Positions within Rexnord’s aerospace sector encompass a range of opportunities related to the design, manufacturing, and support of specialized components and systems for the aviation and aerospace industries. These roles can span engineering, production, quality assurance, supply chain management, and administrative functions. An example would be a mechanical engineer designing a new type of bearing for aircraft landing gear.
Employment within this area contributes significantly to the advancement and reliability of air travel and space exploration. Benefits include contributing to cutting-edge technology, potential for career growth within a global organization, and the satisfaction of knowing one’s work impacts safety and efficiency in the aerospace domain. Historically, the demand for skilled personnel in this field has remained robust, driven by continuous innovation and expansion in the aviation and space sectors.
The following sections will delve into specific career paths, required skills, and the company culture associated with working in this dynamic field. Key areas of focus will include engineering disciplines, manufacturing processes, and the company’s commitment to employee development.
The following suggestions are intended to aid individuals interested in pursuing opportunities within Rexnord’s aerospace division.
Tip 1: Targeted Education: A background in mechanical, aerospace, or materials engineering is highly advantageous. Specific coursework in areas such as finite element analysis, CAD/CAM, and aerospace materials science strengthens candidacy.
Tip 2: Relevant Experience: Prior experience in aerospace manufacturing, quality control, or design, even in internships, provides a significant advantage. Familiarity with aerospace industry standards and regulations is beneficial.
Tip 3: Technical Proficiency: Demonstrated proficiency with relevant software, such as CATIA, SolidWorks, or ANSYS, is critical for many engineering roles. Familiarity with statistical analysis software can also be valuable.
Tip 4: Understanding of Aerospace Standards: Knowledge of industry standards, such as AS9100, and regulatory requirements from agencies like the FAA and EASA is essential for ensuring product compliance and safety.
Tip 5: Highlight Specialized Skills: Expertise in areas such as gear design, bearing technology, or advanced materials processing can differentiate candidates. Showcase any specific knowledge related to Rexnord’s product lines.
Tip 6: Focus on Problem-Solving: Emphasize problem-solving skills and analytical abilities in application materials and interviews. Provide concrete examples of how you have addressed technical challenges in previous roles.
Tip 7: Networking: Attend industry events and conferences to network with professionals in the aerospace sector. Building connections can provide valuable insights and potential opportunities.
Adhering to these suggestions improves the likelihood of a successful application, while aligning skills with specific needs provides tangible evidence of readiness.
The ensuing sections will elaborate on the skills and competencies most valued by Rexnord Aerospace.
1. Engineering roles
Engineering roles are a foundational element within the spectrum of career opportunities at Rexnord’s aerospace division. The efficacy of design, analysis, and testing of aerospace components relies heavily on the expertise of engineers specializing in mechanical, aerospace, materials science, and related disciplines. Consider, for instance, the design of precision bearings crucial for aircraft control surfaces. This task necessitates engineers with a deep understanding of tribology, materials properties, and stress analysis. Without competent engineering personnel, the overall integrity and performance of Rexnord’s aerospace products would be significantly compromised, thereby impacting the organization’s ability to fulfill its commitments to clients in the aerospace sector.
The contribution of engineering talent extends beyond mere product design. These professionals are actively involved in process improvement, failure analysis, and research and development efforts aimed at enhancing the longevity and reliability of aerospace components. For example, materials engineers within the organization might be tasked with identifying and implementing new alloys that offer improved strength-to-weight ratios, thus contributing to enhanced fuel efficiency in aircraft. This illustrates how the engineering skillset is intrinsically linked to continuous innovation and the competitive advantage of Rexnord within the industry. Further, engineering roles often involve collaboration with manufacturing teams to optimize production processes and ensure adherence to stringent quality standards imposed by regulatory bodies such as the FAA and EASA.
In summary, engineering roles represent a critical component of the Rexnord aerospace jobs landscape. Their impact spans product development, process optimization, and regulatory compliance, collectively ensuring the organization’s sustained success in the competitive aerospace market. The demand for skilled engineers within Rexnord’s aerospace division underscores the importance of investing in talent acquisition and employee development within these specialized areas. Failing to prioritize engineering expertise would inevitably undermine the organization’s ability to maintain its position as a leading supplier of aerospace components.
2. Manufacturing Expertise
Manufacturing expertise forms a cornerstone of Rexnord’s ability to deliver high-quality aerospace components. The precision, reliability, and adherence to stringent industry standards required in this sector demand a highly skilled manufacturing workforce. This section explores the crucial facets of manufacturing expertise that are integral to various roles within the organization.
- Precision Machining
The manufacturing of aerospace components often involves extremely tight tolerances and complex geometries. Rexnord’s skilled machinists must be proficient in operating advanced CNC equipment and possess a deep understanding of material properties to ensure parts meet exacting specifications. An example includes the manufacturing of gears for aircraft transmissions, where even micron-level deviations can impact performance and safety. This expertise is crucial for roles such as CNC machinists, tool and die makers, and manufacturing engineers.
- Materials Processing
Aerospace components are frequently made from specialized materials such as titanium, Inconel, and high-strength alloys. These materials require specific processing techniques, including heat treatment, surface finishing, and non-destructive testing to ensure they meet performance requirements. Understanding these processes and their effects on material properties is vital. For instance, proper heat treatment can significantly enhance the fatigue resistance of a landing gear component. This expertise is critical for roles like materials engineers, heat treaters, and quality control inspectors.
- Assembly and Integration
Many aerospace components require intricate assembly procedures involving multiple parts and sub-assemblies. Expertise in assembly techniques, including fastening methods, sealing procedures, and torque control, is essential to ensure proper functionality and prevent premature failure. An example is the assembly of complex bearing systems, where precise alignment and lubrication are critical. Roles requiring this expertise include assembly technicians, manufacturing engineers, and quality assurance personnel.
- Process Control and Quality Assurance
Maintaining consistent product quality requires rigorous process control throughout the manufacturing process. Expertise in statistical process control (SPC), lean manufacturing principles, and quality management systems such as AS9100 is essential for identifying and mitigating potential defects. For instance, real-time monitoring of machining parameters can prevent out-of-tolerance parts from being produced. This expertise is crucial for roles like quality engineers, process engineers, and manufacturing managers.
These facets of manufacturing expertise are fundamental to numerous positions within Rexnord’s aerospace operations. The organization’s commitment to investing in training and development programs ensures that its workforce possesses the necessary skills to meet the evolving demands of the aerospace industry. The integration of advanced manufacturing technologies and continuous improvement initiatives further enhances the value of manufacturing expertise within the context of Rexnord aerospace jobs.
3. Quality Assurance
Quality assurance is an indispensable function within Rexnord’s aerospace operations, intrinsically linked to all facets of related employment opportunities. Its primary objective is ensuring that all manufactured components meet the rigorous standards and specifications mandated by the aerospace industry and regulatory bodies.
- Adherence to Industry Standards
A critical facet of quality assurance within Rexnord’s aerospace jobs is strict adherence to industry standards such as AS9100. This standard establishes a comprehensive quality management system specifically for the aerospace sector. Quality assurance personnel are responsible for implementing and maintaining processes that ensure compliance with these standards. For instance, regular audits are conducted to verify that manufacturing processes adhere to documented procedures, thereby minimizing the risk of defects and ensuring product conformity.
- Inspection and Testing Protocols
Quality assurance professionals implement rigorous inspection and testing protocols throughout the manufacturing process. These protocols encompass a wide range of techniques, including visual inspection, dimensional measurements, non-destructive testing (NDT), and functional testing. For example, radiographic inspection might be employed to detect internal flaws in critical components, while functional testing verifies that components perform as intended under simulated operating conditions. These protocols ensure that only products meeting the highest quality standards are released for use in aerospace applications.
- Statistical Process Control (SPC)
Statistical process control is a key tool employed by quality assurance personnel to monitor and control manufacturing processes. SPC involves the use of statistical techniques to track process variations and identify potential problems before they result in defects. For instance, control charts might be used to monitor the dimensions of machined parts, allowing quality engineers to detect trends or shifts in the process that could lead to out-of-tolerance conditions. By proactively addressing process variations, SPC helps to maintain consistent product quality and reduce the likelihood of defects.
- Corrective and Preventive Action (CAPA)
A robust corrective and preventive action (CAPA) system is essential for addressing any quality issues that may arise. Quality assurance personnel are responsible for investigating the root causes of defects, implementing corrective actions to prevent recurrence, and developing preventive actions to address potential problems before they occur. For example, if a batch of parts is found to be out of specification, a CAPA investigation would be initiated to determine the cause of the deviation and implement measures to prevent similar issues in the future. This proactive approach helps to continuously improve the quality of Rexnord’s aerospace products and processes.
These facets of quality assurance are integral to various roles within Rexnord’s aerospace division, from quality engineers and inspectors to manufacturing managers and process engineers. The effectiveness of the quality assurance function directly impacts the reliability and safety of Rexnord’s aerospace components, thereby underscoring its importance to the organization’s success in this demanding industry.
4. Supply Chain
The supply chain constitutes a critical operational framework impacting various facets of Rexnord’s aerospace-related positions. Its efficiency and effectiveness are directly proportional to the organization’s ability to meet production demands, control costs, and maintain product quality. Therefore, professionals working within this sphere are essential for optimizing the flow of materials and components from suppliers to manufacturing facilities and ultimately to customers.
- Supplier Management
Effective supplier management is vital for securing reliable sources of high-quality materials and components. This involves identifying, evaluating, and managing relationships with suppliers to ensure they meet Rexnord’s stringent requirements. For instance, a supply chain manager might negotiate long-term contracts with suppliers of specialized alloys used in aircraft bearings, ensuring consistent availability and competitive pricing. This is a key responsibility for sourcing specialists and procurement managers.
- Inventory Control
Efficient inventory control is essential for minimizing storage costs and preventing stockouts that could disrupt production. This requires careful forecasting of demand and implementation of inventory management techniques such as just-in-time (JIT) delivery. An example includes maintaining optimal stock levels of fasteners and other standard components used in aircraft assembly. This task falls under the purview of inventory planners and materials managers.
- Logistics and Transportation
Optimizing logistics and transportation is crucial for ensuring timely delivery of materials and components to the right locations. This involves selecting appropriate transportation modes, negotiating shipping rates, and managing customs clearance. Consider the transport of large-diameter bearings for landing gear systems from a specialized manufacturer to Rexnord’s assembly plant. Efficient logistics are crucial for meeting production deadlines. Logistics coordinators and transportation specialists are responsible for these activities.
- Demand Planning and Forecasting
Accurate demand planning and forecasting are necessary for aligning supply with customer demand. This involves analyzing historical sales data, market trends, and customer orders to predict future demand for Rexnord’s aerospace products. For instance, forecasting the demand for replacement bearings for a specific aircraft model helps to ensure adequate inventory levels are maintained. This is typically handled by demand planners and sales forecasters.
The efficient management of these supply chain components directly influences Rexnord’s ability to deliver high-quality aerospace components on time and within budget. Roles in sourcing, logistics, and planning are critical for ensuring a resilient supply chain that supports the organization’s commitments to its aerospace customers. The coordination and optimization of these activities underpin the operational success and competitive advantage of Rexnord within the aerospace industry.
5. Technical Skills
Technical skills are a primary determinant of success within the context of Rexnord’s aerospace roles. These skills represent the practical application of knowledge and expertise directly relevant to the design, manufacture, and maintenance of aerospace components. The demand for specialized technical abilities stems from the industry’s rigorous requirements for precision, reliability, and safety. A mechanical engineer, for instance, must possess proficiency in finite element analysis to simulate stress distributions in critical components. Failure to adequately assess structural integrity can have catastrophic consequences, emphasizing the crucial link between technical competence and operational safety. The presence of such skills directly affects the quality and reliability of the product or service being delivered.
Furthermore, technical skills extend beyond theoretical knowledge to encompass hands-on experience with specialized equipment and software. CNC machinists, for example, require mastery of computer-aided manufacturing (CAM) software to translate engineering designs into precise machine instructions. Similarly, quality control inspectors must be adept at using non-destructive testing (NDT) techniques to identify internal flaws in materials. The mastery of these skills allows technicians to ensure adherence to stringent industry standards and regulations, while ensuring a cost-effective and competitive market. These skills will have an effect on production cycle, increasing market growth and competitive market
In conclusion, technical skills are not merely a desirable attribute for Rexnord’s aerospace positions; they are a fundamental prerequisite for ensuring product integrity, operational safety, and regulatory compliance. The ongoing demand for skilled technicians and engineers underscores the significance of investing in technical education and training programs to meet the evolving needs of the aerospace industry. Without a competent workforce equipped with the necessary technical expertise, Rexnord would be unable to maintain its position as a leading supplier of high-performance aerospace components.
6. Career Growth
Career growth within Rexnord’s aerospace division is directly influenced by the organization’s structure, technological advancements, and industry demands. Entry-level positions provide a foundation for developing specialized skills, while opportunities for advancement arise from demonstrated competence and continuous learning. The availability of internal training programs, mentorship opportunities, and tuition reimbursement schemes contribute to employees’ abilities to acquire new knowledge and progress within the company. For instance, a technician starting in assembly might progress to a supervisory role or transition into a more specialized area such as quality engineering with appropriate training and experience.
The aerospace industry’s dynamic nature necessitates continuous adaptation and skill development. Employees who proactively seek opportunities to expand their expertise and stay abreast of technological advancements are better positioned for career advancement. Rexnord’s investment in research and development also creates avenues for career growth, particularly for engineers and scientists involved in developing innovative solutions. A materials engineer working on new alloy development might advance to a project management role, overseeing the implementation of these materials in new product lines. The organization’s performance management system and talent development programs play a critical role in identifying and nurturing high-potential employees.
Ultimately, career progression within Rexnord’s aerospace sector depends on a combination of individual initiative, organizational support, and alignment with the company’s strategic goals. While challenges such as competition for promotions and the need for ongoing skill development exist, the opportunities for career growth are substantial for individuals who demonstrate commitment, adaptability, and a willingness to learn. This aspect is crucial in attracting and retaining top talent within a highly competitive industry.
Frequently Asked Questions
The following questions and answers address common inquiries concerning employment prospects within Rexnord’s aerospace sector. These answers are designed to provide clarity and insight for prospective applicants.
Question 1: What specific engineering disciplines are most commonly sought for aerospace-related roles?
Mechanical, aerospace, and materials engineering are frequently sought for positions involving design, analysis, and testing of aerospace components. Electrical and computer engineering may be relevant for roles involving control systems or avionics.
Question 2: What level of experience is typically required for entry-level positions?
Entry-level positions generally require a bachelor’s degree in a relevant engineering discipline or a related technical field. Internships or co-op experiences in aerospace or a related industry are highly beneficial but not always mandatory.
Question 3: Are there opportunities for professional development and continuing education?
Rexnord typically provides opportunities for professional development through internal training programs, external workshops, and tuition reimbursement for relevant continuing education courses. Specifics may vary depending on the role and business unit.
Question 4: What are the key performance indicators (KPIs) used to evaluate employee performance in aerospace positions?
KPIs may include adherence to project timelines, cost control, product quality metrics, safety compliance, and contribution to innovation. Specific KPIs will vary depending on the role and department.
Question 5: What types of manufacturing processes are commonly employed in the production of aerospace components?
Common manufacturing processes include precision machining (CNC milling, turning), welding, heat treatment, non-destructive testing (NDT), and assembly. Knowledge of these processes is essential for many manufacturing-related roles.
Question 6: How does Rexnord ensure compliance with aerospace industry regulations?
Compliance with aerospace industry regulations, such as AS9100, is ensured through a robust quality management system. This system encompasses documented procedures, internal audits, and regular training to ensure that all processes meet regulatory requirements.
These responses aim to provide a clearer understanding of the requirements and opportunities within Rexnord’s aerospace division. Successful candidates typically possess a combination of relevant education, technical skills, and a commitment to continuous learning.
The next segment will explore essential takeaways from the above discussion.
Conclusion
The preceding exploration of “rexnord aerospace jobs” has illuminated various critical aspects, spanning engineering disciplines, manufacturing expertise, quality assurance protocols, and supply chain management. Technical skills, professional development opportunities, and the overall potential for career growth have been underscored as essential considerations. The analysis reinforces the demand for specialized knowledge and the necessity of adhering to stringent industry standards within this sector.
The enduring significance of Rexnord’s aerospace division within the broader aviation and space industries warrants continued attention from prospective employees and industry stakeholders alike. Further investigation into specific roles, technological advancements, and the company’s strategic initiatives is encouraged for those seeking to contribute to the advancement of aerospace engineering and manufacturing.
