1365 Installation courses

Learners will be introduced to EAS as part of the fire safety solution for tall residential properties. This CPD course provides learners with an understanding of the requirements of BS 5839-1 in relation to, design, installation, commissioning, and maintenance of EAS.

Duration 5 Days 30 CPD hours This course is intended for The CCSP is ideal for IT and information security leaders responsible for applying best practices to cloud security architecture, design, operations and service orchestration. Overview Upon completing this course, the participants will gain valuable knowledge and skills including the ability to: - Successfully pass the CCSP exam. - Understand the fundamentals of the cloud computing architecture framework. - Understand security challenges associated with different types of cloud services. - Identify and evaluate security risks for their organization?s cloud environments. - Select and implement appropriate controls to ensure secure implementation of cloud services. - Thoroughly understand the 6 essential core domains of the CCSP common body of knowledge: 1. Architectural Concepts & Design Requirements 2. Cloud Data Security 3. Cloud Platform & Infrastructure Security 4. Cloud Application Security 5. Operations 6. Legal & Compliance The goal of the course is to prepare professionals for the challenging CCSP exam by covering the objectives of the exam based on the six domains as defined in the (ISC)2 CCSP common body of knowledge. 1 - Architectural Concepts and Design Requirements Cloud Computing Concepts Cloud Reference Architecture Cloud Computing Security Concepts Design Principles of Secure Cloud Computing Trusted Cloud Services 2 - Cloud Data Security CSA (Cloud Security Alliance) Cloud Data Lifecycle Cloud Data Storage Architectures Data Security Strategies Data Discovery and Classification Technologies Protecting Privacy and PII (Personally Identifiable Information) Data Rights Management Data Retention, Deletion, and Archiving Policies Auditability, Traceability, and Accountability of Data Events 3 - Cloud Platform and Infrastructure Security Cloud Infrastructure Components Cloud Infrastructure Risks Designing and Planning Security Controls Disaster Recovery and Business Continuity Management 4 - Cloud Application Security The Need for Security Awareness and Training in application Security Cloud Software Assurance and Validation Verified Secure Software SDLC (Software Development Life Cycle) Process Secure SDLC Specifics of Cloud Application Architecture Secure IAM (Identity and Access Management) Solutions 5 - Operations Planning Process for the Data Center Design Installation and Configuration of Physical Infrastructure for Cloud Environment Running Physical Infrastructure for Cloud Environment Managing Physical Infrastructure for Cloud Environment Installation and Configuration of Logical Infrastructure for Cloud Environment Running Logical Infrastructure for Cloud Environment Managing Logical Infrastructure for Cloud Environment Compliance with Regulations and Controls Risk Assessment for Logical and Physical Infrastructure Collection, Acquisition, and Preservation of Digital Evidence Managing Communication with Stakeholders 6 - Legal and Compliance Legal Requirements and Unique Risks within the Cloud Environment Relevant Privacy and PII Laws and Regulations Audit Process, Methodologies, and Required Adaptions for a Cloud Environment Implications of Cloud to Enterprise Risk Management Outsourcing and Cloud Contract Design Vendor Management

At the end of the 5 days, Learners will attain an RQF Award in the requirements of FD&FA systems for non-domestic buildings BS 5839-1: 2017.

Helpful tools and products used in the solar industry Residential installation tips Commercial solar installation examples Transformerless inverter installations Grid-tie with battery backup design and installation Off-grid design considerations Load side taps Grounding Ballasted roof top system design Ground mount design Custom racking Wiring methods New technologies Battery box construction

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 PVOL202 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

Get to grips with the installation and configuration of a domain controller, Active Directory, DNS, and Web Server (IIS)

Delegates will develop knowledge of the requirements for the design, installation and commissioning of Fire Detection and Fire Alarm systems within domestic properties in compliance with the requirements of BS 5839-6 and other codes of practice.

The NVQ Level 3 is designed to provide both new entrants and those seeking progression in their career, with the opportunity to develop the necessary skills to carry out job roles and responsibilities associated with the installation and maintenance of Electrotechnical systems. The EWR is for electricians who have been working in the industry for at least 5 years but have not formally completed an industry apprenticeship or Level 3 NVQ qualification. Successful completion of the NVQ and AM2 assessment will satisfy the entry criteria for JIB accredited Gold Card status. Bear in mind that the C&G 2391-50 and 18th Edition courses are pre-requisites to the Experienced Worker route. In case you don’t hold them, we can help you with a Pre-Experienced Worker Route package.

Duration 2 Days 12 CPD hours This course is intended for The primary audience for this course is any IT, facilities or data centre professional, consultant and/or those who work in network cabling system design, implementation and operation. Overview With few exceptions, enterprises today rely on IT for the delivery of business-critical services - often directly to the end consumer. It is therefore vital that the mission-critical data centre is designed, maintained and operated with high-availability and efficiency in mind. Among all the facilities, network cabling is the foundation for the network and one of the major contributors to the availability of the data center.CNCDP© is a 2-day course designed to expose participants to in-depth knowledge in designing and installing the data network cabling system which includes key subject matters such as; technical standards, designing of different cabling sub-systems, calculation of material requirements, architecture, installation, testing and acceptance. Introduction to Structured Cabling System (SCS) Brief history of SCS Basic copper and fibre transmission Copper and fibre cabling Single and multimode fibre Step/graded index multimode fibre Difference between Commercial Wiring and data centre cabling Development of standards Role of standards ANSI/TIA 568 standard Common standards The new usage of cabling to support Smart building Horizontal and Administration - Commercial Building Standard diagram recap: ANSI/TIA-568 Functional elements and example Scenario A: Determine the number of work areas Scenario B: Determine the number of user locations Zone wiring Administration: Interconnect and cross-connect Angled and flat panels Creating a cabling schematic design Convert schematic into physical layout Calculating the material list Horizontal and Administration - Data Centre Standard diagram recap: TIA-942 Basic/Reduced/Typical data centre setup Traditional 3 layers network design/ Spine and Leaf network design Select termination hardware Administration design ToR/EoR/Spine & Leaf cabling design Network and cabling resiliency Create cabling schematic design for ToR/EoR Convert into patch panel/rack layout Calculate the material list for ToR/EoR Building Backbone - Commercial Building Backbone diagram Calculate the copper backbone requirements per Telecom Room (TR) Calculate the fibre backbone requirements per Telecom Room Summarize the building backbone requirements Recognised cables Backbone Patch panels The maximum backbone distances Create cabling schematic design Converting the schematic design into patch panel/ rack layout Building Backbone - Data Centre TIA-942 based backbone topology TIA-942 backbone requirements Recognised backbone cable ToR/EoR/Spine and Leaf Backbone distance estimation Resiliency of backbone cable routes Creating cabling schematic design Converting the schematic design into patch panel/ rack layout Field and Fusion Termination for fibre connectors Pre-terminated fibre trunk and copper cables Architectural Considerations ANSI/TIA569-D Cable pathway and spaces Common requirements for the rooms Definition of the rooms Entrance Room/Demarcation Ceiling and floor pathways types Cable trays/basket/ladder/conduit Inner duct/sleeve/slot Calculating of pathway size Cable run best practices Cable management/AIM Grounding and bonding Separation distance requirements for copper cabling to power cabling Fire stopping Fire rated barrier Fire rated jacket cable Campus / Outdoor Backbone Common campus cable installation and cable types : Aerial cable / Direct-buried / Underground in-conduit Outdoor cable installation planning Lightning / surge protection Approved ground for surge protector Creating a schematic diagram Converting a schematic into a physical layout Site Inspection and Testing Visual site inspection notes Installation common issues Copper testing standard Permanent link / Channel / Patch cord / MPTL testing configuration Fibre connectors Fibre testing standard Tier 1 & 2 certification Fibre link definition Fibre testing steps Fibre inspection and cleaning Calibrating the test sets - 3 methods Setting up mandrel for testing Fibre loss budget calculation G.657 Bend insensitive fibre Optical Time-Domain Reflectometer (OTDR) Exam - Certified Network Cabling Design Professional (CNCDP©) The exam is a 60-minute closed book exam, with 40 multiple-choice questions. The candidate requires a minimum of 27 correct answers to pass the exam. Additional course details: Nexus Humans Certified Network Cabling Design Professional (CNCDP) training program is a workshop that presents an invigorating mix of sessions, lessons, and masterclasses meticulously crafted to propel your learning expedition forward. This immersive bootcamp-style experience boasts interactive lectures, hands-on labs, and collaborative hackathons, all strategically designed to fortify fundamental concepts. Guided by seasoned coaches, each session offers priceless insights and practical skills crucial for honing your expertise. Whether you're stepping into the realm of professional skills or a seasoned professional, this comprehensive course ensures you're equipped with the knowledge and prowess necessary for success. While we feel this is the best course for the Certified Network Cabling Design Professional (CNCDP) course and one of our Top 10 we encourage you to read the course outline to make sure it is the right content for you. Additionally, private sessions, closed classes or dedicated events are available both live online and at our training centres in Dublin and London, as well as at your offices anywhere in the UK, Ireland or across EMEA.