Administrative Losses

The figure below presents the administrative loss percent of each electric cooperative considering the number of employees for each cooperative.

In this post, I consider the administrative loss to be proportional to the number of employees.

In this terms, the more employees, the more electricity usage within their facilities. So less usage means less employees working for the cooperative. The efficient electric cooperative would have less administrative loss given more employees.

With this premise, Tarlac I looks like an efficient operated cooperative since it has more employees yet they incur less power losses for their facilities. On the other hand, Davao Sur has less employees but has spent more administrative losses.

Philippine Electric Cooperatives' System Loss

The following figure presents the system loss in percent of all electric cooperatives in the Philippines. Data came from the NEA website.

 

The average system loss throughout the five year period is about 15%. The median system loss is around 14%. This is not bad for the NEA, though some cooperative suffer with significant power losses in their distribution system as seen from the figure above.  It is notable that high system loss are found in Mindanao, Central Luzon, Bicol and parts of Visayas.

Citations

Here is a list of citations I got from Google search on my technical work:

1. Utilizing Fuzzy Optimization for Distributed Generation Allocation, TENCON 2007 - 2007 IEEE Region 10 Conference, Oct. 30, 2007-Nov. 2, 2007, Taipei, Taiwan – on-line: http://www.ieeexplore.ieee.org/xpl/freeabs_all.jsp?isnumber=4428770&arnumber=4428814&count=405&index=43 in ”Incorporating Distributed Generation into Distribution Network Planning: The Challenges and Opportunities for Distribution Network Operators”, David Tse-Chi Wang, Doctor of Philosophy (PhD) Thesis, The University of Edinburgh, 2010– on-line: http://www.era.lib.ed.ac.uk/bitstream/1842/4621/2/Wang2010.pdf
2. Utilizing Fuzzy Optimization for Distributed Generation Allocation, TENCON 2007 - 2007 IEEE Region 10 Conference, Oct. 30, 2007-Nov. 2, 2007, Taipei, Taiwan – on-line: http://www.ieeexplore.ieee.org/xpl/freeabs_all.jsp?isnumber=4428770&arnumber=4428814&count=405&index=43 in ”Optimum Distribution Generator Placement in Power Distribution System Using Ant Colony Algorithm” by Ghazanfar Shahgholiyan, MohamadAmin Heidari, Mehdi Mahdavi, Majlesi Journal of Electrical Engineering, Volum 3, Number 1, March 2009 – on-line: http://ee.majlesi.info/index/index.php/ee/article/view/184
3. Solving Non-Technical Losses Problem by Technical Methods, Elektrisidad Pilipinas, September 2008, - on -line: http://elektrisidadpilipinas.blogspot.com/2008/09/solving-non-technical-losses-problem-by.html in “Analysis of Non-Technical Losses and its Economic Consequences on Power System” , Master of Engineering Thesis by Tejinder Singh, Thapar University, Patiala, India, June 2009 – on-line: http://dspace.thapar.edu:8080/dspace/bitstream/10266/911/1/Tejinder_PSED.pdf
4. Analysis of Voltage Unbalance Regulation, October 27, 2006, Annual National Convention of Institute of Integrated Electrical Engineers (IIEE), PICC, Manila, Philippines in “On the Assessment of Voltage Unbalance”, Seiphetlho,T.E.;Rens,A.P.J.; Sch. for Electr., Electron. & Comput. Eng., North West Univ., Potchefstroom, South Africa, 2010 14^th International Conference on Harmonics and Quality of Power – on-line: http://ieeexplore.ieee.org/xpl/freeabs_all.jsp?arnumber=5625366
5. Luzon Approximate Network Model, Elektrisidad Pilipinas, July 2010, - on -line: http://elektrisidadpilipinas.blogspot.com/2010/07/luzon-approximate-network-model.htmlThe High Cost of Electricity”, The Philippine On Line Chronicles, July 2010 – on-line: http://thepoc.net/commentaries/8970-the-high-cost-of-electricity.html in “

Note that numbers 3 and 5 are post entries in this blog. Number 4 is a technical paper presented in an Institute of Integrated Electrical Engineers (IIEE). 

Why I posted this? Simple. Any good idea when put out for the public can be a resource for others. 

Framework for Reliability Evaluation of the Smart Grid

Massive deployment of information and communication infrastructure in operating, monitoring and control of electric power systems. This is Smart Grid. This is the vision of a controllable, observable and self-healing power system using smart grid technologies. Communication technologies like fiber hybrid and broadband over power line will enable the data and signal transfer from smart meters, automation and control sensing devices, high end system control centers interfaces in a highly visual environment, and intelligent electronic devices (IEDs). Sensing and measurement devices will be employed for which information data flow are aimed for facilitating wide-area control and protection (WACP) at the bulk power systems and dynamic control and automation at the distribution level, and other applications such as remedial action schemes, substation equipment monitoring and dynamic line rating.

Please see full article here - Framework for Reliability Evaluation of the Smart Grid.   

IIEE's Plagiarism

If you think MVP and the Supreme Court are on fire recently with plagiarism issues, then after reading this blog you may think otherwise.

The Institute of Integrated Electrical Engineers (IIEE) in the Philippines publishes a magazine quarterly, The Electrical Engineer. Copies of the issues are provided with hard copies to residences of members and soft copies at their website. Of course, I am a member of IIEE that's why I get copies on-line. I have called the attention of IIEE Technical Department on this but I can't understand why they keep on repeating this ethical mistake.

Below are tables of comparison I made, from where IIEE technical authors might have sourced their technical articles. I ranked them for fun but the issue is not.

Honorable Mention

GE Tech Note	IIEE Article
http://www.geindustrial.com/publibrary/checkout/GET-8057?TNR=White%20Papers|GET-8057|generic	http://www.iiee.org.ph/home/uploads/SYSTEM%20RELIABILITY.pdf
Control Error – Loss of control power results in the inability to control the process. This may well be the most pervasive voltage interruption problem, especially among commercial users. Contactor Dropout – Many industrial controls employ magnetically-latched contactors as motor control devices. A voltage sip or sag can cause a momentary collapse of the magnetic field which holds the contacts closed. When the contacts open, the motor stops. Voltage Flicker – In the strictest sense, flicker is the repetitive variation in intensity of lighting, and is more of a human irritation factor than a direct cause of process disruption. However, it can also be used in a more literal sense to describe a set of problems in which lighting is extinguished due to voltage dips. Machine Dynamics – Since voltage magnitude is essential to transmitting power, voltage dips and sags limit the ability of a power system to distribute power from sources to loads. This limitation in power transfer can lead to generators not being able to maintain stability.  Stall and Reacceleration – Motors will stall if the supply voltage is depressed for a prolonged period. This may be a problem if the motor is not properly protected. Furthermore, motors must reaccelerate when normal voltage is restored. Reacceleration involves higher than normal motor currents which may result in further voltage sag problems.	Control Error – Loss of control power results in the inability to control the process. Contactor Dropout – Many industrial controls employ magnetically-latched contactors as motor control devices. A voltage dip or sag can cause a momentary collapse of the magnetic field which holds the contacts closed. When the contacts open, the motor stops. Voltage Flicker – In the practical sense, flicker is the repetitive variation in intensity of lighting, and is more of a human irritation factor (threshold of perception, or threshold of human objection) than a direct cause of process disruption. However, it can also be used in a more literal sense to describe a set of problems in which lighting is extinguished due to voltage dips. Machine Dynamics – Since voltage magnitude is essential to transmitting power, voltage dips and sags limit the ability of a power system to distribute power from sources to loads. This limitation in power transfer can lead to generators not being able to maintain stability. Stall & Re-Acceleration – Motors will stall if the supply voltage is depressed for a prolonged period. Furthermore, motors must reaccelerate when normal voltage is restored. Reacceleration involves higher than normal motor currents which may result in further voltage sag problems.
Voltage sag is a partial reduction in the magnitude of voltage that often persists for extended periods and is usually related to system loading conditions Voltage dip is a significant reduction in voltage for a relatively short duration, often caused by power system faults. Voltage interruption is a complete loss of input voltage, lasting from seconds to much longer.	Voltage Sag is a partial reduction in the magnitude of voltage that often persists for extended periods and is usually related to system loading conditions. Voltage Dip is a significant reduction in voltage for a relatively short duration, often caused by power system faults, or as frequently in events of large motor starts-up. Voltage Interruption is a complete loss of input voltage, lasting from seconds to a much longer time.
The actual economic justification for prevent production interruptions due to voltage disturbances must consider the following elements: 1. How vulnerable is the process to various types of voltage disturbances? 2. What is the net cost of production outages due to these disturbances? 3. How effective is a particular solution in avoiding these outages? 4. How does the cost of the solution compare to the savings which can be realized? There are several elements of cost associated with a voltage interruption that should be recognized and quantified in the economic evaluation. Cost of Lost Production – In the simplest case, this is the incremental margin on product that is not manufactured and therefore cannot be sold. Cost of Damaged Product – If the interruption damages a partially completed product, the cost of repairing that product must be recognized. In some cases, the product cannot be repaired, so the value of the raw materials (including the consumed energy up to the point where the disruption occurred) must be accounted for together with the cost of the incremental value added to the product. In the commercial arena, a major source of concern is lost computer data. Cost of Maintenance – The cost of reacting to a voltage disruption experience. This includes everything involved in restoring production, including diagnosing and correcting the problem, cleanup and repair, disposing of damaged product, and environmental costs. In some industries (e.g., plastics and electronics), an interruption for several hours may result in the need to invest many days and thousands of dollars in cleaning up the process system before it can be returned to service. Hidden Costs – This factor may be the most difficult to quantify but it can easily be the most significant. If the impact of the voltage dip or sag is control error, it is possible that the impact on product may not be apparent until the product is in the hands of the consumer. Product recall and/or public relations costs can be significant.	The actual economic justification in preventing production interruptions due to voltage disturbances must therefore consider the following elements: 1) How vulnerable is the process to various types of voltage disturbances? 2) What is the net cost of production outages due to these disturbances? 3) How effective is a particular solution in avoiding these outages? 4) How does the cost of the solution compare to the savings which can be realized? As to the cost associated with voltage interruptions the following elements should be recognized and quantified: Cost of Lost Production – In the simplest case, this is the incremental margin on products that cannot be sold because they are not manufactured. Cost of Damaged Product – If the interruption damages a partially completed product, the cost of repairing that product must be recognized. In some cases, the product cannot be repaired, so the value of the raw materials (including the consumed energy and other manufacturing costs up to the point where the disruption occurred) must be accounted for together with the cost of the incremental value added to the product. In other environments, a major source of concern is lost computer data. Cost of Maintenance – This is the cost of reacting to a voltage disruption. This includes everything involved in restoring production, including trouble-shooting and correcting the problem, cleanup and repair, disposing of damaged product, and environmental costs. In some industries (e.g., plastics, glass manufacturing, cement manufacturing, electronics, etc), an interruption may result in the need to invest many days and a significant amount of money in cleaning up the process system before it can be returned to service. Hidden Costs – This factor may be the most difficult to quantify but it can easily be the most significant. If the impact of the voltage dip or sag is control error, it is possible that the impact on product may not be apparent until the product is in the hands of the consumer. As business nightmare, product recall and the subsequent public relations costs can be significant or may even cause bankruptcies.

 Salutatorian

Pure Power Article	IIEE Article
Harmonics No More, PURE POWER // SUMMER 2009 - http://e-ditionsbyfry.com/Olive/ODE/PLE/default.aspx?href=PLE%2F2009%2F07%2F02&pageno=10&entity=Ar01000&view=entity	HANDLING HARMONICS…. BEFORE IT MISHANDLES YOUR SYSTEM, THE ELECTRICAL ENGINEER MAGAZINE 2ND QUARTER 2010, page 25 - http://www.iiee.org.ph/home/uploads/IIEEpub.pdf
Effects of voltage-wave distortion, however, are evident throughout the distribution system. This condition results when instantaneous current demand exceeds the distribution system’s ability to deliver power to the load.	Voltage-wave distortion, which is evident throughout the distribution system, results when instantaneous current demand exceeds the distribution system's ability to deliver power to the load.
Equipment with the potential for generating voltage-wave distortion includes UPS systems, VFDs, solid-state elevator drives, arc heating units, and other devices with very large, short term current demands.	Equipment with the potential for generating voltage-wave distortion includes UPS systems, VFDs, solid-state elevator drives, arc heating units, and spot welding machines.
There are two primary ways to eliminate voltage harmonics: by incorporating harmonic filters at selected locations, or by eliminating devices that produce voltage wave distortion by purchasing devices that produce lower levels of harmonics.	The two basic ways to eliminate voltage harmonics are: by harmonic filters placed at selected locations, and by eliminating devices that produce voltage-wave distortion by using devices that produce lower levels of harmonics.
Active filters incorporate microprocessors to eliminate harmonics by rapidly compensating for sine-wave deviations from ideal wave forms by inverting the harmonic distortion and reinserting it into the feeder to cancel the harmonics. These models can correct all harmonic magnitudes up to their maximum capability and can eliminate harmonics concerns in electrical-distribution design.	Active filters incorporate microprocessors to eliminate harmonics by rapidly compensating for sine-wave deviations from ideal wave forms by inverting the harmonic distortion and reinserting it into the feeder to cancel the harmonics These models can correct all harmonic magnitudes up to their maximum capability and can eliminate harmonics concerns in electrical-distribution design
SUMMARY Without careful design considerations, harmonics can cause expensive & damaging problems. As a result, each potential harmonic producer should be investigated to determine the frequency and level of harmonics so the appropriate type of filtering may be specified. Doubled neutral conductors and k-factor transformers should be used only as a last resort in existing installations to mitigate large triplen harmonic levels; and not as a routine procedure for every facility. Judicious use of harmonic filters for either a dedicated, device-specific application or on a group basis. Incorporating a single filter to handle a number of harmonic-producing loads, can be the most cost-effective way to limit harmonics in the distribution system.	A SYSTEMS APPROACH Without careful design considerations, harmonics can cause expensive, damaging problems. As a result, each potential harmonic producer should be investigated to determine the frequency and level of harmonics so the appropriate type of filtering may be specified. Doubled neutral conductors and k-factor transformers should be used only as a last resort in existing installations to mitigate large triplen harmonic levels, not as a routine procedure for every facility. Judicious use of harmonic filters for either a dedicated, device-specific application or on a group basis, incorporating a single filter to handle a number of harmonic producing loads, can be the most cost effective way to limit harmonics in the distribution system.

 Valedictorian

See word for word imitations by clicking title
Book	IIEE Article
Integrated Solutions for Energy & Facility Management By Association of Energy Engineers, Sioros/Assoc En, Donna Sioros	Specification Guidelines for Improving Immunity to Power Quality Defects, THE ELECTRICAL ENGINEER MAGAZINE October-December 2008, page 35- http://www.iiee.org.ph/home/uploads/IIEEoct_decISSUE.pdf

Electric Power Education Evaluation

When a credited agency evaluated my education credentials, my bachelor degree in electrical engineering was assessed as an equivalent of a US degree in electrical engineering. My Master of Engineering degree was not evaluated as an advanced degree above the undergraduate level, it was likewise assessed as another bachelor degree equivalent in the US.

Looking back, I went to that master’s program due to a requirement of the higher education agency in the Philippines which encourage college instructors to acquire advanced degrees. As wanting to fulfill a requirement, I enrolled where the program might be easy and might be cheap in terms of fees. So, after three years, I got the degree.

I wasn’t thinking of where I could use the advanced degree further. I did not envision going abroad and using the degree but perhaps I should have look at all angles.

Why? Almost the same effort will be poured into a degree that might be easy or relatively hard. When I was employed at TRANSCO, I decided to go to the state university for further studies. They admitted me for another master’s program but later I requested to be admitted in the PhD level which the department approved. As far as I can remember, the same effort I gave into the master’s studies was almost the same amount I gave to the PhD studies. As long as you got the theory, practice plus books and internet, you got the edge.

So here are my points.

For students planning to take advanced degree after your undergraduate level, enroll in an institution where they give you the advanced education you deserve. Do not go for mediocrity. Do not allow yourself to fulfill a requirement. Require yourself to advance. Look into the curriculum before you enroll; is it a replay of your BS or a notch higher than your BS? In any case, you will put effort. Better to put effort into what is worthy.  Compare the curriculum with US curriculums, are they parallel? No, I’m not saying you are going abroad, what I’m telling you is that you must know what a graduate student in the US must know. Be at par with the world.

For institutions offering advanced degrees, be sure to offer advanced degrees. Forward yourself by moving your student forward.  Do not give them what they already know. Do not teach them what they can teach you. Don’t let them do all the work in one semester and give them credit which is equivalent to what they have already achieved. You can do better by pushing your student to do better. If you are offering an electric power advanced degree, consider to offer the following:

·         Power System Stability

·         Power System Analysis

·         Power System Protection

·         Power System Reliability

·         Electricity Markets

·         Electricity Regulation and Laws

·         Information and Communication in Power Systems

·         Distribution System Analysis

·         Power System Operation and Control

·         Power System Planning

·         Power System Economics and Rates

No, I did not waste my time in my master’s degree. However, I believe I can do better. We can do better.

Application of N-1 Contingency Analysis

The Philippine Grid Code (PGC) regulates that transmission systems must be N-1 compliant. Any single component in outage must not result to any thermal overloading of lines, which means above 100% of MVA rating, and no voltage limits will be violated whether overvoltage or undervoltage. Voltage limits are 0.95 per-unit voltage and 1.05 per unit voltage.

In this post, we demonstrate how to apply this application to the Luzon Approximate Network model though we will focus only on the thermal loading of lines. I am assuming any voltage violations can be eliminated by transformer tap change or capacitor switching at the substations of power plant switchyards.

In Powerworld, there are two ways, I can think of, to do this. Open the case and manually switch of any branch then solve the case. Or use the automated way to apply contingency analysis.

Before we go further, here are initial evaluations needed to undergo: (1) no existing overloads in the pre-contingency, (2) no existing voltage violations, (3) generating machines are not over dispatched.

In the Philippines, the substation configuration is usually a breaker and a half arrangement. With this assumption, the single branch contingency or N-1 is adaptable. In other power systems abroad, there are design contingencies which will trip several lines, not only one branch, for an N-1 set-up. These contingencies are called design contingencies. Also, any bus (outage of 1 or more lines) or breaker fail (outage of one or more lines) contingency are not considered in the N-1 analysis at least in the Philippines.

Here are the steps for N-1 analysis:

1.    Open the case in Powerworld
2.    At Edit Mode or Run Mode, in Case Information palettes go to Limit Monitoring to check existing pre-contingency thermal overloads. Identify overloads at the column of % of Limit Used. Redispatch generation to correct pre-contingency overloads, if possible. If no pre-contingency overloads are present, proceed to N-1 analysis (Figure 1).

Figure 1.

3.    At Run Mode, go to Tools. Click on Contingency Analysis, a new window will open (Figure 2). In Contingencies, click Auto-Insert to create contingency to be applied to the power network. Another window will open then click Do Insert Contingencies, notice the options of contingency combinations (Figure 3).

Figure 2.

Figure 3.

4.    Program will ask you to confirm 92 contingencies to be created (Figure 4). Click Yes. This will create the contingencies and will input the contingencies in the window (Figure 5). Notice Status as Initialized.

Figure 4.

Figure 5.

5.    Click Start Run to begin N-1 contingency analysis.
6.    When the simulation is finished, at the left bottom of the window, there is a status update for the finished contingency calculations (Figure 6).

Figure 6.

Figure 7.

7.    To view results, click Combined Tables, then to Legacy Tables ' click Contingency Definition-Violation Table' Copy to Clipboard. When finished, paste in notepad or any MS Word type program. You can also view result per contingency when you click at any one of the contingency at the window (Figure 7).

If I am working on this I will analyze the results and even apply the contingency manually and observed the resulting overloads. This means, I don't depend on the software's results but "analyze" the results. Why do the overloads happen? What were the pre-contingency loadings at the overloaded elements? Why is the contingency credible enough to produced those thermal violations? If in operations planning horizon, what are the actions needed to mitigate the thermal overloads?

In doing N-1 analysis, don't let the power system engineer be an "N". Meaning, he must not let himself be taken away by the software and he must not depend fully on the software's results but he is to gain more understanding on the network when examining the results.