and critical issues clearly to the VP of Space Vehicle Engineering and program leadership. 
  • Support spacecraft integration and test campaigns including I&T planning, anomaly investigation, and resolution.

QUALIFICATIONS

  • 15+ years of professional experience in spacecraft, launch vehicle, or advanced defense propulsion systems, with at least 5 years in a technical leadership or people management role. 
  • Demonstrated experience leading propulsion systems development across the full lifecycle - from concept and design through integration, test, and flight operations. 
  • Deep expertise in fluid system design and analysis including rocket engines, flight valves, propellant tanks and pressurization systems. 
  • Extensive propulsion test experience including hot-fire and pressure testing, vehicle-level propulsion checkouts, propellant loading, and test facility operations and safety management. 
  • Proven track record of building, scaling, and leading high-performing propulsion engineering teams. 
  • Excellent written and verbal communication skills, with demonstrated ability to present complex technical content to senior leadership and external customers. 
  • Passion for the space and defense industry and a drive to push the boundaries of what's possible. 

PREFERRED SKILLS AND EXPERIENCE

  • Hands-on experience with metal additive manufacturing for propulsion applications, including design for AM, process qualification, and flight certification of printed components. 
  • Experience with valve and/or propellant tank design, analysis, and manufacturing. 
  • Familiarity with or direct experience overseeing a propulsion test facility, including infrastructure planning and safety program management. 
  • Background in DoD space or missile defense propulsion programs. 
  • Experience scaling a propulsion or aerospace engineering organization during a high-growth or startup phase. 
  • Master's degree or PhD in Mechanical or Aerospace Engineering. 
  • Familiarity with relevant standards: MIL-STD, AIAA propulsion standards, NASA-STD, or equivalent. 
  • Active DoD security clearance (Secret or above), or the ability to obtain one. 

COMPENSATION

  • Base Salary: $190,000-$320,000
  • Equity + Benefits including Health, Dental, Vision, HRA/HSA options, PTO and paid holidays, 401K, Parental Leave 

Your actual level and base salary will be determined on a case-by-case basis and may vary based on the following considerations: job-related knowledge and skills, education, location, and experience. 

ADDITIONAL REQUIREMENTS

  • Ability to maintain or obtain TS//SCI clearance. 
  • Work Location-Primarily onsite at our GravityWorks factory in Centennial, CO, with regular travel (up to 20%) to our Long Beach, CA factory and vendor/test sites.
  • Work environment-the work environment; temperature, noise level, inside or outside, or other factors that will affect the person's working conditions while performing the job.
  • Physical demands-the physical demands of the job, including bending, sitting, lifting and driving.

This position will be open until it is successfully filled. To submit your application, please follow the directions below. #LI-OnsiteÂ