Industrial Engineer
About this position
The Industrial Engineer is responsible for designing and improving production processes, reducing waste, and ensuring compliance with quality and safety standards.
Responsibilities
• Design, build, modify, jig, and tools. Machinery used in the production process in the responsible area based on the principle of Fool proof design As well as improving the capabilities of processes and machines.
• Design the production process to be efficient Reduce non-value-added work and analyze the potential for waste. This is to prevent by relying on the principles of standard work and FMEA to comply with the production of lean systems.
• Reduce control the cost of materials used in production;
• Participate in Analyze problems caused by the production process, as well as cooperate and support various information to the other parties, customers, and product suppliers to correct and prevent waste.
• Perform tasks as assigned by supervisors efficiently and save costs.
• Prepare weekly performance reports.
• Support the company's plan to launch new products.
• Control documentation to ensure compliance and implementation of ISO 9001
• Control, and support various safety-related tasks. To comply with the ISO 45001 & 14001 system.
• Support various tasks to achieve the company's goals and policies.
Requirements
• Education Bachelor's Degree: A Bachelor's degree in Industrial Engineering is typically the minimum qualification. Some related degrees, like Manufacturing Engineering, Operations Research, or Systems Engineering, are also acceptable for entry into the field. Certifications: Various certifications can be beneficial, depending on the industry or specialization, such as: Lean Six Sigma (Green Belt, Black Belt): For process improvement and quality control.
• Core Knowledge Areas Knowledge of how manufacturing systems work, including production planning, materials handling, and supply chain management. Expertise in quality assurance methods, including statistical process control (SPC), total quality management (TQM), and Six Sigma methodologies. Understanding how to design workplaces and processes to improve human interaction with systems. Managing and optimizing the flow of materials and products from suppliers to customers. Analyzing and optimizing complex systems to ensure efficient operation. Skills in analyzing costs and developing strategies to reduce waste and increase efficiency.
• Skills Process Optimization: Ability to analyze existing systems and find ways to make them more efficient, cost-effective, and sustainable. Data Analysis: Proficiency in using statistical tools and software (such as Minitab, R, Excel, or Python) to interpret data and drive process improvements. Project Management: Experience in managing projects from start to finish, often using tools like Gantt charts, PERT diagrams, or software like Microsoft Project or Asana. Problem-solving: Strong analytical thinking to solve complex operational and manufacturing issues. Lean Manufacturing: Knowledge of Lean principles to reduce waste and streamline processes. Communication Skills: Ability to work with cross-functional teams.