Collins Aerospace in Troy, OH: Jobs & Impact [2024]

A significant manufacturing and technological presence exists in a city located in the southwestern region of the Buckeye State. Specifically, a major facility operating as part of a global leader in aerospace and defense is located there, contributing to the region’s economic landscape and technological advancement.

The facility’s presence fosters local job creation and provides opportunities for skilled workers in engineering, manufacturing, and related fields. Furthermore, its operations support technological innovation, contributing to advancements in aerospace components, systems, and services. The history of this operation is rooted in a legacy of engineering excellence, evolving to meet the ever-changing demands of the aviation industry and national defense.

The presence of this major aerospace entity in this specific Ohio city is intrinsically linked to ongoing discussions regarding economic development, technological advancement, and workforce opportunities within the region and the broader aerospace sector.

Considerations for Navigating Developments

The following points offer guidance when analyzing matters connected to the aerospace entity in the Ohio municipality.

Tip 1: Monitor Regional Economic Reports: Review economic development reports from the Ohio region. These publications frequently detail the impact of large employers, including manufacturers, on the local economy and workforce dynamics.

Tip 2: Track Aerospace Industry News: Stay informed about aerospace industry trends through reputable news sources and trade publications. Developments affecting the broader aerospace sector can indirectly impact operations within specific facilities.

Tip 3: Review Company Public Statements: Analyze official press releases and statements issued by the aerospace organization. These communications offer insights into strategic priorities, facility investments, and potential workforce adjustments.

Tip 4: Examine Government Contracts and Awards: Investigate publicly available records of government contracts and awards related to the aerospace entity. These documents provide context for the organization’s projects and revenue streams.

Tip 5: Follow Local Government Initiatives: Track local government initiatives focused on economic development and workforce training. These programs may be designed to support and attract industries like aerospace manufacturing.

Tip 6: Consider Supply Chain Relationships: Investigate the supply chain connected to the facility. Understanding the network of suppliers and partners provides a broader perspective on its economic influence.

Tip 7: Analyze Workforce Data: Examine workforce statistics related to manufacturing and engineering occupations within the region. This data can indicate the demand for skilled labor and the impact of major employers.

By considering these points, a more informed perspective can be developed regarding the ongoing operations and potential future developments associated with this prominent aerospace entity.

The information above provides a framework for further investigation and analysis.

1. Advanced Manufacturing

The integration of advanced manufacturing practices is central to the operations conducted by the aerospace entity located in the Ohio city. These methodologies are not merely supplementary but are foundational to its ability to produce high-precision components and systems for the aerospace industry.

• Precision Machining and Fabrication

  Sophisticated machining and fabrication techniques, including computer numerical control (CNC) machining, additive manufacturing (3D printing), and laser cutting, are employed to create intricate and highly accurate parts. These capabilities are critical for producing components that meet stringent aerospace specifications. As an example, complex turbine blades are manufactured using multi-axis CNC machines to achieve the required aerodynamic profiles and material properties. This ensures optimal engine performance and fuel efficiency.

• Automation and Robotics

  Automation and robotics are utilized extensively throughout the manufacturing processes to enhance efficiency, reduce errors, and improve worker safety. Robotic systems handle repetitive tasks, such as material handling, welding, and painting, enabling human operators to focus on more complex and value-added activities. The integration of automated inspection systems ensures that parts meet quality standards at each stage of production. This application minimizes the risk of defects and reduces the need for rework.

• Digital Manufacturing and Data Analytics

  Digital manufacturing technologies, including the Internet of Things (IoT), cloud computing, and data analytics, are leveraged to optimize manufacturing processes and improve decision-making. Sensors embedded in equipment and machines collect real-time data on performance, utilization, and environmental conditions. This data is analyzed to identify patterns, predict potential failures, and optimize maintenance schedules. The use of digital twins allows for virtual simulations of manufacturing processes, enabling engineers to test new designs and optimize production parameters before implementation on the shop floor. This significantly reduces development time and improves product quality.

• Materials Science and Engineering

  Advanced materials, such as titanium alloys, composites, and ceramics, are utilized to create lightweight, strong, and durable components that can withstand extreme operating conditions. Material selection and processing are carefully controlled to ensure that parts meet the required mechanical, thermal, and chemical properties. Advanced surface treatments, such as coatings and plating, are applied to protect components from corrosion, wear, and environmental degradation. The use of advanced materials enables the manufacture of high-performance components that contribute to the overall efficiency and reliability of aerospace systems.

These advanced manufacturing facets illustrate the technological sophistication that exists within the aerospace facility in the Ohio location. Such practices are crucial for maintaining competitiveness in the global aerospace market and fulfilling the demanding requirements of modern aviation.

2. Aerospace Engineering

Aerospace engineering is inextricably linked to the operations in the Ohio city. It provides the intellectual and technical foundation for the design, development, and manufacturing of aerospace components and systems at that location. The presence of aerospace engineering expertise is crucial for maintaining competitiveness and driving innovation within the facility.

• Design and Analysis of Structural Components

  Aerospace engineers conduct structural analyses to ensure that components can withstand the stresses and strains experienced during flight. This involves the use of finite element analysis (FEA) software to simulate the behavior of structures under various loading conditions. For instance, engineers analyze the wing structures to determine their ability to withstand aerodynamic forces, as well as vibrations. This is crucial for ensuring structural integrity and preventing failures.

• Development of Avionics Systems

  Avionics engineers design and develop the electronic systems that control and monitor aircraft functions. This includes navigation systems, communication systems, and flight control systems. Software and hardware integration is vital. Flight control computers exemplify this; they require sophisticated algorithms to stabilize the aircraft, manage fuel consumption, and provide pilots with critical flight data.

• Aerodynamics and Fluid Dynamics Research

  Aerospace engineers conduct research in aerodynamics and fluid dynamics to improve the performance and efficiency of aerospace vehicles. Wind tunnel testing, as well as computational fluid dynamics (CFD) simulations, are employed to study airflow patterns around aircraft. This research informs the design of more efficient wings, engine inlets, and other aerodynamic surfaces. One crucial research area involves understanding the formation of turbulence and its effect on drag; this knowledge is incorporated into the design of aircraft and jet engines.

• Materials Science and Engineering Applications

  Aerospace engineers are involved in the selection and application of advanced materials for aerospace components. This includes the use of composites, titanium alloys, and other lightweight, high-strength materials. Engineers must understand the properties of these materials and how they behave under different operating conditions. Examples includes the application of carbon fiber reinforced polymers (CFRP) in aircraft fuselages to reduce weight and improve fuel efficiency.

The application of aerospace engineering principles within the Ohio facility is vital for developing and manufacturing high-performance aerospace components. By integrating advanced design methodologies, sophisticated simulation tools, and a deep understanding of materials science, the engineers at this location contribute significantly to the advancement of aerospace technology and to the enduring competitiveness of this aerospace facility.

3. Regional Employment

A significant factor within the operational scope of the aerospace entity in the Ohio municipality is its role as a major employer. The facility provides a variety of job opportunities, influencing the economic landscape and contributing to the overall employment rate within the region.

• Direct Employment Opportunities

  The aerospace facility directly employs a substantial number of individuals in a variety of roles, ranging from skilled manufacturing technicians and engineers to administrative and management personnel. These positions offer competitive salaries and benefits, providing economic stability for employees and their families. For example, the facility could employ hundreds of machinists, assemblers, and quality control specialists dedicated to manufacturing aerospace components. These direct employment opportunities contribute significantly to the local tax base and support local businesses.

• Indirect Employment Generation

  Beyond direct employment, the presence of the aerospace facility generates indirect employment opportunities within the region. These jobs are created in supporting industries, such as suppliers of raw materials, transportation services, and maintenance providers. The facilitys demand for these services creates a ripple effect, stimulating economic activity and creating additional job opportunities. As an example, local trucking companies may expand their operations to transport materials and finished products to and from the facility, creating new driving and logistical support positions.

• Skill Development and Training Programs

  The aerospace entity often invests in skill development and training programs to enhance the capabilities of its workforce. These programs may include apprenticeships, on-the-job training, and tuition reimbursement for employees pursuing higher education. By investing in workforce development, the facility ensures that it has a skilled workforce capable of meeting the evolving demands of the aerospace industry. As an example, the facility may partner with local community colleges to offer specialized training programs in advanced manufacturing techniques, preparing students for careers in the aerospace sector.

• Economic Stabilization and Community Support

  The presence of a large employer like the aerospace facility can provide economic stabilization for the region, reducing reliance on other industries and providing a stable source of income for residents. The facility also contributes to community support through charitable donations, sponsorships, and volunteer activities. This active engagement in the community strengthens the relationship between the facility and its neighbors, creating a mutually beneficial partnership. The facility may sponsor local STEM education initiatives, encouraging students to pursue careers in science, technology, engineering, and mathematics.

The influence of this aerospace operation extends far beyond its physical location. Its impact on regional employment serves as a catalyst for economic development, driving job creation, fostering skill development, and providing stability to the surrounding communities. The synergy between the facility and the local workforce creates a mutually beneficial relationship that sustains both the facility and the broader regional economy.

4. Technological Innovation

The Ohio-based aerospace facility is significantly involved in driving technological innovation within the aerospace industry. This commitment is not simply aspirational; rather, it is fundamental to the entity’s operational model and long-term competitiveness. The facility’s activities, ranging from materials science to advanced manufacturing processes, directly contribute to advancements in aerospace technology.

• Development of Advanced Materials

  The facility actively engages in the research and development of advanced materials suitable for aerospace applications. This includes the investigation of lightweight alloys, composite materials, and high-temperature ceramics. These materials are designed to improve aircraft performance, reduce fuel consumption, and enhance structural integrity. An example involves the development of novel titanium alloys with superior strength-to-weight ratios. These materials enable the manufacture of lighter and more efficient aircraft components, leading to reduced operating costs and improved environmental performance. The implication of such innovation is enhanced fuel efficiency and aircraft range.

• Advancements in Avionics Systems

  The aerospace entity is involved in the development of sophisticated avionics systems, including navigation systems, flight control systems, and communication systems. These systems incorporate cutting-edge technologies, such as artificial intelligence, machine learning, and sensor fusion. An example is the development of autonomous flight control systems that can enhance safety and reduce pilot workload. These systems use advanced algorithms to analyze real-time data from multiple sensors, enabling them to make decisions and control the aircraft without human intervention. The implication is increased safety and efficiency in flight operations.

• Application of Additive Manufacturing Techniques

  The facility leverages additive manufacturing techniques, such as 3D printing, to produce complex aerospace components with enhanced performance characteristics. This approach enables the creation of intricate geometries and customized designs that are not feasible with traditional manufacturing methods. An example involves the 3D printing of engine nozzles with optimized cooling channels. This improves engine efficiency and reduces emissions. Additive manufacturing also allows for rapid prototyping and accelerated product development cycles, which is advantageous for bringing innovative aerospace technologies to market quickly. The implication is faster development and production of aerospace components.

• Integration of Digital Engineering Tools

  The entity utilizes digital engineering tools, such as computer-aided design (CAD), computer-aided manufacturing (CAM), and computer-aided engineering (CAE), to design and simulate aerospace systems. These tools enable engineers to create virtual prototypes and test designs under various operating conditions. An example is the use of computational fluid dynamics (CFD) software to simulate airflow patterns around aircraft wings. This allows engineers to optimize wing designs for improved aerodynamic performance. Digital engineering tools also facilitate collaboration and knowledge sharing among engineers, leading to more efficient product development. The implication is improved design and performance of aerospace systems.

These technological advancements, driven by the specific operational location and its parent organization, underscore the pivotal role this aerospace entity plays in pushing the boundaries of innovation within the aerospace sector. The integration of these advancements results in improved performance, efficiency, and safety across a broad spectrum of aerospace applications.

5. Economic Impact

The presence of the aerospace facility in the Ohio city exerts a considerable influence on the regional and local economies. This impact extends beyond direct employment, creating a complex web of economic relationships that benefit a range of stakeholders.

• Direct Financial Contributions Through Employment

  The facility’s payroll represents a substantial direct financial contribution to the local economy. Employees’ wages and salaries are spent within the community, supporting local businesses and services. Furthermore, income taxes paid by employees contribute to the funding of local government services, such as schools and infrastructure. For example, a facility employing several hundred individuals with an average salary supports numerous local businesses, from restaurants and retailers to housing providers. The stability of this income stream is a critical factor in the region’s economic health.

• Indirect Support for Supply Chain Businesses

  The facility relies on a network of suppliers and service providers, both local and regional, to support its operations. This creates indirect economic benefits for these businesses, as they receive revenue from the aerospace facility. This can lead to business expansion, job creation, and increased investment in the local economy. For example, a local machine shop that provides precision-machined parts to the aerospace facility may be able to invest in new equipment and hire additional employees as a result of this business relationship. This further stimulates the regional economy.

• Attraction of Related Industries and Investment

  The presence of a major aerospace facility can attract other related industries and investment to the region. This is because companies in the aerospace supply chain may choose to locate near the facility to reduce transportation costs and improve coordination. Furthermore, the presence of a skilled workforce and a supportive business environment can attract other high-tech companies to the area. For example, an engineering firm specializing in aerospace design may choose to open an office near the facility to take advantage of the available talent pool and collaborate with the facility on projects. This clustering effect can create a virtuous cycle of economic growth.

• Contribution to the Local Tax Base

  The aerospace facility contributes to the local tax base through property taxes, sales taxes, and other forms of taxation. These tax revenues help to fund essential public services, such as schools, roads, and public safety. The facility’s tax contributions can also support economic development initiatives, such as infrastructure improvements and business attraction programs. A significant facility can be a major source of tax revenue for the local government, providing the resources necessary to improve the quality of life for residents and support future economic growth.

In conclusion, the aerospace facility’s economic impact extends far beyond its own operations, influencing a wide range of sectors and contributing significantly to the overall prosperity of the region. The financial contributions, indirect support for businesses, attraction of related industries, and contribution to the tax base all underscore its importance as an economic driver.

6. Supply Chain Integration

Effective supply chain integration is a critical element supporting the operations within the aerospace entity located in the Ohio city. The facility’s ability to produce high-quality aerospace components and systems is contingent on a well-managed and integrated network of suppliers, manufacturers, and logistics providers.

• Strategic Sourcing and Supplier Relationships

  The aerospace operation relies on strategic sourcing practices to identify and select suppliers who can provide high-quality materials and components at competitive prices. Establishing strong relationships with key suppliers is essential for ensuring a reliable and responsive supply chain. As an example, the facility may develop long-term contracts with suppliers of specialty alloys or composite materials, guaranteeing a stable supply of these critical inputs. These relationships enable collaborative efforts to improve quality, reduce costs, and enhance innovation.

• Inventory Management and Logistics Coordination

  Efficient inventory management and logistics coordination are vital for minimizing lead times and reducing inventory costs. The aerospace facility utilizes advanced inventory management systems to track materials and components throughout the supply chain, from raw materials to finished products. Logistics coordination involves optimizing transportation routes, warehousing strategies, and delivery schedules. As an example, the facility may implement a just-in-time (JIT) inventory system, where materials are delivered only when they are needed for production. This reduces storage costs and minimizes the risk of obsolescence. Effective inventory management and logistics coordination ensure that materials are available when and where they are needed, supporting uninterrupted production.

• Quality Control and Traceability

  Maintaining rigorous quality control and traceability throughout the supply chain is paramount in the aerospace industry. The facility implements comprehensive quality control procedures to ensure that all materials and components meet stringent aerospace standards. Traceability systems are used to track the origin and history of each part, enabling quick identification and resolution of any quality issues. For example, the facility may require suppliers to provide detailed documentation on the manufacturing process for each component, including material certifications and inspection reports. This level of scrutiny ensures that all parts meet the required specifications and are safe for use in aerospace applications.

• Information Technology Integration

  Effective supply chain integration requires the seamless flow of information between the aerospace facility and its suppliers. This is achieved through the use of information technology systems, such as enterprise resource planning (ERP) software and supply chain management (SCM) tools. These systems enable real-time visibility into inventory levels, production schedules, and supplier performance. The utilization of electronic data interchange (EDI) for transmitting purchase orders and invoices streamlines the procurement process, reducing paperwork and improving efficiency. Information technology integration facilitates collaboration and communication among all supply chain partners, leading to improved decision-making and optimized supply chain performance.

The effectiveness of supply chain integration is intrinsically linked to the aerospace operation’s ability to meet production targets, control costs, and maintain high levels of quality. Through strategic sourcing, inventory management, quality control, and information technology integration, the aerospace facility ensures a resilient and efficient supply chain that supports its competitive position in the aerospace industry.

Frequently Asked Questions

The following addresses common inquiries regarding the aerospace entity located in Troy, Ohio. The responses are intended to provide factual information and context regarding its operations and impact.

Question 1: What specific types of products are manufactured at this Troy, Ohio location?

The Troy, Ohio facility manufactures a range of aerospace components and systems. These include, but are not necessarily limited to, actuation systems, power management systems, and other critical components for commercial and military aircraft. Specific product lines are subject to change based on market demands and technological advancements.

Question 2: How many people are employed at the aerospace facility in Troy, Ohio?

Employment figures fluctuate based on business conditions and project demands. However, the facility generally employs a significant number of individuals in various roles, including engineering, manufacturing, administration, and management. Current employment figures are typically available through the company’s investor relations or public relations departments.

Question 3: What is the overall economic impact of this facility on the Troy, Ohio, region?

The facility’s economic impact is multifaceted. It includes direct employment, indirect employment through supply chain relationships, contributions to the local tax base, and support for local businesses and services. A detailed economic impact assessment would require a comprehensive study of the region’s economic data.

Question 4: What types of skills and qualifications are typically sought in employees at this location?

The facility seeks individuals with a range of skills and qualifications, depending on the specific role. These often include engineering degrees (aerospace, mechanical, electrical), manufacturing experience, technical certifications, and strong problem-solving abilities. Experience in the aerospace industry is generally considered a valuable asset.

Question 5: Does the Troy, Ohio, facility engage in research and development activities?

The facility is involved in research and development activities, aimed at improving existing products and developing new technologies for the aerospace industry. These activities often involve collaboration with universities, research institutions, and other companies in the aerospace sector.

Question 6: How does the facility contribute to the local community in Troy, Ohio?

The facility contributes to the local community through various means, including charitable donations, sponsorships of local events, and volunteer activities. The company may also support local educational initiatives and workforce development programs.

These questions and answers offer a general overview of the aerospace entity’s presence in Troy, Ohio. Further specific information should be sought directly from the company’s official sources.

The following section transitions to an exploration of potential future developments related to the facility.

Concluding Observations on troy ohio collins aerospace

This exploration has considered various facets associated with the aerospace facility located in Troy, Ohio. The analysis encompassed advanced manufacturing techniques, aerospace engineering contributions, regional employment dynamics, technological innovation, broader economic impact, and supply chain integration. These interconnected elements demonstrate the facility’s multifaceted role within the regional economy and the broader aerospace industry.

The continued monitoring of developments related to the Troy, Ohio, Collins Aerospace facility is warranted, given its significance as a driver of economic activity and technological advancement. Consistent evaluation of publicly available information, industry reports, and economic indicators remains essential for understanding the evolving influence of this entity on the region and within the aerospace sector.