A prominent manufacturing and engineering facility located in southeastern Wisconsin specializes in the design, development, and production of advanced solutions for the aerospace and defense industries. This facility contributes significantly to the region’s manufacturing base and supports the broader aerospace ecosystem.
The site plays a crucial role in supplying critical components and systems to global aerospace clients. The operations benefit from the region’s skilled workforce, established infrastructure, and proximity to other key industry players, fostering innovation and efficient production processes. Its history reflects a commitment to technological advancement and delivering high-quality products for demanding applications.
The following sections will delve into the specific capabilities, product lines, and the impact this particular location has on the aerospace sector, alongside discussions about its employment opportunities and future growth trajectory.
The following insights offer guidance for individuals seeking engagement with the aerospace facility located in New Berlin, Wisconsin. These tips emphasize preparation, understanding the industry, and strategic networking.
Tip 1: Research Company Divisions. Familiarize yourself with the various operational units housed within the facility. Understanding the specific products and services provided by each division allows for targeted applications and networking efforts.
Tip 2: Target Skills Alignment. Prioritize demonstrating skills directly relevant to the aerospace sector and, ideally, skills required based on current job listings. Highlight certifications, experience with industry-specific software, and applicable technical proficiencies.
Tip 3: Emphasize Quality Assurance Awareness. The aerospace industry adheres to stringent quality control standards. Showcase familiarity with ISO 9001, AS9100, or other relevant quality management systems. Concrete examples of contributing to quality improvements are valuable.
Tip 4: Demonstrate Problem-Solving Abilities. Aerospace engineering and manufacturing require robust problem-solving skills. Prepare examples of successfully addressing technical challenges, implementing process improvements, and overcoming obstacles in previous roles.
Tip 5: Leverage Professional Networks. Attend industry events and connect with professionals currently working in the aerospace sector, particularly those affiliated with facilities in the Wisconsin area. Information interviews can provide valuable insights.
Tip 6: Tailor Application Materials. Avoid generic resumes and cover letters. Customize application materials to directly address the specific requirements and responsibilities outlined in job descriptions. Quantify accomplishments whenever possible.
Tip 7: Prepare for Technical Interviews. Technical roles typically involve rigorous interviews. Practice answering technical questions, reviewing fundamental engineering principles, and preparing detailed explanations of past projects.
These strategies are intended to improve the likelihood of successful engagement and contribution to the workforce located within the facility. Understanding the industry landscape and matching individual expertise with specific needs is paramount.
The following sections will provide more insights related to specific employment areas, the overall economic impact of the location, and recent updates.
1. Manufacturing Capabilities
The facilitys manufacturing capabilities are a cornerstone of its operations. These capabilities encompass a broad range of activities, from precision machining of complex components to the assembly and testing of integrated aerospace systems. The existence of these manufacturing operations at this specific location directly enables the production of parts and assemblies vital to both commercial and military aircraft. For example, the site might specialize in producing actuation systems or electronic controls, which are then integrated into aircraft produced by major manufacturers. Without these manufacturing resources, the broader aerospace industry would face significant supply chain disruptions.
The importance of localized manufacturing extends beyond mere production volume. It fosters innovation by allowing engineers and manufacturing personnel to collaborate closely, leading to optimized designs and efficient production processes. Furthermore, the location’s manufacturing capabilities often support the development of new technologies and materials, contributing to advancements in aircraft performance, safety, and fuel efficiency. A real-world example of this is the development of lighter, more durable materials that are then used in the production of aircraft components, improving fuel economy and extending aircraft lifespans. This benefits airlines through reduced operating costs, and it enables the production of more advanced aircraft.
In conclusion, the manufacturing capabilities at this facility are not simply an operational detail but a critical element underpinning the aerospace industry’s ability to innovate, produce, and maintain aircraft globally. Challenges, such as maintaining a skilled workforce and adapting to evolving technological standards, necessitate continuous investment in training and infrastructure. The sites manufacturing strength directly impacts the efficiency, safety, and technological advancement of the broader aerospace sector.
2. Engineering Expertise
Engineering expertise at the Wisconsin facility represents a critical component of its overall contribution to the aerospace sector. The site’s engineering capabilities drive innovation, improve product performance, and ensure compliance with rigorous industry standards.
- Design and Development of Aerospace Systems
The engineering team at this location focuses on the design and development of advanced aerospace systems. This includes creating detailed specifications, performing simulations, and conducting rigorous testing to ensure the reliability and performance of these systems. A specific example is the development of advanced actuation systems used in flight control surfaces. These systems require precise engineering to ensure responsiveness and safety during flight. The ability to design and develop such systems contributes directly to the safety and efficiency of aircraft.
- Materials Science and Testing
Expertise in materials science is essential for selecting and testing materials used in aerospace applications. Engineers at the site evaluate the properties of various materials, including their strength, durability, and resistance to extreme temperatures and pressures. This ensures that components can withstand the harsh conditions of flight. An example of this is testing composite materials for use in aircraft structures. Thorough testing ensures that these materials meet stringent performance requirements.
- Software and Systems Integration
The integration of software and hardware systems is a critical aspect of modern aerospace engineering. Engineers at the location develop and implement software solutions for controlling and monitoring various aircraft systems. This includes developing embedded software for flight control computers and integrating sensors and actuators into a cohesive system. An example of this work is the development of flight management systems that optimize fuel efficiency and enhance flight safety.
- Compliance and Certification
Aerospace engineering requires strict adherence to industry regulations and standards. The engineering team at this location ensures that all products meet the necessary compliance requirements and certifications. This involves rigorous testing, documentation, and collaboration with regulatory agencies. An example is obtaining FAA certification for new aircraft components. This ensures that products meet stringent safety standards before being deployed in commercial aircraft.
These facets of engineering expertise collectively demonstrate the vital role the Wisconsin facility plays in advancing aerospace technology and ensuring the safety and reliability of aircraft systems. The continuous investment in engineering talent and resources is essential for maintaining the site’s competitiveness and contributions to the aerospace industry. The convergence of these capabilities positions the facility as a key player in the design, development, and certification of critical aerospace components.
3. Regional Employment
The existence of the aerospace manufacturing and engineering facility in New Berlin, Wisconsin, directly influences regional employment patterns. The site serves as a significant employer within Waukesha County and the broader southeastern Wisconsin region. This employment extends across various skill levels, encompassing engineers, technicians, manufacturing personnel, administrative staff, and management roles. The presence of a major aerospace firm creates a demand for skilled labor, impacting local educational institutions and training programs. Technical colleges and universities respond to this demand by offering specialized courses and certifications relevant to the aerospace industry. The facility’s hiring practices, therefore, exert a direct and measurable effect on the regional workforce. A reduction or expansion of operations correlates with fluctuations in employment rates within the surrounding communities. For example, a new contract award might necessitate an increase in manufacturing personnel, while automation initiatives could lead to workforce adjustments.
Furthermore, the facilitys role as an employer extends beyond direct employment. It indirectly supports jobs within its supply chain and related service industries. Local businesses providing materials, equipment, or logistical support benefit from the facility’s presence. The concentration of aerospace-related expertise within the region also attracts other companies and investments, creating a positive feedback loop that further stimulates economic activity and employment opportunities. The practical significance of this is evident in the economic stability and growth observed in communities near major aerospace facilities. These areas typically experience higher levels of job creation and income compared to regions lacking such industrial anchors. The facility also supports apprenticeship programs and internships, fostering the development of future generations of aerospace professionals.
In summary, the aerospace facility in New Berlin is an important driver of regional employment, impacting both direct and indirect job creation. Its presence influences the skills landscape, attracts related businesses, and contributes to the overall economic well-being of the region. While facing challenges such as maintaining a skilled workforce and adapting to technological advancements, the site’s continued operation is vital for sustaining employment opportunities and fostering economic growth in southeastern Wisconsin. This relationship between industrial presence and regional prosperity underscores the importance of supporting and promoting the aerospace sector within the state.
4. Aerospace Innovation
The facility in New Berlin, Wisconsin, actively participates in aerospace innovation through several key mechanisms. Its engineering teams engage in research and development activities focused on enhancing aircraft performance, safety, and efficiency. This innovation manifests in the development of new materials, advanced manufacturing techniques, and improvements to existing aerospace systems. For example, the site may contribute to the design and testing of lighter, more durable composite materials used in aircraft structures. These innovations directly translate into improved fuel efficiency, reduced maintenance costs, and enhanced safety for airlines and passengers. The facility’s commitment to research and development ensures it remains at the forefront of technological advancements within the aerospace industry, driving progress beyond its immediate operational scope.
The incorporation of cutting-edge technologies is integral to the facility’s innovative approach. This includes the adoption of advanced automation systems, 3D printing technologies, and data analytics tools to optimize manufacturing processes and improve product quality. For instance, the implementation of additive manufacturing techniques allows for the creation of complex parts with greater precision and efficiency, reducing material waste and lead times. Furthermore, data analytics are used to monitor manufacturing processes in real-time, identifying potential issues and optimizing performance. These technological integrations contribute directly to the facility’s competitiveness and its ability to deliver advanced solutions to its clients. By embracing these technologies, the facility enhances its capacity for innovation and ensures its continued relevance in the evolving aerospace landscape.
In conclusion, the New Berlin facility plays a significant role in driving aerospace innovation through its research and development efforts, adoption of advanced technologies, and focus on continuous improvement. Its contributions directly impact the performance, safety, and efficiency of aircraft, benefiting both the aerospace industry and the end-users. While challenges such as maintaining a skilled workforce and navigating regulatory hurdles persist, the facility’s commitment to innovation remains a critical element of its long-term success and its contributions to the broader aerospace ecosystem. This commitment ensures the continuous advancement of aerospace technology and its positive impact on society.
5. Supply Chain Integration
The aerospace manufacturing and engineering facility situated in New Berlin, Wisconsin, operates as a critical node within a complex global supply chain. Its functionality is intrinsically linked to the efficient integration and coordination of suppliers, manufacturers, and distributors. Disruptions at any point within this supply chain directly impact the facility’s ability to produce and deliver essential aerospace components and systems. A well-integrated supply chain ensures the timely availability of raw materials, specialized parts, and advanced technologies required for manufacturing processes. The absence of this integration would lead to delays, increased costs, and potentially, compromised product quality. For instance, a disruption in the supply of specialized alloys could halt the production of critical aircraft components, impacting delivery schedules and potentially affecting airline operations. The New Berlin facilitys success depends, therefore, on its ability to manage and optimize its position within this interconnected network.
The facility actively participates in supply chain integration by employing sophisticated inventory management systems, fostering close relationships with key suppliers, and implementing rigorous quality control measures. These efforts aim to minimize disruptions, improve efficiency, and reduce costs. For example, the site might utilize just-in-time (JIT) inventory management to minimize storage costs and ensure the timely availability of materials. It may also collaborate with suppliers to develop customized components that meet specific performance requirements. The implementation of blockchain technology could further enhance transparency and traceability within the supply chain, improving its resilience and accountability. By actively participating in these integration strategies, the facility strengthens its position within the aerospace industry and mitigates the risks associated with global supply chain vulnerabilities. This proactive approach is essential for maintaining a competitive edge and ensuring the continuous delivery of high-quality aerospace solutions.
In summary, the New Berlin, Wisconsin facility is deeply intertwined with the success of its supply chain integration, which directly influences operational efficiency, product quality, and the ability to meet customer demands. Challenges such as geopolitical instability, material shortages, and evolving industry standards necessitate continuous monitoring and adaptation. Strategic investments in supply chain technology, supplier relationships, and workforce training are essential for maintaining a robust and resilient supply chain. The facility’s commitment to these principles underscores its commitment to delivering high-quality aerospace solutions and contributing to the overall success of the industry. The facility’s integration is therefore not merely an operational detail, but a strategic imperative for sustained success.
6. Defense Contribution
The New Berlin, Wisconsin facility’s involvement in the defense sector constitutes a significant component of its operational portfolio. This contribution primarily manifests through the design, development, and manufacturing of critical components and systems utilized in military aircraft, ground vehicles, and other defense-related applications. The facility’s expertise in areas such as avionics, actuation systems, and electronic warfare solutions directly supports the operational readiness and technological superiority of armed forces. For example, the site might produce advanced flight control systems for military helicopters or develop electronic countermeasures to protect aircraft from missile threats. These contributions are essential for maintaining national security and providing military personnel with the tools they need to perform their duties effectively. The absence of these capabilities would negatively impact defense readiness and potentially compromise military operations.
The connection between the New Berlin facility and the defense sector extends beyond direct manufacturing and engineering activities. The site also provides maintenance, repair, and overhaul (MRO) services for military equipment, ensuring the continued functionality and performance of critical defense assets. These services are crucial for extending the lifespan of military systems and minimizing downtime. For instance, the facility might overhaul avionics systems on military transport aircraft or repair damaged components on armored vehicles. The expertise and capabilities present at the site are particularly valuable in supporting legacy systems and adapting them to meet evolving operational requirements. This support ensures that military forces have access to reliable and effective equipment, even as technology advances and new threats emerge. The facility’s commitment to providing high-quality MRO services strengthens its partnership with the defense sector and contributes to the long-term sustainability of military operations.
In summary, the defense contribution of the New Berlin facility is a multifaceted endeavor involving the design, manufacturing, and maintenance of critical components and systems for military applications. This involvement strengthens national security, supports military readiness, and contributes to the technological advancement of defense capabilities. While challenges such as navigating complex regulatory requirements and adapting to evolving military needs persist, the facility’s commitment to serving the defense sector remains a vital aspect of its mission and its broader contribution to society. The integration with the defense sector thus becomes not just an economic driver but a strategic asset.
Frequently Asked Questions
The following questions address common inquiries related to the aerospace facility in New Berlin, Wisconsin, providing objective and factual information.
Question 1: What are the primary product lines manufactured at the New Berlin facility?
The facility specializes in the design, development, and manufacturing of a range of aerospace systems, including actuation systems, flight controls, and avionics components. Specific product offerings are subject to change based on market demands and strategic business decisions.
Question 2: What types of job opportunities are typically available at the location?
Employment opportunities encompass a variety of roles, including engineering positions (mechanical, electrical, aerospace), manufacturing technicians, quality control specialists, supply chain professionals, and administrative staff. Specific openings vary based on current business needs.
Question 3: What certifications or quality standards does the facility adhere to?
The facility operates under stringent quality management systems, typically including AS9100 and ISO 9001 certifications. Adherence to these standards ensures compliance with industry regulations and customer requirements.
Question 4: How does the New Berlin facility contribute to the local economy?
The facility serves as a significant employer in the southeastern Wisconsin region, contributing to the local economy through job creation, tax revenue, and support for local businesses. Its presence also stimulates economic activity within the surrounding communities.
Question 5: Does the facility engage in research and development activities?
Yes, the facility dedicates resources to research and development, focusing on innovation in aerospace technologies, materials, and manufacturing processes. These efforts contribute to the advancement of aerospace capabilities and the development of next-generation products.
Question 6: How does the facility support sustainability and environmental responsibility?
The facility implements various initiatives aimed at minimizing its environmental impact, including waste reduction programs, energy efficiency measures, and compliance with environmental regulations. Specific sustainability efforts are continually evaluated and improved.
These questions and answers provide a general overview of the New Berlin facility. For detailed information, direct engagement with company resources is recommended.
The next section will provide summary and conclusion.
Conclusion
The preceding exploration of Collins Aerospace New Berlin, WI, has illuminated its multifaceted role within the aerospace industry and the regional economy. The facility’s manufacturing capabilities, engineering expertise, and integration within the global supply chain were presented. Also emphasized were its contributions to regional employment, aerospace innovation, and the defense sector. Each of these aspects underscores the facility’s significance as a key player in the advancement of aerospace technology and economic stability within southeastern Wisconsin.
The facility’s continued success hinges on its ability to adapt to evolving industry demands, embrace technological advancements, and foster a skilled workforce. Further research into the site’s long-term strategic plans and community engagement initiatives would provide a more comprehensive understanding of its ongoing impact and future trajectory. The sustained operation and growth of Collins Aerospace New Berlin, WI, remains vital for the continued prosperity of the region and the advancement of the aerospace industry.
