OPR Designer software What does OPR Designer deliver? ABB’s OPR designer software has been developed to simplify lightning protection system design (especially for ESE solutions). This software is ideal for consultants and contractors working in the field of lightning protection, as it has been designed to deliver the optimal, flexible solution for ESE lightning protection in the shortest time possible. The solution delivered determines the type and location of air terminals on a structure, as well as provides a detailed list of the installation accessories, fixings and earthing components needed. Implementation of a lightning protection system including free-standing pylons on site is also feasible. Bills of quantity related to each lightning protection system design are accessible at any time in the software, and can also be exported to Excel file.
Product packing details are also included. Additionally, the software permits the generation of a complete design and bill of quantity in PDF format considering the entirety of the project, including: • Air terminal positioning on the imported plan with defined protection radius (a plan may be imported from a picture, PDF, Autocad file or even a Google earth view); • Comprehensive and detailed list of materials; • Catalog pages for products used in the lightning protection system design; • Test certificates for the ESE air terminals Download the.
The most powerful and accurate suite of commercially available grounding (earthing) and electromagnetic analysis software packages on the market. A complete array of auxiliary software tools are included in the CDEGS suite to complement, support and enhance the methods used to solve various problems involving grounding, electromagnetic interference, electromagnetic fields and transient phenomena that can be tackled by CDEGS. Description CDEGS ( Current Distribution, Electromagnetic Interference, Grounding and Soil Structure Analysis) is a powerful set of integrated software tools designed to accurately analyze a variety of electromagnetic related problems encountered in all industries involving electric networks. A variety of advanced solvers provide adapted approaches to your problems • Direct solutions of Maxwell’s equations. • Circuit-based analyses.
• Finite element methods. • Inversion algorithms. • Fast Fourier transforms and transient analysis. • Hybrid methods. • Stunning graphics.
Earth Mat is preferable to large substations because of space saving on the ground level due to substantial reduction. This paper presents the design of earthing systems for the 132/33Kv substation in Rivers state of Nigeria. Join for free. Download full-text PDF. Computer software packages can be used to assist in. GSA (GROUNDING SYSTEM ANALYSIS) for regular application (applicable in. A widely utilized and recognized module for earth grid calculations and design.
Includes all electromagnetic coupling modes • Conduction, through metallic elements, coatings and the earth itself. • Magnetic induction. • Capacitive effects. Modeling elements • Complex soil structures such as the multi-region, horizontally layered soil with an arbitrary number of layers and resistivities and single-regions consisting of cylindrical, hemispherical, hemispheroidal, inclined, vertical and horizontal layers.
Finally, horizontal multilayer soils that can include embedded finite soil volumes with arbitrary resistivities are available to help you tackle the most challenging project. • Conductors and pipes, physical dimensions and electromagnetic properties. 
• Metallic Plates. • Multi-component concentric cables and cables contained in an enclosure. • Perfect “virtual” connections.
• Circuit components and Transformers. • Arbitrary sources and signals including those emitted by remote sources such as solar magnetic storms. With CDEGS, you • Avoid simplifying assumptions and model any system realistically.
• Compute currents flowing in arbitrary networks of conductors, and their associated electric fields, magnetic fields and scalar potentials. • Take into account the electrical complexity of soil structures. • Accurately calculate line parameters of arbitrary 3D networks. • Determine realistic current distributions between all metallic paths connected to electric networks subjected to various fault scenarios. • Accurately interpret soil resistivity measurements and Fall-of-Potential tests. • Calculate potential distributions, electric and magnetic fields anywhere above or below ground. • Evaluate GPR, touch and step voltages, coating stresses and leakage current densities.