64903 Courses

AM2EU1

The 5-Day Beginner Industrial Robotics Course is designed for individuals with little to no prior experience in robotics, offering a solid introduction to the fundamentals of industrial automation. This hands-on training program provides participants with the essential skills and knowledge to understand, operate, and program industrial robots, preparing them for real-world applications. Throughout the course, attendees will learn the basics of how robots work, including their key components, types, and movements. The course starts with an overview of industrial robots and their role in various industries, followed by essential safety protocols to ensure safe and effective robot operation. Practical sessions will allow participants to set up and perform simple robot tasks, building their confidence in controlling and programming robots. By the end of the 5-day training, beginners will have a clear understanding of how industrial robots function, how to program them for various tasks, and how to set them up safely. They will be equipped with the foundational skills needed to start a career in robotics or apply robotic solutions in their own industries, driving efficiency and automation.

This course is designed for site managers, site agents and those who are responsible for planning, organising and monitoring staff.

Students who complete PV202 will be able to: Define the purpose of the National Electrical Code (NEC®) and NEC® terminology for PV equipment Determine procedures for proper installation of equipment and conductors, including minimum requirements for working space Examine methods for PV wire management and determine where expansion fittings are required Describe and identify electrical services, including split-phase and three-phase Wye (Y) and Delta (∆) Evaluate electrical service details to collect and record during solar site evaluation Identify options for NEC®-compliant PV system interconnection to the utility grid and determine whether a supply side, load side, or additional service connection is appropriate Identify code-compliant methods for connecting an inverter to an existing AC feeder Calculate PV module voltage based on temperature to ensure compatibility with system components and NEC® Section 690.7, and explore other options for maximum PV system DC voltage calculations Identify NEC® requirements and sizing of disconnects and overcurrent protection devices (OCPDs) in grid-direct PV systems Define inverter grounding configurations Evaluate inverter choices and system configurations, including string inverters, central inverters, and module level power electronics (MLPE) Identify requirements for equipment grounding, equipment grounding conductors (EGC), and grounding electrode conductors (GEC), and size the conductors according to the NEC® Identify common causes of ground-faults and arc-faults Describe ground-fault and arc-fault protection devices Describe benefits and appropriate locations of surge protection devices (SPD) Demonstrate the use of sun charts and perform calculations to determine row spacing and minimize inter-row shading Identify how Codes detailing access for first responders impact PV array roof layout Examine fire classifications that affect racking and module selection Detail NEC rapid shutdown requirements and options for implementation Identify load and structural considerations for low- and steep-slope roof-mounted PV systems Calculate wind uplift force and select appropriate lag bolts Review issues related to planning, design, and installation of ground-mount PV arrays Review PV system circuit terminology, definitions, and conductor types Calculate minimum overcurrent protection device (OCPD) size and conductor ampacity using appropriate adjustment and correction factors Calculate voltage drop and verify system operation within acceptable limits Examine requirements for PV system labeling Calculate the maximum and minimum number of modules per PV source circuit, and number of PV source circuits per inverter Determine size of residential grid-direct PV system based on site and customer-specific considerations including the number and wiring layout of modules, conductor and OCPD sizes, and the AC interconnections Determine the size of a large, multiple inverter, grid-direct PV system based on site and customer-specific considerations, including the quantity and layout of modules and inverters and the AC interconnection Define large-scale PV and review associated NEC® allowances and requirements Describe importance of Data Acquisition Systems (DAS) Identify common DAS equipment and hardware Review DAS design, installation, and commissioning processes and common problems associated with DAS Show how reports can be generated and utilized to remotely assess health of system

Students who complete PV203 will be able to: Recognize demand and PV production curves Identify the common types of PV systems and their major components Describe DC and AC coupled systems Discuss load profiles and modes of operation, including: peak load shaving, time-of-use, zero-sell, self-consumption prioritization, demand-side management Introduce utility-scale storage and microgrids Explain the relationship between real power, apparent power, and reactive power Complete a load estimate for different system types and for seasonal loads; evaluate electrical requirements of loads Identify phantom loads and efficiency upgrades Estimate starting surge and power factor requirements Describe the differences when sizing battery-based systems compared to grid-direct systems Choose a peak sun hour value based on design criteria for various systems Review battery basics and terminology Describe and compare different battery chemistries and technologies Find the capacity and voltage of different batteries; determine state of charge List safety precautions and hazards to be aware of when working with batteries; list appropriate personal protective equipment (PPE) Identify appropriate battery enclosures Calculate values for current, voltage, and energy for different battery bank configurations Review battery bank design parameters Complete a lithium-ion battery bank design example Review and compare different design example costs List features, options, and metering available for different types of battery chargers Explain basics of lithium battery charging Compare generator types and duty cycle ratings, including fuel options Identify specifications critical for choosing appropriate battery-based inverters Discuss different overcurrent protection devices and equipment disconnects and when/where they are required Define the maximum voltage drop slowed for the proper functioning of a battery-based PV system Identify safe installation procedures List basic commissioning tests which should be completed before and after a system is operating

Multimode system configurations Load analysis and battery bank sizing PV array sizing Specifying multimode inverters Advanced multimode functions Code compliance, best practices, and installation considerations Charge controllers for multimode systems DC coupled multimode battery backup design example AC coupled system design considerations AC coupled multimode battery backup design example Energy Storage Systems (ESS) overview ESS residential sizing example Large-scale multimode system design and use cases   Note: SEI recommends working closely with a qualified person and/or taking PV 202 for more information on conductor sizing, electrical panel specification, and grounding systems. These topics will part of this course, but they are not the focus.

Stand-alone system configurations Charge controller and array considerations RV system design example DC lighting system design example Clinic system design example Code compliance and best practices for stand-alone systems Advanced battery-based inverters Generator sizing DC coupled stand-alone residential system design example AC coupled stand-alone microgrid system design example Large-scale microgrid considerations and case studies Flooded battery maintenance considerations Stand-alone PV system commissioning and maintenance Note: SEI recommends working closely with a qualified person and/or taking PV 202 for more information on conductor sizing, electrical panel specification, and grounding systems. These topics will part of this course, but they are not the focus.

https://www.transmedia.co.uk/course/ai-image-generation-using-firefly

The Institution of Occupational Health and Safety (IOSH) is a globally respected chartered body that champions the highest workplace standards of health and safety.  Safehouse are proud to offer training of the IOSH Managing Safely course. This training programme is designed for any individual who has organisational responsibilities for managing health and safety risks, resources and workplace practices. Once complete, it provides an excellent foundation for further study for those looking to pursue a career in health and safety and gain qualifications accredited by the National Examination Board in Occupational Safety and Health (NEBOSH) or NVQ Course Programme and Duration The IOSH Managing Safely course takes three full days to complete and covers, in detail, the core responsibilities of anyone tasked with managing workplace health and safety. Those responsibilities are covered in seven distinct units of study: Unit 1: Introducing managing safely Unit 2: Assessing risks Unit 3: Controlling risks Unit 4: Understanding responsibilities Unit 5: Understanding hazards Unit 6: Investigating incidents Unit 7: Measuring Performance To help prepare candidates for end-of-course examinations, daily interactive homework assignments and quizzes will also be set by the tutor. Certification In order to successfully complete the course and gain IOSH certification, delegates must complete a 45-minute examination to assess their learning and carry out a practical assessment to demonstrate the application of knowledge gained. Location At our Barnsley based training centre, with free parking on site bistro, free wifi and a great learning environment. Easily accessible from Junction 36 and 37 of the M1. Course Costs Course fees include expert tuition, course materials, examinations and certification. Costs are £395.00 plus VAT with discounts available for multiple booking / delegates.

This IMI qualification is designed for those personnel who in the course of their daily work may encounter damaged electric/hybrid vehicles. It contains the knowledge required to work safely around the electric/hybrid vehicles high and low voltage electrical system and electric drive train systems. On completing this qualification those personnel will have gained knowledge of both low and high voltage technologies and an understanding of their dangers. The content of this qualification has been designed to give learners the knowledge and skills required to work safely around Electric/Hybrid vehicles during emergency and recovery situations.