Earthing Calculation Software Free Download

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Earthing Calculation software, free download Windows 7
Earthing Calculation software, free download
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The CYMGRD software is a substation grounding grid design and analysis program specially developed to help engineers optimize the design of new grids and reinforce existing grids, of any shape, by virtue of easy to use, built-in danger point evaluation facilities.
User-friendly data entry, efficient analysis algorithms and powerful graphical facilities make the CYMGRD software an efficient tool that helps the engineer arrive at technically sound and economical designs.

Program Features

The use of the CYMGRD software allows for the rapid analysis of various design alternatives to choose an economical solution for any particular installation.
The program conforms to IEEE 80™ 2000, IEEE 81™ 1983 and IEEE 837™ 2002.

Analytical Capabilities

Finite element analysis of the ground grid conductors and rods
Computation of the station ground resistance (Rg) and the Ground Potential Rise (GPR)
Touch and surface potential analysis, inside and outside the grid perimeter, with color display in 2D or 3D representation
Step voltage analysis
Uniform or two-layer soil model from field measurements or user-defined values
Computation of reduction factor (Cs)
Library of the most common types of surface layer materials
Library of typical station soil resistivity values
Safety assessment calculations for maximum permissible touch and step voltages as per IEEE 80™ 2000
Current Split Factor (SF) estimated from substation configuration data as per IEEE 80™ 2000
Computation of the Decrement Factor (DF) from bus (X/R) ratio and shock duration data as per IEEE 80™ 2000
DC component of asymmetrical fault current taken into account in the computations
Electrode analysis for the optimal sizing of conductors and rods based on the most common type of electrode material as per IEEE Std. 80-2000 and Std. 837-2002
Supports symmetrical or asymmetrical grids of any shape
Arbitrarily located ground rods
Ability to model return electrodes and distinct electrodes
Ability to model concrete encased rods
Computation of maximum single phase to ground fault current for a specified grid

The CYMGRD/AutoCAD® Interface module

The CYMGRD / AutoCAD® Interface module allows the user to alternate between the AutoCAD® and the CYMGRD environments.
This utility is not a substitute for AutoCAD®. In fact, AutoCAD® remains a firm software requirement for CADGRD, because it is AutoCAD® that will produce the necessary *.DXF or *.DWG file(s) that contain the pictorial description of the substation grid layout realized with the CYMGRD software.

Simulation Results Management

The charts functionality allows:

Graphical comparison of deduced soil model with field measurements, for model acceptance
Color-coding of the surface potential gradients based on user-defined thresholds for touch or surface potentials. Any area of the grid can be selected with the mouse for detailed calculations and danger point evaluation
Equipotential contours for surface potentials in either 2-D or 3-D plots, with facilities to examine the graphs from any desired viewing angle
Graphics of touch and step voltage variation along any straight line, with comparison to the safe values computed by the safety assessment module
Graphic indications on the 2-D grid layout of the area being analyzed for touch and step voltages, for easy identification of hazardous locations

Earthing Calculations regarding your safety – you’re overdue an update!

If 1-ohm is still in circulation on your documentation then this section applies to you.

Easy to use and accurate multilayer earthing design software for electrical engineers. Calculate grid resistance, GPR, touch and step voltages, lightning protection design for substations, power plants, solar and wind farms. SafeGrid is a world-leading earthing design package and an economical alternative to XGSLab and CDEGS. Complies with international IEEE, IEC and EN electrical safety.
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Even though the Earthing Calculations for determining a safe System Earth (Ground) has shifted away from an arbitrary resistance figure, usually <1 ohm. It’s still all too common to see this outdated measure of installed success appear on client/employer requirement specifications(ER’s). As part of the Earthing Calculations Design Safety brief.

IEC based EN 50522 Earthing of power installations exceeding 1 kV a.c. implemented in 2010. And supersedes BS 7354 (1990) code of practice for the design of high-voltage open-terminal stations. BS 7430 Earthing Protection, was similarly updated in 2011.

Probabilistic Approach

The first really big step-change is the recognition that electrical system safety is probabilistic in nature.

What do I mean?

For many years, engineers have used a deterministic approach to allowable step and touch voltages. Therefore, based on recognised international standards such as IEEE-80 / BS 7354 / BS 7430. However, the weakness with the ‘deterministic’ approach was that a constant safety criterion was applied across all sites. That’s, regardless of the physical context of that site. For example, an industrial site has very different safety context to a school or swimming pool. Which may have children with bare feet and possibly wet bodies.

Or, another example is a T&D (transmission & distribution) manned substation in the middle of an urban setting may have very different risk characteristics compared to an unmanned DNO (distribution network operator) substation. In a remote hard to reach rural setting.

This is where the ‘Probabilistic’ approach, using well-understood risk management procedures to assess individual site risks (likelihood and consequence) have been introduced. This approach considers the fibrillation risk (from the step or touch voltage) and the coincidence risk (from the fault frequency and circulation of people on or near the site). Thanks to Charles Dalziel’s work, a target fatality/survivability factor is provided (IEC 60479-1) which is relative to various societal risks within a general population.

Earthing Calculations for Safety – Applied Research

The societal risks mentioned above relate to a typical population of the ‘general public’. The population is made up of people with a massive array of physical (and mental) variables. From gender, age, size, shape, BMI levels, mental endurance, etc. Some of the population sampled may carry a range of additional medical conditions, which could increase their susceptibility to a body current/stress voltage.

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The latest standards attempt to take this survivability factor into account. There are subtle differences between the IEEE and IEC standards when it comes to the calculation of body current. But in all cases, it’s important to understand, that in this context ‘probability’ means that not everyone is predicted to survive. The design question then follows for compliant safety calculations.

What survival rate do your Safety Earthing Calculations allow for?

Accepting that statistically, it is not reasonably practicable to design for 100% survival. What do you consider to be an ‘acceptable’ casualty number (deaths)? 5%… 30%… 50%?

It’s a sobering thought. Even taking on board the highest survival rate for your Earthing arrangement. For ease of Safety Calculations, if a facility has 100 people passing through it or nearby it. Statistically, the probability is that for a compliant design at least 5 of those 100 people may not make it home. Indeed, some of the initial survivor’s injuries may have life-shortening and/or life-changing consequences that do not appear in the initial mortality figure! And this assumes a scenario where the Earthing is considered ‘safety compliant’, technically secure and in good condition. Imagine what the casualty number might be for a non-compliant design?

Safety Earthing Calculations – Ignorance is bliss

Electrical Power System related faults and surges are known to occur frequently across networks. Whether switching, lightning or a fault/failure. Rise of Earth Potential events are a reality and their frequency is being measured and monitored by responsible operators. Usually, a well-designed Earthing/grounding system means an EPR (earth potential rise) event passes unnoticed. This can foster a false sense of security to the point of contempt. But make no mistake, the risk is very real and the consequences of a poor or insufficient design can be absolute.

It’s only recently within the past decade or so, that Earthing Risk is firmly back on the safety agenda as advances in technology, such as the visual software tools, make understanding the risk easier to identify across multiple disciplines, not just for the benefit of the Electrical Engineer.

Safe Earthing Calculations Automation

Technology-based automation is entering into many facets of our day-to-day life. For example, from driverless cars to the wifi-enabled expresso coffee maker in our office. The latest Safety Calculations for Earthing grounding design is no different.

Earthing Calculation software, free download Windows 7

EN 50522 – Earthing above 1kV recognises the scale, extent and complexity of Earthing safety calculations exceed what most reasonable engineers would attempt by manual calculation. And any manual calculation involves using simplified equations (at best) which can lead to inaccurate scenario safety calculation and therefore insufficient design with all the consequences (risk) mentioned above.

Earthing Calculation software, free download

The most recent updates in the standards recognise the advances in FEA (finite element analysis) software tools and their contribution to a better-understood and a safer world. FEA tools run by competent engineers, like CDEGS, allow vast amounts of data to be processed in safety computations, which, without a limitless reserve of cash, in many cases were previously un-studiedly.

A Cautionary note – Bill Gates (founder of Microsoft) better understood that Technology was not going to be the ‘silver bullet’ to all ourproblems when he said:

The first rule of any technology used in a business is that automation applied to an efficient operation will magnify the efficiency. The second is that automation applied to an inefficient operation will magnify the inefficiency. (Bill Gates)

Earthing Calculation software, free download Pdf

The automation of Safety Calculations relies on technically secure ‘inputs’ AND the competency level of those using it. Bill Gates understood the limitations of his software. It is always advisable that you check the limitations of yours (see this article for a comparison) together with the skillset of those who are using it.

So, in summary. The standards have changed and been in force for a number of years and the old 1-ohm rule has gone! If you have this requirement referenced in one of your own Employer’s Requirements file. It’s time to update.

The King is dead, long live the King! (wikipedia)

The 1-ohm rule might be dead but its successor most definitely is not. As a top 1% accredited specialist earthing consultant, GreyMatters is always happy to assist with policy development including Employer’s Requirement specifications.

Greymatter’s has expertise in a wide variety of Electrical Earthing System Services use the chat window below or, Contact Us here.