Objectives
• Explain the role of the 3500 monitoring system in machinery monitoring and protection
• Identify installation conditions affecting the correct operation of proximity transducer systems
• Test monitor alarms and verify channel values in a radial vibration monitor
• Use Bently Nevada propriety configuration software to configure and/or reconfigure the 3500 monitor system
• Troubleshoot the 3500 monitor system and associated transducers using software and hardware techniques
Objectives
• Extend knowledge on machinery diagnostic techniques and rotor dynamics for rotating machinery
• Recognize, explain and account for effects of complex rotor dynamics interaction of modes, mode shapes,
thermal changes, bearing design, torsional vibration and structural modes by using rotor modeling, actual
machine data and case history
• Use standard vibration diagnostic tools on machine-simulating rotor kits through demonstration
• Analyze and discuss case histories that highlight the vibration documentation, analysis and machine
malfunction corrective techniques.
Objectives
• Discover the various types of machines and practical application of the malfunction detection methodology
taught during the Machinery Diagnostics course
• Practice on real data from the field from different rotating machines and learn about their typical malfunctions
• Analyze actual machine case histories using System 1 or ADRE databases
• Organize data in plot formats believed to be indicative of the machine fault
• Present conclusions and make recommendations
Objectives
• Explain how the fundamentals of machine design and behavior are reflected in the vibration measurements
• Reduce machine vibration data into usable plot formats. Explain which plot formats are best to use in the different stages of machine diagnostics
• Describe the causes, effects and indicators of the typical machine malfunctions; including recognition of problems such as unbalance, misalignment, rubs, shaft cracks and fluid induced instabilities
Objectives
• Explain the role of the Orbit 60 monitoring system in machinery monitoring and protection
• Learn how to configure and maintain the Orbit 60 monitoring system
• Test alarms and troubleshoot the Orbit 60 monitoring system
Objectives
• Manage alarms and generate diagnostic reports with actionable information
• Configure and manage alarm setpoints with statistical tools
• Verify transient and steady state data using various types of plots, analyze, and visualize data to report on
machine health and determine appropriate actions
• Maintain healthy System 1 databases to ensure operational efficiency
Today, the worlds of functional safety and cyber security are inseparably linked in modern plant and process control systems.
This is also reflected by relevant standards regarding functional safety e.g. IEC 61511 with requirements to conduct a security risk assessment to identify the security vulnerabilities for SIS and to provide the necessary resilience against the identified security risks.
Engineers, Project Managers, Plant Managers, Technicians, and all who may be directly or indirectly involved are faced to handle, describe and understand principles of security management.
The 3.5 day Training will provide you with valuable skills and knowledge. This training ends with an exam. Successful participants will receive a written confirmation from TÜV Rheinland indicating that they have passed the exam. This document is a prerequisite to attend the advanced trainings of the TÜV Rheinland Cyber Security Training Program and to obtain the CySec Specialist (TÜV Rheinland) certificate.
Download Cyber Security Fundamentals (TÜV Rheinland)traning PDF
Functional Safety Engineer in Railway Industries according to TÜV Süd According the standards EN 50126 / EN 50128 / EN 50129 / EN 50159 the participant will learn about the processes necessary in the safety life cycle. The training course adopts a situation-based approach to the role of supporting processes and the resulting deliverables.
Explanations of the necessary work products and appropriate treatment of safety plans are an integral part of the training
This 3,5-day workshop will highlight the requirements of the different standards and will give advice for a standard-conform realization of Functional Safety.
Participants will learn how to understand Functional Safety Management and Lifecycle principles as well as how to communicate and use them.
Download Functional Safety Engineer(TÜV Süd) Cenelec traning PDF
Engineering HIMax systems with SILworX
The HIMax system is programmed and configured using the SILworX programming tool.
The course starts with an introduction of system family HIMax and options for implementation and operation. Then the handling of SILworX will be discussed extensive in all major parts.
Here the participants will get a deep understanding starting with programming techniques via generation of project up to test and diagnosis possibilities. Also the implementation of safety requirements will be discussed in detail. Training will be supported by practical exercises using projects in HIMax systems.
Upon successful completion, every participant will be able to generate projects in SILworX and implement HIMax systems on-site and are able to independently engineer and operate the communication between HIMax systems and between HIMax systems and third-party systems.
Engineering HIQuad X systems
The HIQuad X system is programmed and configured using the SILworX programming tool.
The course starts with an introduction of system family HIQuad X and options for implementation and operation. Then the handling of systems will be discussed extensive in all major parts.
Here the participants will get a deep understanding starting first startup of system up to test and diagnosis possibilities. Also the implementation of safety requirements will be discussed in detail. Training will be supported by practical exercises using projects in HIQuad X systems.
Upon successful completion, every participant will be able to handle system HIQuad X and implement HIQuad X systems on-site.