59279 Courses

Our 2023 online courses work in the same way that our classroom courses do, but they are completed via the online platform Zoom. The course can be completed on any device that the Zoom app can be used on, such as a PC, laptop, tablet or smart phone. As with our face to face driver CPC training, completion of this remote learning course will gain you 7 hours towards your CPC, per day, totalling 35 hours for the week. To book your place on the course, simply click on the link below, and complete the online booking form. These details will be used to produce a registration document and provide you with a course certificate on successful completion of the course. To book individual courses, please email with a copy of your driving licence and the course you would like to book to info@totalcompliance.co.uk Monday – Drivers Hours / Tachographs Tuesday – Vehicle Checks / Public Image Wednesday – Licence, weights & Dimensions / Security Thursday – Tiredness & Lifestyle / Economical Driving Friday – Vulnerable Road Users Course cost includes upload fee and VAT. £299 including VAT and DVSA upload fees of £8.75 per day.

HSE, First aid at work, EFAW, FAW,

Mandalas, in essence, can be understood to be diagrams, patterns and pictures that are distillations of cosmic wisdom and harmony; repositories of archetypal intelligence. Mandalas offer a potentially powerful means of deepening one’s spiritual and contemplative practice. This is especially true when they are constructed - using the traditional tools of compass and straightedge - in a considered and contemplative manner. During this week-long course, Daniel Docherty will guide participants through the construction of a number of mandalas from different traditions including mandalas that embody significant planetary patterns. We will explore their inherent symbolism and cosmic correspondences. Participants will also make their our own inks and paints from plant and mineral in order to colour and ensoul their designs. 

Celtic Pattern, Geometry and Imagination A five-day extended course with Adam Tetlow 25-29 October 2021 SAOG Studios (Ruskin East) Emerson College, Forest Row, East Sussex, RH18 5JX, UK 10:00-17:00   Cost: £335 

Students who complete PVOL203 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

Define multimode system terminology Describe goals and applications of multimode systems Detail basic component layouts of multimode systems Define microgrid systems and diagram component layouts for microgrid applications List applications for multimode systems Distinguish between back-up and self-consumption use cases Examine daily and annual data to perform a load analysis Review battery bank sizing Identify PV array sizing methods and variables for multimode systems Calculate minimum PV array size to meet load requirements Calculate what percentage of overall annual consumption will be offset by selected PV array size Analyze data required to specify a multimode inverter Differentiate between sizing considerations for internal and external AC connections Describe various configurations for stacking and clustering multiple inverters Describe when and why advanced inverter functions are used Discuss the equipment and designs needed for advanced multimode functions Analyze each advanced multimode function List data needed to perform an accurate financial analysis of systems that use advanced multimode functions Describe factors that can affect the financial analysis of systems using advanced multimode functions Describe the National Electrical Code (NEC®) Articles that apply to the different parts of PV and energy storage systems (ESS) Identify specific requirements for ESS and systems interconnected with a primary power source List relevant building & fire codes Communicate specific requirements for workspace clearances, disconnects, & OCPD Describe PV system requirements that affect ESS installation List ESS labeling requirements Review DC coupled systems, including advantages and disadvantages Discuss MPPT charge controller operations and options Review charge controller sizing for grid-tied systems Design a DC coupled multimode PV system for a residential application Define operating modes of an AC coupled PV system while grid-connected or in island mode Explain charge regulation methods of grid-direct inverter output Review AC coupled PV system design strategies Evaluate equipment options for AC coupled multimode applications Design an AC coupled multimode PV system for a residential application Define Energy Storage System (ESS) Describe criteria for evaluating energy storage system configurations and applications Design ESS system for back-up power Describe large-scale energy storage system applications and functions; review use case examples Analyze equipment configuration options for large-scale AC and DC coupled systems Formulate questions to enable design optimization of large-scale energy storage systems 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 be part of this course, but they are not the focus.

Define terms used in stand-alone systems Name common applications for stand-alone systems; describe basic component layouts Describe differences between AC and DC coupling State principle elements of a microgrid Define the importance of an accurate load analysis Review load analysis procedures; perform a load analysis based on daily data Review battery bank sizing for lead-acid and lithium-ion battery types Define array sizing variables and how they affect design for both MPPT and non-MPPT charge controllers Explain charge controller types and describe maximum power point tracking and voltage step-down Examine the calculations for PV array sizing Describe the difference between sizing for a non-MPPT and an MPPT charge controller Complete array configuration calculations for a system with a non-MPPT and an MPPT charge controller Summarize the parameters to check when selecting a charge controller Explain the purpose of DC load control and the three ways it can be implemented Identify design variables, advantages, and disadvantages of DC-only PV systems Describe how to size and integrate components for a recreational vehicle (RV) application Identify installation and maintenance considerations specific to mobile applications Identify applications and considerations for DC lighting systems Specify a battery-based inverter given electrical load and surge requirements Describe various configurations for stacking and clustering multiple inverters Examine inverter / charger size considerations Describe multiwire branch circuit wiring and concerns with single-phase supplies Describe the purpose and function of a generator Identify considerations that impact generator selection Solve for location-based performance degradation Specify a generator given electrical load, battery charging, and surge requirements Estimate approximate generator run time List generator maintenance Describe the National Electrical Code (NEC®) Articles that apply to the different parts of PV and energy storage systems (ESS) Identify NEC® requirements for workspace clearances, disconnects, and overcurrent protection devices (OCPD) that apply to PV systems Locate and apply specific requirements for storage batteries, stand-alone systems, and energy storage systems Identify labeling requirements List relevant building and fire codes Review installation considerations and best practices for stand-alone systems as related to batteries, design strategies, monitoring and metering, balance of system (BOS) equipment Review DC-coupled stand-alone residential system design Define operating modes of off-grid AC coupled PV systems Explain charge regulation of AC coupled PV inverters in a stand-alone system Discuss AC coupled PV system design strategies; evaluate equipment options for AC coupled off-grid applications Design a stand-alone microgrid system with PV (AC and DC coupled) and generator power sources Distinguish between isolated and non-isolated microgrids Compare concepts of centralized versus decentralized generation and controls Identify different types of microgrid analysis and planning software Review isolated microgrid use case examples Identify general PPE for battery system maintenance Develop a battery maintenance plan Identify methods to measure battery state of charge Identify common causes of battery problems and how to avoid them Identify PPE for lead-acid battery maintenance Develop a battery maintenance plan for lead-acid batteries Describe how to correctly add water to a flooded lead-acid (FLA) battery bank Identify methods to measure battery state of charge of FLA batteries Define when and why equalization is needed Identify common causes of battery problems and how to avoid them 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.

Discuss preventative and reactive maintenance plans and activities. Summarize safety procedures and PPE requirements for O&M technicians. Describe the field procedures required to evaluate the performance of PV systems. List appropriate requirements for meters, tools, and other equipment used in O&M activities. Define the theory, procedures, and processes behind insulation resistance testing, IV curve tracing, infrared cameras and thermal imaging, and other tools of the trade. Analyze test results to determine performance, compare baseline data, and pinpoint system issues. Describe inspection requirements for preventative maintenance inspections. Illustrate methods for locating and troubleshooting common PV array and system faults using appropriate methodologies and testing tools.

This comprehensive online interior design course includes 12 self study modules, and weekly 1:1 telephone and or video consultations. I will personally guide and inspire you through your creative learning journey.

Explore the Classic Sturmey Archer Hub Course with Vince Warner: private 1-to-1 tuition for mastering vintage bicycle hub mechanics.