.Whirlpool Corporation (NYSE:WHR) is committed to being the best global kitchen and laundry company, in constant pursuit of improving life at home. In an increasingly digital world, the company is driving purposeful innovation to meet the evolving needs of consumers through its iconic brand portfolio, including Whirlpool, KitchenAid, Maytag, Consul, Brastemp, Amana, Bauknecht, JennAir, Indesit and Yummly. In 2020, the company reported approximately 19 billion in annual sales, 78,000 employees and 57 manufacturing and technology research centers.Whirlpool Corporation is consistently recognized by FORTUNE as one of the World's Most Admired Companies. Our values are the driving force behind everything we do. Integrity, Respect, Inclusion and Diversity, One Whirlpool, and Spirit of Winning propel our teams to excellence. Get to know us and see what its like to be part of a company that is in constant pursuit of improving life at home.This role in summaryWhirlpool is looking for a Subsystem Sr Analyst. The role is located in the Global Product Organization within the Refrigeration Platform. The engineer will be responsible for Mechanical Structures subsystem deliverables, including development, execution, verification and validation, working with global cross functional teams during various phases of projects and across various technologies such as structural mechanics, plastic design and sheet metal design.Your responsibilities will include:Drive New Product Development projects for the refrigeration business with a focus on structural components.:Handle multiple projects simultaneously and drive them to implementation using the concurrent engineering mindset by closely working with key stakeholders such as system integrators, cooling and thermal subsystems, industrial engineers, marketing, verification and validation team, controls, sourcing and procurement, manufacturing, etc:Starting with multiple concepts development and converging to preferred concepts by use of conceptevaluation tools, design development, simulation and verification and validation methods.:Development of detailed design considering key metrics (material, manufacturability (DFM, DFA), cost, aesthetics, craftsmanship, safety, etc:Design capture by use of Failure Modes and Effects analysis (FMEA), requirements capture, Design guides, drawings, Tol Stacks, A3s, etc:Use of OPEx (Six Sigma) tools and fundamentals to drive product development. Use of critical thinking, Design of Experiments (DOEs), Component of Variations (COVs), Thought Maps, Process Maps, etc:Submitting simulation requests with clear boundary condition definitions, and interpret results to make necessary design modifications