tag:blogger.com,1999:blog-76213351630550537442024-03-08T06:44:29.223-08:00Engineering Seminar Topics | Electrical Engineering TechnologyThis is a blog developed to assist the people who are looking for the Seminar topics, especially the Electrical Seminar Topics. This Electrical site will give the reference in many other latest technical details of the Electrical Engineering field.This will provide the latest seminar topics, Electrical standards, Electrical news,electric news, electrical engineering news, electricity news, etc.Seminar Topicshttp://www.blogger.com/profile/01524755623435065211noreply@blogger.comBlogger23125tag:blogger.com,1999:blog-7621335163055053744.post-36021016029460990962012-07-20T04:54:00.000-07:002012-07-20T04:54:49.898-07:00Dynamic Voltage Restorer (DVR)<div dir="ltr" style="text-align: left;" trbidi="on">
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<span style="font-family: "Cambria","serif"; font-size: 12.0pt; line-height: 115%; mso-ascii-theme-font: major-latin; mso-hansi-theme-font: major-latin;">Voltage
variations are a nightmare for the industries like Semiconductor fabrication
plants, Paper mills, Food processing plants and, automotive assembly plants
etc. Fast variation in source voltage can affect the overall performance of the
industry and also cause damage to critical loads in these industries resulting
in great financial loss. The most common disturbances that occur in the source
voltage are voltage sags or swells that can be due to disturbances in the transmission
line or system, adjacent feeder faults and Fuse or breaker operation. Voltage
sags of even 10% lasting for 5-10 cycles can result in costly damage in
critical loads and heavy machineries in an industry. The voltage sags can be
symmetrical faults in which negative and zero sequence components are also
present.</span></div>
<div class="MsoNormal" style="text-align: justify; text-indent: 36.0pt;">
<span style="font-family: "Cambria","serif"; font-size: 12.0pt; line-height: 115%; mso-ascii-theme-font: major-latin; mso-hansi-theme-font: major-latin;">Presence of
uncompensated nonlinear loads in the distribution system can cause harmonic
components in the supply voltages which are extremely dangerous. To mitigate
the problems caused by poor quality of power supply, series connected
compensators are used. These compensators are called <b>Dynamic Voltage
Restorer</b> (DVR), as their primary application is to compensate for voltage
sags and swells. Their configuration is similar to that of SSSC (Static
Synchronous Series Compensator). However, the control techniques are different.
A DVR is expected to respond fast (less than ¼ cycles) and thus employs PWM
converts (</span><span style="background: white; color: black; font-family: "Cambria","serif"; font-size: 12.0pt; line-height: 115%; mso-ascii-theme-font: major-latin; mso-bidi-font-family: Calibri; mso-bidi-font-weight: bold; mso-bidi-theme-font: minor-latin; mso-hansi-theme-font: major-latin;">Pulse-width modulation<b> </b></span><span style="font-family: "Cambria","serif"; font-size: 12.0pt; line-height: 115%; mso-ascii-theme-font: major-latin; mso-bidi-font-family: Calibri; mso-bidi-theme-font: minor-latin; mso-hansi-theme-font: major-latin;">converts</span><b><span style="background: white; color: black; font-family: "Cambria","serif"; font-size: 10.0pt; line-height: 115%; mso-ascii-theme-font: major-latin; mso-bidi-font-family: Arial; mso-hansi-theme-font: major-latin;">)</span></b><span style="font-family: "Cambria","serif"; font-size: 12.0pt; line-height: 115%; mso-ascii-theme-font: major-latin; mso-hansi-theme-font: major-latin;"> using IGBT (</span><span style="background: white; color: black; font-family: "Cambria","serif"; font-size: 12.0pt; line-height: 115%; mso-ascii-theme-font: major-latin; mso-bidi-font-family: Calibri; mso-bidi-font-weight: bold; mso-bidi-theme-font: minor-latin; mso-hansi-theme-font: major-latin;">Insulated gate bipolar transistor</span><b><span style="background: white; color: black; font-family: "Cambria","serif"; font-size: 10.0pt; line-height: 115%; mso-ascii-theme-font: major-latin; mso-bidi-font-family: Arial; mso-hansi-theme-font: major-latin;">)</span></b><span style="font-family: "Cambria","serif"; font-size: 12.0pt; line-height: 115%; mso-ascii-theme-font: major-latin; mso-hansi-theme-font: major-latin;"> or IGCT (</span><span style="background: white; color: black; font-family: "Cambria","serif"; font-size: 12.0pt; line-height: 115%; mso-ascii-theme-font: major-latin; mso-bidi-font-family: Calibri; mso-bidi-font-weight: bold; mso-bidi-theme-font: minor-latin; mso-hansi-theme-font: major-latin;">Integrated
Gate-Commutated Thyristor</span><b><span style="background: white; color: black; font-family: "Cambria","serif"; font-size: 10.0pt; line-height: 115%; mso-ascii-theme-font: major-latin; mso-bidi-font-family: Arial; mso-hansi-theme-font: major-latin;">)</span></b><span style="font-family: "Cambria","serif"; font-size: 12.0pt; line-height: 115%; mso-ascii-theme-font: major-latin; mso-hansi-theme-font: major-latin;"> device.</span></div>
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<span style="font-family: "Cambria","serif"; font-size: 12.0pt; line-height: 115%; mso-ascii-theme-font: major-latin; mso-hansi-theme-font: major-latin;">A DVR has to
supply energy to the load during the voltage sags. If a DVR has to supply
active power over longer periods, it is convenient to provide a shunt converter
that is connected to the DVR on the DC side. As a matter of fact one could
envisage a combination of DSTATCOM (Distribution Static Compensator) and DVR
connected on the DC side to compensate for both load and supply voltage
variations.<span style="mso-spacerun: yes;"> </span>The combined compensator is
termed as Unified Power Quality Conditioner (UPQC) which has similar to UPFC (</span><span style="background: white; color: black; font-family: "Cambria","serif"; font-size: 12.0pt; line-height: 115%; mso-ascii-theme-font: major-latin; mso-bidi-font-family: Calibri; mso-bidi-font-weight: bold; mso-bidi-theme-font: minor-latin; mso-hansi-theme-font: major-latin;">Unified Power Flow Controller</span><span style="font-family: "Cambria","serif"; font-size: 12.0pt; line-height: 115%; mso-ascii-theme-font: major-latin; mso-hansi-theme-font: major-latin;">). However
the control objectives are different. </span></div>
<div class="MsoNormal" style="text-align: justify; text-indent: 36.0pt;">
<span style="font-family: "Cambria","serif"; font-size: 12.0pt; line-height: 115%; mso-ascii-theme-font: major-latin; mso-hansi-theme-font: major-latin;">The DVR was first
installed on Duke Power System in USA in August 1996, with a rating of 2MVA
with 660 kJ of energy storage capacity, it is capable of compensating 50%
voltage sag for a period of 0.5 second (30 cycles). It was installed to protect
an automated yarn manufacturing and rug weaving facility. Since then, several
DVRs have been installed to protect microprocessor fabrication plants, paper
mills etc. typically, DVRs are made of modular design with a module rating of 2
MVA or 5 MVA. They have been installed in substations of voltage rating from 11
kV to 66 kV.</span></div>
</div>Seminar Topicshttp://www.blogger.com/profile/01524755623435065211noreply@blogger.com0tag:blogger.com,1999:blog-7621335163055053744.post-86938753993714158542011-03-18T12:29:00.000-07:002011-03-18T12:39:53.215-07:00AIR BLAST CIRCUIT BREAKERS<div style="text-align: justify; font-family: arial;">Circuit breakers are mechanical devices designed to close or open contact members, thus closing or opening of an electrical circuit under normal or abnormal conditions. Air blast circuit breakers are using compressed air or gas as the circuit breaking or interrupting medium. Gases such as nitrogen, carbon dioxide, hydrogen or Freon can be used as arc interrupting medium. But compressed air is the most accepted arc interrupting medium. The reasons are, nitrogen has circuit breaking properties similar to compressed air and there is no advantage of using it. Carbon dioxide has a draw back as it is difficult to control owing to freezing at valves and other restricted passages. Hydrogen has increased breaking capacity but it’s costlier.<br /><br />Freon has high dielectric strength and good arc extinguishing properties, but it is expensive and it is decomposed by the arc into acid forming elements.<br /><br />Desirable features of air blast circuit breakers are High speed operation, which is very necessary on large inter connected networks in order that system stability can be maintained and in the air blast circuit breaker this is achieved because the time interval between the receipt of a tripping impulse and contact separation is very short. Suitability for frequent operation, repeated switching by an air blast circuit breaker is possible simply because of absence of oil, which rapidly carbonizes with frequent operation, and because there is an insignificant amount of wear and tear at the current carrying contact surfaces. High speed reclosure by automatic means is an advantage on hv inter connected networks to assist and maintain system stability during the clearance of transient faults, a type of fault which is perhaps in majority on over head line. Negligible maintenance, the ability of the air blast circuit breaker to cope with repeated switching also means that negligible maintenance is required. Elimination of fire hazard, because of the absence of oil the risk of fire is eliminated.<br /><br />Reduced size, the growth of dielectric strength is so rapid in air blast circuit breakers that final gap required for arc extinction is very small. This reduces the size of the device.<br /><br />The air blast circuit breaker requires an auxiliary compressed air system which supplies air to the breaker air receiver. When opening is required compressed air is admitted to the arc extinction chamber. It pushes away the moving contacts. In doing so the contacts are separated and the air blast takes away the ionized gases along with it and assist arc extinction.</div>Seminar Topicshttp://www.blogger.com/profile/01524755623435065211noreply@blogger.com0tag:blogger.com,1999:blog-7621335163055053744.post-19978866524648515802009-11-12T11:36:00.000-08:002009-11-12T11:47:33.830-08:00VACUUM CIRCUIT BREAKER<span style="font-weight: bold;">VACUUM CIRCUIT BREAKERS</span><br /><br /> Circuit breakers are devices which can automatically break a circuit under fault conditions and it can make the circuit manually after the fault. Circuit breakers are classified into different types. One of the main circuit breaker among them is Vacuum circuit breaker. Here vacuum is used to extinct the arc. Arc extinction is the main process of a circuit breaker<br /><br /> Before that, it is needy to explain how an arc is produced. Circuit breaker has two contacts- Fixed and movable, otherwise called as electrodes. Normally the contacts remain closed but if any fault occurs these contacts open automatically and of course can be opened manually.<br /><br /> We know that circuit breakers work under the instructions from relay. When the trip coils from relay energize, circuit breaker identifies fault occurred and hence the contacts are pulled apart. A high intensity current flows through the contacts of the circuit breaker before they are opened by the system. At the same instant contacts begin to separate and causes heavy heat and temperature in between the contacts. This is termed as an arc. This heat is highly dangerous and can cause heavy damage to the whole system. So it has to be extinguished in no time.<br /><br /> Vacuum is having superior qualities over other arc quenching medium. It has high insulating strength. When the contacts are opened in vacuum, the arc is produced in between them. It got extinguishes quickly since the metallic vapours and ions produced during the arc rapidly condense on the surface of the circuit breaker contacts, resulting in quick recovery of dielectric strength.<br /><br /> The contacts of Vacuum circuit breaker and arc shied is mounted inside a vacuum chamber. The chamber is connected to the control mechanism by means of stainless steel bellows. A glass vessel is used as the outer insulating body. This is all about its construction.<br /><br /> Vacuum circuit breaker is really the most reliable one with low cost, no fire hazards, no gas generation, low arc energy, little maintenance and low inertia.Seminar Topicshttp://www.blogger.com/profile/01524755623435065211noreply@blogger.com2tag:blogger.com,1999:blog-7621335163055053744.post-28007941972357059922009-11-08T07:13:00.000-08:002009-11-08T07:52:58.909-08:00What is an Actuator?<span style="font-weight: bold;">Actuator</span> is a typical mechanical device used to move or control a mechanism or a system. This device gains energy for its working from air, electricity or liquid and then converts it into some kind of motion.<br /><br /> In engineering field <span style="font-weight: bold;">actuators</span> have many more applications in different sectors. In this field actuators are used as mechanisms to provide motion and are again used to stop the motion of that particular device. So it is clear that actuator just actuates the motion. May be start or stop, depends on the machine.<br /><br /> In <span style="font-weight: bold;">electronics engineering</span>, actuators are <span style="font-weight: bold;">subdivisions of transducers</span>. They are used to transform input signal into motion. Normally input signal would be electrical. E.g. electrical motors, pistons, relays, pneumatic actuators, piezo electric actuators etc. Actuators can be sometimes used as hardware components. Different types of actuators are available like plasma actuators, pneumatic actuators, electric actuators, linear actuators.<br /><br /> It’s a type of tool used to put something into automatic action. Actually actuators are used with number of sources. Depending on the type of actuator we are using, different tools will be assisting us to put the device to motion. Mostly they are used in office work area since most of them are used to move valve door in systems.<br /><br /> Sometimes they are used to maneuver certain mechanical devices on work. Depending on the shape and style actuators are divided into different classes. <span style="font-weight: bold;">Linear actuators, valve actuators, hydraulic actuators</span> are the best known and used among them. Each of them has assigned functions e.g. hydraulic actuators are used to allow more pressure, size and movement with the object.<br /><br /> All of these different types of actuators are best when knowing what type of motion control you need. They also provide speed, Belt drive, acceleration and accuracy with linear motion No matter what type of actuator is needed, there is a tool that makes it easier to maneuver a certain object or space in your work area.Seminar Topicshttp://www.blogger.com/profile/01524755623435065211noreply@blogger.com0tag:blogger.com,1999:blog-7621335163055053744.post-59959417461734264562009-11-04T10:51:00.000-08:002009-11-04T11:11:29.876-08:00DIGITAL SIGNAL PROCESSING (DSP)<span style="font-weight: bold;">What is Digital Signal Processing?</span><br /><br /> It’s a major branch of science that deals with the representation of signals as symbols or sequences and after that these signals are getting processed. There are two subfields of processing available- Analog signal processing and Digital signal processing.<br /><br /> This <span style="font-weight: bold;">digital signal processing</span> also includes subfields like <span style="font-weight: bold;">audio and speech processing, sonar and radar processing, sensor array processing, spectral estimation, statistical signal processing, digital image processing, signal processing for communication systems, biomedical signal processing, seismic signal processing</span> etc. So from the above description it’s clear that <span style="font-weight: bold;">DSP</span> is a vast branch in engineering field that requires genuine attention and development.<br /><br /> Generally these processing measures the continuous analog signals and is then converted into digital form by means of an Analog to Digital converter (A-D converter). For certain, the required output would be in Analog form, so the signal is then converted to Analog using Digital to Analog converter (D-A converter). We know that this process is very complex when compared with analog processing and hence error detection and correction methods are used to clarify the process.<br /><br /> The main notable <span style="font-weight: bold;">advantage of DSP</span> is that it is less affected to noise and hence non vulnerable. DSP algorithms are carried out in special processors like Digital Signal Processors which is inbuilt in the systems. Since the process is very lengthy and time consuming, we usually undergo the process in this type of processors. DSP’s include microprocessors, digital signal controllers, field programmable gate arrays etc. DSP’s can be implemented using specialized microprocessors like DSP56000, TMS320 and the SHARC.<br /><br /> Usually the digital signals are denoted in time domain, frequency domain, spatial domain etc. With the available characteristics, it is decided that on which domain the signal can be denoted. Sampling is another important point to be specified. Sampling can be done in signal processing during two stages discretization and quantization. In the dicretization stage the space of signals are divided into equivalence classes and quantization is carried out by replacing the signals with representative signals.<br /><br /> DSP has applications in the fields of audio signal processing, audio compression and in the fields as mentioned earlier.Seminar Topicshttp://www.blogger.com/profile/01524755623435065211noreply@blogger.com0tag:blogger.com,1999:blog-7621335163055053744.post-436043606204106782009-10-30T10:39:00.000-07:002009-10-30T11:14:25.205-07:00What are Lightning Arresters?<span style="font-weight: bold;">LIGHTNING ARRESTER</span><br /><br /> <span style="font-weight: bold;">Lightning arresters</span> or surge diverters are used to protect the earth screen and ground wires in an electrical system against direct lightning strokes. They conduct the high voltage surges to the ground without getting affected to the system. The lightning arrestor provides a cone of protection which has a ground radius approximately equal to its height above the ground.<br /><br /> The <span style="font-weight: bold;">surge diverters</span> consist of a spark gap in series with a nonlinear resistor. The function of non linear resistor is very important. As the gap sparks over, due to the over voltage, the arc would get short circuited and may cause power flow current in the arrester. Since the characteristic of the resistor is to offer high resistance to high voltage, it prevents the effect of a <span style="font-weight: bold;">short circuit</span>. After the surge is over, the resistor offers high resistance to make the gap non-conducting.<br /><br /> One end of the <span style="font-weight: bold;">arrestor</span> would be connected to the terminal of the equipment to be protected and other end would be grounded. The length of the spark gap is set in such a way that normal <span style="font-weight: bold;">line voltage</span> is enough to cause an arc across the gap but high voltage would break down the air insulation and form an arc.<br /><br /> <span style="font-weight: bold;">Different types of surge diverters</span> are available depending on the purpose. Some of them are Rod gap arrester, Horn gap arresters, Multigap arresters, Expulsion type lightning arrester and valve gap arrester. Each of them has variety of range of operating conditions.Seminar Topicshttp://www.blogger.com/profile/01524755623435065211noreply@blogger.com0tag:blogger.com,1999:blog-7621335163055053744.post-57660774626811852112009-10-28T02:46:00.000-07:002009-10-28T02:50:59.910-07:00What are Acoustic Couplers?<span style="font-weight: bold;"> ACOUSTIC COUPLER</span><br /><br /> The term <span style="font-weight: bold;">acoustic</span> means sound. This is a device used in telecommunication field for <span style="font-weight: bold;">coupling electrical signals</span> by <span style="font-weight: bold;">acoustical means</span>. Its main working is related to our telephone. <span style="font-weight: bold;">Acoustic coupler</span> is a terminal and interface device to link data terminals and radio sets with telephone. <span style="font-weight: bold;">Acoustic couplers</span> are used to transmit data over telephone lines using modems. This is a device onto which telephone handset is placed to connect computer to the network, a modem will be also there. Modems that do not use acoustic coupler can some times be called as Direct Connected Modems<br /><br /> The link between the terminals and telephones can be achieved by means of <span style="font-weight: bold;">acoustic signals</span> rather than through<span style="font-weight: bold;"> electrical connections</span>. In 1956 acoustic couplers came into use in our telephone industry till then this industry was a closed system wholly controlled and owned by Bell systems.<br /><br /> At first acoustic couplers were sensitive to external disturbances and noises. <span style="font-weight: bold;">Direct electrical connections</span> to telephone networks were made legal in early times. But rapidly preference got secured to the modem connecting method and hence acoustic couplers are used widespread. At times acoustic couplers are no longer used since now a days, telephones can be directly connected to modem instead of connecting to modular telephone connectors. Better connections can be established by avoiding unwanted breakage in signals. Still acoustic coupler modems can be useful in some situations like, in a hotel room where telephone cable is anchored in the walls. <span style="font-weight: bold;"><br /></span>Seminar Topicshttp://www.blogger.com/profile/01524755623435065211noreply@blogger.com1tag:blogger.com,1999:blog-7621335163055053744.post-52166398383872453772009-10-28T02:02:00.000-07:002009-10-28T02:11:48.180-07:00VARISTORSWhat is a VARISTOR?<br /><br /> The name varistor came from <span style="font-weight: bold;">variable resistor</span>. Varistor is a pure electronic component used to protect circuits from transient over voltages making the circuit triggered. The function of a varistor is to provide increased current when voltage becomes excessively high. Varistor is also known as <span style="font-weight: bold;">Voltage Dependent Resistor</span> (VDR) since it depends on voltage.<br /><br /> The most common type we are dealing with now days is <span style="font-weight: bold;">Metal Oxide Varistor</span> (MOV). It is just like a Unijunction Transistor, since it allows current flow only in one direction. It contains mass of ceramic grains enclosed between two metal plates. The boundary between and its neighbour forms a diode junction. So when a small voltage is applied across the electrodes, only a small current passes due to the reverse break down at the junctions. Similarly when a large voltage is applied, due to thermionic emission large current passes through the junction. This behavior results in nonlinear current voltage characteristic.<br /><br /> <span style="font-weight: bold;">Varistor</span> can absorb surge in some ways but to some to extent. A typical surge protector power strip can be made using MOV’s. A varistor provides no equipment protection from inrush surge current. A varistor doesn’t control such events. <span style="font-weight: bold;">Varistors</span> have many applications on different electronic circuits. It can replace ordinary resistor in almost all functions, basically it can vary its resistance. So using varistors we can control voltage and current to the circuit. Thus we can protect the circuit from internal damage and severe short circuits.Seminar Topicshttp://www.blogger.com/profile/01524755623435065211noreply@blogger.com0tag:blogger.com,1999:blog-7621335163055053744.post-65674454957762178062009-10-26T05:27:00.000-07:002009-10-26T05:32:47.502-07:00SCADA<span style="font-weight: bold;"> SCADA</span><br /><br /> SCADA is the acronym of Supervisory Control And Data Acquisition. It is used in the fields of data acquisition and monitoring in industries. SCADA is a pure software package and not having any hardware components. It is the monitoring section of a process and the decision making section. It controls all the process taken while doing a particular task.<br /><br /> Normally we use couplet of software, e.g. SCADA- PLC couplet. Here SCADA acts as master and PLC acts as slave. SCADA gives instructions and PLC obeys as per the order. In short control is safe in SCADA hands. It’s more convenient if we use the couplets even if SCADA alone can do all the operations alone.<br /><br /> SCADA operations are categorized under three below explaining sections. Such as- industrial, infrastructure and facility based processes. Industrial process includes manufacturing, production, power generation etc. Infrastructure based process means water treatment, waste water collection, refining etc. Facility process includes building, airport and all public sector processes.<br /><br /> SCADA mainly consists of five subsystems. Each is assigned to perform a particular task. The five subsystems are:<br /><br /> + HMI or Human Machine Interface- This is an apparatus used to supply data to the human operator and through this he could able to monitor and control<br /> + A supervisory computer system- This is used to acquire data and to send commands to the process.<br /> + RTU or Remote Terminal Unit- These are connected to sensors to do a process, Converts sensor signals to digital data and sends this data to the supervisory system.<br /> + PLC or Programmable Logic Controller- used as field devices in a process, since they are economical, flexible, versatile and much configurable than general purpose RTU’s.<br /> + Communication- Many modes of communication are available. Communication connects supervisory systems to RTU’s.<br /><br /> Three generation SCADA software is available. They are First generation or Monolithic, Second generation or distributed, Third generation or Integrated. Now third generation is in use.<br /><br /> SCADA has applications on energy management system, multi tasking, automation, industrial control systems, data exchange, pipeline transport, graphical design etc. SCADA made almost all sections under its control tactically. Mainly we use this software in automation purposes. This software is freely available and another advantage is no programming is needed. So even a person who is not good in programming can handle SCADA well and efficiently.Seminar Topicshttp://www.blogger.com/profile/01524755623435065211noreply@blogger.com0tag:blogger.com,1999:blog-7621335163055053744.post-15697970595866903402009-10-26T05:20:00.000-07:002009-11-19T10:36:22.947-08:00Privacy Policy<span style="font-size:small;"><br /><strong><span style="font-size:small;">Privacy Policy for www.electricalseminartopics.blogspot.com</span></strong></span><span style="font-size:large;"><br /></span><br /><span><br />Your privacy is important to us. We are committed to safeguarding your privacy while online at our site www.electricalseminartopics.blogspot.com. The following discloses the information gathering and dissemination practices for this </span><br /><br /><input name="IL_MARKER" type="hidden">Web site.<br /><br />The Information We Collect<br /><br /><strong>The Information We Collect</strong><br /><br /><span><span><br />We use statcounter, google analytics and other hosting service tools to collect the information. 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A short paragraph with content in quotes is acceptable with a link-back to the post at <span>electricalseminartopics.blogspot</span>.com<br /><br />Credit the Source<br /><br />You need to clearly highlight the fact that the content was derived from <span>electricalseminartopics.blogspot.com</span>.com<br /><br /><strong><br /></strong><br /><br /><strong>Link Back</strong><br /><br />You need to link back to the article from which you derived the excerpt.<br /><br />Advertisers<br /><br /><span><br />We use outside ad companies to display ads on our site. These ads may contain cookies and are collected by our ad companies, and we do not have access to this information. We work with the ad companies: <span style="font-weight: 400; font-style: normal; text-decoration: underline; color: rgb(51, 0, 255);font-family:Verdana;font-size:12px;" >Google Adsense</span>,</span><br /><br />Infolinks,chitika, Adbrite etc. Please check their websites for respective privacy policies.<br /><br /><strong>Contact Information</strong><br /><br />If users have any questions or suggestions regarding our privacy policy, please <a style="color: blue;" href="http://www.blogger.com/admin@techalone.com">Contact us</a>.Seminar Topicshttp://www.blogger.com/profile/01524755623435065211noreply@blogger.com0tag:blogger.com,1999:blog-7621335163055053744.post-76456360641194206942009-10-22T12:01:00.000-07:002009-10-22T12:11:50.812-07:00What is a neural network?<span style="font-weight: bold;">What are NEURAL NETWORKS</span>?<br /><br /> The term neural network refers to be a club of biological neurons. But now this term is referred as artificial neural network which is composed of artificial neurons. So first of a comparison is needed between both the terms.<br /><br /> <span style="font-weight: bold;">Biological neural network (BNN)</span> is composed of natural and is connected in central nervous system or peripheral nervous system. They are destined to perform specific functions as ordained. Artificial neural network are fabricated with a group of artificial neurons. The name is so given because we know a neuron is the basic functional unit of our body which is capable of doing specific functions. These artificial ones are used to solve artificial intelligence problems. <span style="font-weight: bold;">The artificial neural network (ANN)</span> focuses on the detailed coverage of two types.<br /><br /> In BNN a single neuron is connected to other neurons and finally forms an extensive connection. These connections are called synapses and are connected with axons to dendrites. As such neural networks are extremely complex. Scientists need to melt the properties of BNN artificially in different areas. They ended up in the formation of ANN. The ANN concentrated in the solving of particular assigned tasks. It is successfully applied to speech recognition, face recognition, image analysis, adaptive control, to construct robots etc. Mostly now they are employed in the fields of statistical estimation, optimization and control theory. All neural networks take numeric input and numeric output.<br /><br /> The concept of neural networks emerged in the late 18th century. In the early 1950’s Friedrich Hayek was the one to posit this idea to the world.<br /><br /> The utility of ANN lies in the fact that it can be used to observe variety of functions. It can be used to determine the significance of seating arrangement in a class room. In real life it deals with function approximation, time prediction, blind signal production, data processing etc. Neural network software is used to research, stimulate, develop and apply ANN and BNN. Neural networks, with their remarkable ability to derive meaning from complicated or imprecise data, can be used to extract patterns and detect trends that are too complex to be noticed by either humans or other computer techniques. A neural network is not something that can be categorized in a single feature. It’s a day by growing branch of science. In all the ways above said neural network is a typical notable area that can produce drastic changes in technologies.Seminar Topicshttp://www.blogger.com/profile/01524755623435065211noreply@blogger.com0tag:blogger.com,1999:blog-7621335163055053744.post-31046220066418438312009-10-22T05:42:00.000-07:002009-10-22T05:55:35.460-07:00ELECTRO DYNAMIC TETHER<span style="font-weight: bold;">What is an ELECTRO DYNAMIC TETHER</span>?<br /><br /> Tether means rope or chain used to fasten animals. In the case of space this tether finds application for connecting two space crafts. So tether is a term which needs key relevance that finds application even in space field. Physically a tether is a long flexible cable that connects two masses. When the cable is electrically conductive it is called as electro dynamic tether.<br /><br /> In the early 20th century Giuseppe Colombo came up with an idea of connecting two space crafts by means of some flexible cables. It also needed to be electrically conductive. So as a step forward to this idea NASA launched a shuttle to deploy a satellite on a tether to study the electromagnetic effects of a conducting tether as it passes through Earth’s magnetic fields ad a current was produced in the tether as it passes earth’s magnetic field, acting as an electric generator. This was the actual origin of electro dynamic tether.<br /><br /> There are mainly three <span style="font-weight: bold;">types of electro dynamic tether</span> employed systems available depending on the advantages.<br /><br /> 1. Electro dynamic tether systems- In this type two heavy masses are separated by means a long flexible extensive electrically conductive cable. This can perform various functions in space craft.<br /> 2. In low earth orbit tether can provide electrical power and positioning capability for satellites and space crafts.<br /> 3. In the case of long term mission tethers could drastically reduce the amount of fuel needed.<br /><br /> Now tethers are made of electrically conducting materials like aluminium or copper. This provides additional <span style="font-weight: bold;">advantages to the tethers</span>. An <span style="font-weight: bold;">electro dynamic tether</span> is a device use to convert orbital energy to electrical energy and it works on the principle of electro magnetic induction. This can be used for power generation. Tethers found applications in orbit raising, lowering and debris removal. Another application of tether is artificial gravity inside space crafts.Seminar Topicshttp://www.blogger.com/profile/01524755623435065211noreply@blogger.com0tag:blogger.com,1999:blog-7621335163055053744.post-20804285965209354352009-10-22T05:37:00.000-07:002009-10-22T05:40:59.529-07:00ELECTRICAL POWERLINE NETWORKING<span style="font-weight: bold;">ELECTRICAL POWERLINE NETWORKING</span><br /><br /> It is the method normally called <span style="font-weight: bold;">home networking</span> through which we are capable of interconnecting computers. This networking uses excited AC wire and power outlets to transmit the desired data to homes and different offices. Powerline networking allows sharing web access, printers, PC drives with all the existing wires, that means no new wires are needed to interconnect. Power line is one of the efficient methods for interconnecting computers. It uses electrical wiring in our house to create a network.<br /><br /> The main and key <span style="font-weight: bold;">advantage of powerline networking</span> is the PCs need not be put near the phone outlets instead the devices are connected through electrical output. We can’t start networking just by plugging in. Power line networking is based on Alliance home plug 1.o standard. With this type of networking we can interlink all the devices in our home without interrupting the working of each device.<br /><br /> As said earlier no extra wire is need for this networking. It uses standard plug or outlet to interlink and hence it is possible to access any where at home. It is easy to connect with Ethernet. Ethernet is a standard protocol for transferring data to and fro. Another notable feature is this type of networking provides maximum bandwidth and variable frequency band. This is the cheapest method for connecting different devices locating in various rooms.<br /><br /> IN this type of networking electrical power is transmitted over high voltage lines and distributed in low voltage lines. Proprietary specifications for power line home networking have been developed by a number of different companies within the framework. Power line communication modems are available for the data transfer. So lets conclude power line networking as one of the efficient and fabulous methods to interconnect computers.Seminar Topicshttp://www.blogger.com/profile/01524755623435065211noreply@blogger.com0tag:blogger.com,1999:blog-7621335163055053744.post-78384948276512683932009-10-22T05:22:00.000-07:002009-10-22T05:28:32.151-07:00What are Electrical Generators?<span style="font-weight: bold;">ELECTRICAL GENERATOR</span><br /><br /> It is a device that converts mechanical energy into electrical energy. The source of mechanical energy may be a reciprocating pump or turbine. Essentially an electrical generator consists of two parts-magnetic field and conductors.<br /><br /> The energy conversion is based on the principle of production of dynamically induced e.m.f. This dynamically induced e.m.f is produced under Faraday’s laws of Electromagnetic Induction. The e.m.f causes current flow if the circuit is closed. A generator forces electric charge to move to an external circuit, but it doesn’t produce any charge. The charge is present in the windings of wire.<br /><br /> Dynamo was the first electrical generator capable of supplying power to the industry. It uses electromagnetic principles for the conversion of mechanical power in electric current<br /><br /> As described in electrical terms and mechanical terms generator consists of two parts<br /><br /> <span style="font-weight: bold;">1) Mechanical-Rotor and Stator</span><br /><br />Rotor is the rotating part of motor, dynamo, alternator and generator and a Stator is the stationary part of motor, dynamo, alternator and generator.<br /><br /> <span style="font-weight: bold;">2) Electrical-Armature and Field</span><br /><br />Armature is the power producing component of motor, dynamo, alternator and generator and Field is the magnetic field component of motor, dynamo, alternator and generator.<br /><br /> Generator uses field coils that require a current flow to be present in the field coils. (Equivalent circuit). Different types of generators now in use are vehicle mount, engine generators, human powered electrical generators etc.<br /><br /> As described above an electrical generator converts mechanical energy into electrical energy. It is a most common which we use frequently. This plays such a major role in electricity production.Seminar Topicshttp://www.blogger.com/profile/01524755623435065211noreply@blogger.com7tag:blogger.com,1999:blog-7621335163055053744.post-64110379472809531322009-10-22T05:16:00.000-07:002009-10-22T05:20:29.256-07:00What are Sensors?<span style="font-weight: bold;">SENSORS</span><br /><br /> A <span style="font-weight: bold;">sensor</span> is a device that measures a physical quantity and coverts it into a signal that can be identified by an instrument. Sensors have variety of uses in almost all instruments that we come across in our everyday life. It has innumerable applications in cars, machines, elevators, aerospace, medicine, manufacturing etc. Sensors are to be designed even to measure minute readings. If its size is maintained to be small, it has various advantages. Technologically it adds variety of applications.<br /><br /> All sensors need to be calibrated against known standards. Resolution of a sensor is used to measure even the least variations in the measurements and displays digitally. Sensors sensitivity is another point to be noted. It indicates how much the sensors output changes when the measured quantity changes. Sensors can be used with verniar interfaces.<br /><br /> A good sensor must obey certain rules. They are listed under. It should be sensitive to measured property and insensitive to others, it should not influence the measured property. It should be designed so that must be linear in nature. An ideal sensor means, the output signal should be directly proportional to the measured quantity. The ideal sensor wouldn’t possess all these characters and its sensitivity will be much low<br /><br /> Different types of sensors are acoustic, sound, vibration, automotive, transportation, chemical etc. Sensors are small devices that can be used with large equipments with definite functions. It founds innumerable applications in all the fields of science and technology. So let’s conclude a sensor as a small magic device that can be encapsulated in different equipments for various different functions.Seminar Topicshttp://www.blogger.com/profile/01524755623435065211noreply@blogger.com2tag:blogger.com,1999:blog-7621335163055053744.post-11609700063652131462009-10-22T05:07:00.000-07:002009-10-22T05:13:27.913-07:00Mechatronics Engineering<span style="font-weight: bold;">what is mechatronics</span>?<br /><br /> A formal definition of mechatronics is “the synergic integration of mechanics, mechanical engineering, electronics, computer technology and IT to produce enhanced products and systems. <br /><br />Mechatronics is a vast subject which has deep roots in the fields of mechanical, electronic, computer and control engineering. Mechatronics is exceptionally useful in design engineering to create new products. Actually it is a combination of mechanics, computing, controlling etc. This combination made possible the invention of more versatile systems.<br /><br />A robot is the typical example for a mechatronic system. It includes all the aspects of above said subjects. The collaboration of mechatronic molecules gives rise to new different formats of designs. Mechatronic is such an advanced field of technology which makes possible new creations with the help of almost all the major branches in technical field. Hybrid systems important to mechatronics include production drives, synergy drives, planetary exploration rovers, automotive subsystems, auto focus cameras, hard drives and CD players.<br /><br />It has applications on automation and robotics, servo mechanics, sensing and control systems, automotive engineering, biomedical engineering, computer aided design, manufacturing systems etc. So this topic is much relevant to discuss about.Seminar Topicshttp://www.blogger.com/profile/01524755623435065211noreply@blogger.com0tag:blogger.com,1999:blog-7621335163055053744.post-49394950091784863962009-10-12T18:57:00.000-07:002009-10-15T02:49:39.050-07:00ELECTRICAL EQUIPMENTS<form action="http://www.google.co.in/cse" id="cse-search-box" target="_blank"><br /> <div><br /> <input type="hidden" name="cx" value="partner-pub-8198824950721768:qpeagiltpux" /><br /> <input type="hidden" name="ie" value="ISO-8859-1" /><br /> <input type="text" name="q" size="31" /><br /> <input type="submit" name="sa" value="Search" /><br /> </div><br /></form><br /><script type="text/javascript" src="http://www.google.co.in/cse/brand?form=cse-search-box&lang=en"></script><br /><br /><br /><span style="font-weight: bold;">ELECTRICAL EQUIPMENTS</span><br /><br />Electrical equipment is an appliance powered by electricity. This includes an enclosure, several electrical components, power switch etc. A machine which is the part of an electrical distribution system can be put under the category of electrical equipment. The components in this include switch board, distribution board, circuit breakers, energy meters, transformers etc<br /><br /> Let’s have a look at some significant electrical equipment. Electrical switch board is a major appliance. It directs electricity from one form to another. These switch boards contain large number of panels and each of it contains switches to redirect electricity. Actually the control of electricity to this switch board is carried out by electrical generators. As the power law defines the amount of power entering and leaving the switch must be equal. So generators make this stable. While going to the technical side of switch boards, it contains bus bars inside the case to isolate the switch board from the connections before it gets opened.<br /><br /> Distribution board is key electrical equipment. The main function of a distribution board is to divide the electric power feed into subsidiary circuits. It provides a safety breaker and fuse for each circuit in a common enclosure and hence the distribution board is sometimes called as power breaker.<br /><br /> An unavoidable part in electrical equipment section is circuit breakers. Basically it is an electric switch. It is designed to protect a device from over current or short circuit. It detects the fault if any and stops the flow of current to it. It incorporates manual as well as automatic control for switching operations. The latter control employs relays and operates only under fault conditions.<br /><br /> Its known to every one, transformer holds the top slot in the priority list. It’s a static piece of apparatus by means of which electric power from one circuit is transformed into electrical power of the same frequency in another circuit. It can raise and lower the voltage according to the need with the increase or decrease in current. The physical basis of a transformer is mutual induction and it works under the principle of Faraday’s laws of electromagnetic induction.<br /><br /> The above explained are some of the main electrical equipments which hold the key place in this section.Seminar Topicshttp://www.blogger.com/profile/01524755623435065211noreply@blogger.com1tag:blogger.com,1999:blog-7621335163055053744.post-59573313172239258742009-10-10T04:26:00.000-07:002009-10-10T05:16:56.177-07:00ELECTRICAL ENGINEERING<span style="font-weight: bold;">ELECTRICAL ENGINEERING</span><span style="font-weight: bold;"> DEPARTMENT</span><br /><br />It is commonly known as <span style="font-weight: bold;">Electrical & Electronics engineering</span>. <span style="font-weight: bold;">Electrical engineering</span> has as much relevance as electricity has in our life. So it is considered as one of the major and <span style="font-weight: bold;">basic branches in engineering field</span>. We can’t even think of an earth with out <span style="font-weight: bold;">electricity</span>.<br /><br /> At first this branch dealt with electricity, electronics and electromagnetism, now power electronics, power systems, digital signal processing, control systems are all handled by an <span style="font-weight: bold;">electrical engineer</span>. The major advancement in this field was emerged by late 19th centaury. By 17th centaury the work on electricity got started. It includes the famous works done by George Ohm on the relationship between current and potential difference, Michael Faraday’s Electromagnetic induction, James Clerk Maxwell’s theory on electricity and electromagnetism. These all made the advancement of an electric era so fast.<br /><br /> Major and noticeable inventions in this field are Cathode Ray Oscilloscope by Karl Ferdinand Baum, Diode by John Fleming, Triode by Robert Von Lieben and Lee Deforest, Albert Hull’s Magnetron which eventually lead to the development of Microwave oven by Percy Spencer. These inventions made our life as wonderful as we wish. We know how well these all take parts in our life.<br /><br /> In the field of education, an <span style="font-weight: bold;">electrical engineer covers</span> Maths, Physics, computer science, specific topics in electrical engineering. They should have detailed knowledge in Electrical machines, signal processing, power systems, power electronics, and control systems<br /><br /> An electrical engineer has to work in the development of wide range of technologies. They use to design, test and supervise all electric systems. They are destined to work in electric power stations, telecommunication systems, and satellite communications, in the fields of power generation, transmission and distribution. It includes work on transformers, motors, alternators, generators etc.<br /><br /> <span style="font-weight: bold;">Electrical engineer</span> has a key role in the field of space flight. Control system is a major topic in electrical engineering; this plays an exceptionally strong role in space flight. Electronics is the sub discipline of electrical branch. It involves the testing of electric circuits, properties of resistors, capacitors, diodes etc. It deals with the study of radar, commercial circuits, microprocessors and its applications on different fields.<br /><br /> Digital signal processing is an unavoidable section in electrical engineering. It deals with the analysis and manipulation of signals. Another markable feature is in the field of computer technology. This involves the designing of computer and computer systems.<br /> In short, in every walk of our life we can feel the importance of electricity and hence electrical engineering.Seminar Topicshttp://www.blogger.com/profile/01524755623435065211noreply@blogger.com0tag:blogger.com,1999:blog-7621335163055053744.post-70706026326506917272009-10-09T00:13:00.000-07:002009-10-09T00:14:51.851-07:00BASIC ELECTRICAL RULESBASIC ELECTRICAL RULES<br /><br />To protect all while working under electric apparatus from hazardous conditions some rules are to be strictly followed. They are made and proposed for the safety of users. These rules are listed under several sections.<br /><br /> Make sure that the equipment used is safe and check its working conditions properly. If the equipment is watered by some means, do avoid contact with it. Use the appliance only for the purpose for which it is made. Before using the device, check whether it has passed the entire requirement prescribed. Avoid direct contact from fuses. The equipments that are made to use in wet conditions may only used in that condition, ensure it. Before using identify its working and disconnecting methods. Equipments with out the mark of manufacturer can’t be used. Maintenances should be done in a proper way. The cases, cables, fuses all should be fixed as prescribed. Another important thing is the equipment should be perfectly grounded and is over current protected. Several different rules are to be used in different working conditions. The devices are to be classified under type, voltage, power rating and several other factors. Replace the fuse only after rectified the mistake of the blown fuse. Avoid using wires with poor insulation. Don’t touch the circuit with fingers. Proper safety measures are to be followed in each case.Seminar Topicshttp://www.blogger.com/profile/01524755623435065211noreply@blogger.com0tag:blogger.com,1999:blog-7621335163055053744.post-69574395364000968462009-10-08T23:55:00.000-07:002009-10-09T00:12:41.203-07:00ELECTRICAL SAFETY MEASURESELECTRICAL SAFETY MEASURES<br /><br />We can’t even think of a day with out electricity. It has such relevance in our every day life. We know in earlier periods how miserable were the days with out electricity. It’s an extremely powerful force and if it’s not used properly and if proper safety measures are not taken, electricity would become deadly harmful. So the topic about safety measure is such a way important. Taking proper safety measures will always keep the harm away<br /><br /> It’s important to take apt measures against accidents while working indoor and outdoor. Public utility commission of Ohio offers several tips for keeping safety under all working conditions.<br /><br /> To ensure indoor safety we must make sure that no electric cords or wires are frayed or cracked. If any, remove or replace it in no time. Over loading is another important cause for accidents because it’s really harmful to take large number of appliances from a single outlet, it’s to be avoided. Ensure that electric plugs are fitted properly. While unplugging always pull the plug and not the cord because pulling the cords do harm to all the internal connections and may harm the user. Avoid using extension cords and if necessary relieve suddenly after use. Avoid contact of water from all the electric appliances. Never use any metal pieces to dislodge something from an electrical appliance.<br /><br /> Let’s have a look at the outdoor precautions to be taken. Severe weather conditions may cause live power wires fall on the ground, don’t ever attempt to touch the wire and its surroundings. Inform the police as early as possible if noticed. Use wood ladders around the power lines instead of metal; also keep the ladders at a minimum distance of 10 feet away from the power lines. Make the surroundings of power line free from plants, branches of tree. Don’t use any wet tools. Keep the electric lines far from the reach of children.<br /><br /> Use wires and cables with ISI mark, Use lamp holders with lamp, use appropriate MCB and Use apt rated fuses. While repairing get the certified electrician. If any accident occurs, don’t touch the victim directly. Make him free from electric contact, i.e., to turn off the supply, give him first aid and call for medical assistance. If ant electric device catches fire, don’t try to put out it with water, immediately switch off the supply and use fire extinguisher.<br /><br /> Taking all these safety tips under consideration, stay free from harm and use electricity wisely and properly.Seminar Topicshttp://www.blogger.com/profile/01524755623435065211noreply@blogger.com0tag:blogger.com,1999:blog-7621335163055053744.post-32200986805553296302009-09-30T12:20:00.000-07:002009-09-30T12:25:14.415-07:00National Electrical Code - NEC<span style="font-weight: bold;">National Electrical Code (NEC)</span><br /><br /> <span style="font-weight: bold;"> National Electrical Code</span> is the United States standard for the installation of electric wiring safely; it is the most approved American national standard. Actually it is a series of codes issued by National Fire Protection Association (NFPA). This NEC consists of 19 code making panels and technical correlating committee. NEC work is sponsored by NFPA. It is formally identified as ANSI/NFPA 70.<br /><br /> This code was published in 1897 and is getting updated every three years. The 2008 code is the most recent version. Most states adopt the most recent edition within a couple of years of its publication. As with all national codes some of the portions or sections are omitted usually, but NEC is the least amended model code<br /><br /> <span style="font-weight: bold;">NEC</span> can be accessed to the public as a book in early periods but now available in the electronic version. NEC is composed of introduction, nine chapters. The introduction contains purpose, scope, enforcement and rules or information. These chapters deal with voltages, connections, markings, wiring devices, conductors, cables, cords, switches, heaters etc. In general all the chapters enclose numbered articles, parts, sections (or lists or tables) italicized exceptions, and fine print notes (FPN) -- explanations that are not part of the rules. Each code article is numbered based on the chapter which is in.<br /><br /> For eg; Article 210 addresses branch circuits and receptacles. This says about the minimum number of branches, placement of receptacles etc. NEC also has laws about how many circuits and receptacles are to be placed in a residential dwelling. It has separate law enforcement sections on conduit and cable protection, temperature rating etc<br /><br /> <span style="font-weight: bold;">NEC</span> consists of codes covering all the sections in <span style="font-weight: bold;">electrical field</span>. So in general NEC is the most accepted and least amended electrical code.Seminar Topicshttp://www.blogger.com/profile/01524755623435065211noreply@blogger.com0tag:blogger.com,1999:blog-7621335163055053744.post-16297506827201953752009-08-29T23:51:00.001-07:002009-08-30T00:03:44.789-07:00Seminar on DSTATCOMThis Electrical Engineering Seminar Topic is related with the DSTATCOM<br /><br /> Shunt Connected Controllers at distribution and transmission levels usually fall under two catogories – Static Synchronous Generators (SSG) and Static VAr Compensators (SVC).<br /><br />A Static Synchronous Generator (SSG) is defined by IEEE as a self-commutated switching power converter supplied from from an appropriate electric energy source and operated to produce a set of adjustable multiphase voltages , which may be coupled to an ac power system for the purpose of exchanging independently controllable real and reactive power. When the active energy source (usually battery bank, Superconducting Magnetic Energy Storage etc) is dispensed with and replaced by a DC Capacitor which can not absorb or deliver real power except for short durations the SVG becomes a Static Synchronous Compensator (STATCOM) . STATCOM has no long term energy support in the DC Side and can not exchange real power with the ac system ; however it can exchange reactive power. Also , in principle, it can exchange harmonic power too. But when a STATCOM is designed to handle reactive power and harmonic currents together it gets a new name – Shunt Active Power Filter. So a STATCOM handles only fundamental reactive power exchange with the ac system.<br /><br />STATCOMs are employed at distribution and transmission levels – though for different purposes. When a STATCOM is employed at the distribution level or at the load end for power factor improvement and voltage regulation alone it is called DSTATCOM. When it is used to do harmonic filtering in addition or exclusively it is called Active Power Filter. In the transmission system STATCOMs handle only fundamental reactive power and provide voltage support to buses. In addition STATCOMs in transmission system are also used to modulate bus voltages duting transient and dynamic disturbances in order to improve transient stability margins and to damp dynamic oscillations.<br /><br />IEEE defines the second kind of Shunt Connected Controller called Static VAr Compensator (SVC) as a shunt connected static var generator or absorber whose output is adjusted to exchange capacitive or inductive current so as to maintain or control specific parameters of the electrical power system (typically bus voltage).Thyristor-switched or thyristor-controlled capacitors/inductors and combinations of such equipment with fixed capacitors and inductors come under this.This has been covered in an earlier lecture and this lecture focusses on STACOMs at distribution and transmission levels.<br /><br />PWM Voltage Source Inverter based Static VAr Compensators (referred to as SVC here onwards) began to be considered a viable alternative to the existing passive shunt compensators and Thyristor Controlled Reactor (TCR ) based compensators from mid-eighties onwards. The disadvantages of capacitor/inductor compensation are well known. TCRs could overcome many of the disadvantages of passive compensators. However they suffered from two major disadvantages ;namely slow response to a VAr command and injection of considerable amount of harmonic currents into the power system which had to be cancelled by special transformers and filtered by heavy passive filters.<br /><br />It became clear in the early eighties that apart from the mundane job of pumping lagging/leading VArs into the power system at chosen points ,VAr generators can assist in enhancing stability of the power system during large signal and small signal disturbances if only they were faster in the time domain. Also ,they can provide reactive support against a fluctuating load to maintain the bus voltage regulation and to reduce flicker problems,provide reactive support to control bus voltages against sag and swell conditions and provide reactive support to correct the voltage unbalance in the source – if only they were fast enough. PWM STATCOMs covered in this lecture are capable of delivering lagging/leading VArs to a load or to a bus in the power system in a rapidly controlled manner.<br /><br />High Power STATCOMs of this type essentially consist of a three phase PWM Inverter using GTOs,Thyristors or IGBTs, a D.C. side capacitor which provides the D.C. voltage required by the inverter,filter components to filter out the high frequency components of inverter output voltage,a link inductor which links the inverter output to the a.c supply side,interface magnetics (if required) and the related control blocks. The Inverter generates a three-phase voltage, which is synchronized with the a.c supply ,from the D.C. side capacitor and the link inductance links up this voltage to the a.c source. The current drawn by the Inverter from the a.c supply is controlled to be mainly reactive(leading or lagging as per requirement) with a small active component needed to supply the losses in the Inverter and Link Inductor (and in the magnetics,if any).The D.C. side capacitor voltage is maintained constant( or allowed to vary with a definite relationship maintained between its value and the reactive power to be delivered by the Inverter) by controlling this small active current component. The currents are controlled indirectly by controlling the phase angle of Inverter output Voltage with respect to the a.c side source voltage in the “Synchronous Link Based Control Scheme” whereas they are controlled directly by current feedback in the case of “Current Controlled Scheme”.In the latter case the Inverter will be a Current Regulated one ,i.e. its switches are controlled in such a way that the Inverter delivers a commanded current at its output rather than a commanded voltage (the voltage required to see that the commanded current flows out of Inverter will automatically be synthesized by the Inverter).Current Control Scheme results in a very fast STATCOM which can adjust its reactive output within tens of microseconds of a sudden change in the reactive demand.<br /><br />For more details, visit <a href="http://techalone.com">Techalone.com</a>Seminar Topicshttp://www.blogger.com/profile/01524755623435065211noreply@blogger.com0tag:blogger.com,1999:blog-7621335163055053744.post-75826639810020309422009-07-31T17:21:00.000-07:002009-07-31T17:25:32.864-07:00Electrical Seminar Topics<span style="font-weight:bold;">Electrical Engineering Seminar Topics</span><br /><br />electricalseminartopics.blogspot.com basically provides a place for all latest info about Electrical Seminar Topics including Engineering Seminar topics and the reviews of those topics too.One must checkout for latest Technical Seminar Topics including Engineering Seminar topics,Engineering seminars,Electrical Seminar Topics and the reviews of those topics.<br /><br />If you want a Technical seminar topic some times you have to search it in different places.And if you need to select one Engineering seminar topic you have to search a lot in the internet or the related books. electricalseminartopics.blogspot.com can help you a lot or it.The trend in the seminar topics are changing in these days.We are also trying to make this task as much simple. 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Also all types of new technical topics are reviewed.<br />like many others, found myself in the need for Technical topics and that’s when the internet comes in hand. A person who is very active always come back looking for more engineering seminars that suits their needs. Fortunetely, these sites usually have their seminars divided into categories by the branch of the Engineering, rescent technical topics and so on.<br /><br />It is an informative & useful site for all kinds of seminar lovers. It has quality Technical seminars & a variety of categories to choose from. I think it should be recommended to all IT geeks.<br /><br />Very rarely you come across an IT site, which caters to the industries, really great useful. Real fun to have access to all seminars of various branches in one site.<br /><br />One can easily download Technical seminars in your computer using this site. You could get all latest technical seminar topics here since they are updated daily.<br />Thus it is recommended to all those who want to experience first hand information on Technical seminar topics on varied topics.Seminar Topicshttp://www.blogger.com/profile/01524755623435065211noreply@blogger.com0