1

Trainee Graduate Structural Engineer Jobs in Colorado

Civil Engineer

Greeley, CO · On-site

$2.9K - $5.8K/mo

There are no uniforms, no drilling, and no service obligation until after you graduate. Simply work ... structural engineering, transportation engineering and community planning. You'll quickly find ...

Civil Engineer

Colorado Springs, CO · On-site

$2.9K - $5.8K/mo

There are no uniforms, no drilling, and no service obligation until after you graduate. Simply work ... structural engineering, transportation engineering and community planning. You'll quickly find ...

Civil Engineer

Denver, CO · On-site

$2.9K - $5.8K/mo

There are no uniforms, no drilling, and no service obligation until after you graduate. Simply work ... structural engineering, transportation engineering and community planning. You'll quickly find ...

Civil Engineer

Thornton, CO · On-site

$2.9K - $5.8K/mo

There are no uniforms, no drilling, and no service obligation until after you graduate. Simply work ... structural engineering, transportation engineering and community planning. You'll quickly find ...

Civil Engineer

Fort Collins, CO · On-site

$2.9K - $5.8K/mo

There are no uniforms, no drilling, and no service obligation until after you graduate. Simply work ... structural engineering, transportation engineering and community planning. You'll quickly find ...

Civil Engineer

Aurora, CO · On-site

$2.9K - $5.8K/mo

There are no uniforms, no drilling, and no service obligation until after you graduate. Simply work ... structural engineering, transportation engineering and community planning. You'll quickly find ...

Sr. Mechanical Engineer

Longmont, CO · On-site

$125K - $175K/yr

... structural integrity. The Mechanical Engineer will collaborate with RF Engineering and ... Each post-graduate degree may substitute 2 years of experience requirement. * SolidWorks, Creo, or ...

next page

Showing results 1-20

Trainee Graduate Structural Engineer information

What types of projects can a Trainee Graduate Structural Engineer expect to work on during their first year?

As a Trainee Graduate Structural Engineer, you’ll typically be involved in a diverse range of projects, from assisting with the design of residential and commercial buildings to supporting infrastructure developments like bridges or public facilities. Early in your career, you’ll likely focus on tasks such as preparing technical drawings, conducting site visits under supervision, and performing calculations using industry-standard software. This exposure helps you understand different construction methods, materials, and regulatory requirements while collaborating closely with experienced engineers, architects, and construction teams.

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

To thrive as a Trainee Graduate Structural Engineer, you need a degree in civil or structural engineering and a solid understanding of structural analysis and design principles. Familiarity with industry-standard software such as AutoCAD, Revit, and structural analysis tools, along with knowledge of relevant codes and standards, is typically required. Strong problem-solving abilities, attention to detail, teamwork, and clear communication skills make candidates stand out. These competencies are crucial for delivering safe, effective engineering solutions and collaborating efficiently on complex construction projects.

What does a Trainee Graduate Structural Engineer do?

A Trainee Graduate Structural Engineer assists in designing, analyzing, and assessing building structures to ensure they are safe, stable, and meet regulatory standards. They typically work under the supervision of experienced engineers, helping to create technical drawings, perform calculations, and visit construction sites. Their day-to-day tasks often include using software for modeling structures, preparing reports, and collaborating with architects and other professionals. This role is designed to provide practical experience and training for recent graduates pursuing a career in structural engineering.

What is the difference between Trainee Graduate Structural Engineer vs Graduate Civil Engineer?

AspectTrainee Graduate Structural EngineerGraduate Civil Engineer
QualificationsTypically a Bachelor's or Master's in Structural or Civil EngineeringUsually a Bachelor's or Master's in Civil Engineering
Work EnvironmentDesign firms, consulting engineering offices, construction sitesConstruction sites, design firms, infrastructure projects
CertificationsMay pursue Chartered Engineer status (CEng)Likewise, may pursue CEng or similar certifications
Job FocusStructural design, analysis, and safety assessmentsBroader civil engineering tasks including transportation, water, and structural work

The main difference is that a Trainee Graduate Structural Engineer specializes in structural design and analysis, while a Graduate Civil Engineer has a broader focus on various civil engineering disciplines. Both roles often require similar educational backgrounds and certifications, but their work environments and project types differ slightly.

What are the most commonly searched types of Graduate Structural Engineer jobs in Colorado? The most popular types of Graduate Structural Engineer jobs in Colorado are:
What are popular job titles related to Trainee Graduate Structural Engineer jobs in Colorado? For Trainee Graduate Structural Engineer jobs in Colorado, the most frequently searched job titles are:
What job categories do people searching Trainee Graduate Structural Engineer jobs in Colorado look for? The top searched job categories for Trainee Graduate Structural Engineer jobs in Colorado are:

Senior Blade Structure Engineer

Envision Energy

Boulder, CO • On-site

$115K - $150K/yr

Other

Posted 14 days ago


Job description

Job Openings >> Senior Blade Structure Engineer
Senior Blade Structure Engineer
Summary
Title: Senior Blade Structure Engineer ID: 1050 Location: Boulder, CO Salary Range: $115,000.00 - $150,000.00
More about this job >
Description
Senior Blade Structure Engineer | Global Blade Innovation Center 
About the Global Blade Innovation Center
Envision Energy's Global Blade Innovation Center (GBIC) was established in 2015 to build a world-class,
in-house blade design capability. Engineers from industry-leading OEMs, national
laboratories, and top graduate programs have collaborated to create a state-of-the-art design
capability from the ground up. Envision's in-house blade designs and technologies have disrupted
global markets and delivered significant reductions in Levelized Cost of Energy (LCOE) alongside
measurable expansion of Envision's market share.
The Role
As a Senior Blade Structure Engineer, you will operate across the full span of composite blade
engineering: from hands-on field failure investigation through to the development of next-generation
design technologies and product-level solutions. You will own the most technically complex
challenges the business unit faces, with a mandate not only to diagnose and close field problems,
but to translate that physical understanding into better designs, improved materials application, and
new engineering capabilities that advance the product. You will serve as a key technical voice on
the team's hardest problems and bring the cross-functional influence to drive solutions across
design, production, and operations.
To be successful in this role you will be expected to bring the judgment to frame the right problem,
the physical intuition built through hands-on field investigation, and the cross-functional influence
required to turn technical insight into business action.
Key Responsibilities:
Composite Structural Design & Technology Development

Lead development of composite design technologies and methodologies that advance blade
structural performance, durability, and manufacturability, from concept through validation
and production integration.
Develop and apply multi-fidelity engineering tools and models to evaluate, optimize, and
improve blade structural designs at both component and product level.
Characterize and apply composite material behavior, including damage progression, fatigue
response, and failure mechanisms, to drive design improvements informed by physical
evidence.
Identify product-level structural challenges and lead engineering solutions that address root
causes, not just symptoms, spanning laminate design, joint architecture, sandwich
construction, and manufacturing methods.
Collaborate with aerodynamics, loads, controls, and manufacturing disciplines to ensure
structural designs are integrated, producible, and field proven.
Field Investigation & Root Cause Analysis
Lead hands-on assessment of damaged and failed composite wind turbine blades in factory
and field environments. This is a core, non-delegable part of the role.
Own root cause analysis for the business unit's most challenging structural failure modes,
with current priority on root joint structural fatigue; sandwich composite damage
mechanisms including core cracking and laminate-core interface delamination; and
manufacturing defect characterization and prediction.
Define and implement corrective and preventive solutions that close the loop between field
findings and upstream design, including repair methodologies, design changes, material
substitutions, and process improvements.
Work with blade material and testing teams to validate engineering models and design
assumptions against physical evidence from field and factory.
Communicate findings and recommendations with clarity to engineering, production, and
operations stakeholders.
AI-Augmented Engineering
Apply AI and data-driven tools to accelerate structural assessment, defect pattern
recognition, and failure analysis of workflows.
Leverage available AI tools to improve the efficiency and consistency of RCA
documentation, reporting, and corrective action tracking.
Maintain engineering rigor in evaluating AI-assisted outputs. Physical understanding of
composite behavior governs not model output alone.
Qualifications Required:
MS or PhD in Aerospace, Mechanical, Civil Engineering, or a closely related discipline.
5+ years of professional engineering experience in wind energy, aerospace, or a closely
related structural composites industry.
Deep knowledge of composite design, damage mechanics, and manufacturing methods,
including sandwich composite structures, adhesive joints, and bolted connections.
Expertise in FEA/FEM modeling and analysis experience (ANSYS, ABAQUS, or similar) in
shells and solids covering composites to tooling interfaces and damage modeling.
Demonstrated track record of leading root cause analysis for complex composite structural
failures and driving corrective and preventive solutions through implementation.
Proven ability to work effectively across organizational boundaries (production, operations,
and engineering) without direct authority.
Strongly Valued
Hands-on experience leading or strongly supporting blade manufacturing, prototyping, or
serial production on a specific project.
Background in novel concept development: ideation, engineering, prototyping, testing, and
production integration.
Experience developing or applying data-driven / AI tools in a structural engineering context
(e.g., defect classification, anomaly detection, fatigue life prediction).
Proficiency in Python, MATLAB, or similar scripting, data processing, automation of
analyses.
Background in novel composite repair methodology development, including validation
testing and production integration.
What We're Looking For
The ideal candidate moves fluidly between the field and the design office and sees them as the
same problem viewed from different angles. You build physical intuition from hands-on failure
investigation, and you apply that intuition to develop design technologies and product solutions that
make the next blade better than the last. You are intellectually restless about failure: you want to
understand why something failed and use that understanding to advance the product, not just
document the incident. You have the persistence and cross-functional credibility to drive solutions
from first principles all the way through to implementing design and field-validated results.
Strong interpersonal, collaboration, and communication skills are essential. Envision's culture is
entrepreneurial and fast-moving; a minds-on/hands-on approach is expected. Desire and ability to
work effectively across cultural boundaries and international time zones is critical.
Work Arrangement & Travel
Work arrangement: Hybrid
Travel: Up to 15% international travel, including field site visits and collaboration with global
GBIC teams.
Apply Now
 
Refer to a Friend
Copyright 2026 Envision Energy. All rights reserved.
Powered by ApplicantStack Hiring Software
Privacy Policy | Terms of Use