Bridge Lcr
Bridge Lcr
Obsolete Product Redesign
Obsolete Product Redesign – LCR Bridge
Orchid Technologies was selected to update the electronics design of the Precision LCR Instrument. Accurate to 0.05%, the original 1988 instrument design was well executed. However, vintage 1980's state of the art electronic components were going 'end-of-life' at an alarming rate. Orchid studied the design and operation of the existing equipment. We generated a detailed development plan proposing significant technical improvements, and cost reductions. Then we set to work. Our new instrument is form, fit, and function compatible with the old, while achieving improved accuracy and a 3x increase in measurement speed.
Obsolete Product Assembly Simplification
The original LCR meter required multiple circuit boards to perform its functions. These circuit boards were shielded with a complex jumble of sheet metal, spacers, and screws. Additionally, expensive coax cables were installed to make the DUT connection. Orchid's new design is elegantly simple. All circuitry is now on a single board, Altera FPGA devices integrate digital functions, and system shielding has been simplified. The result–a lower cost, easier to build, easier to service assembly that has another five to seven years product life.
Precision Analog and Digital DSP Technology
Low total-harmonic-distortion precision sine wave generation, phase-balanced analog amplifiers, low noise power systems, and very high accuracy 18 bit analog to digital conversion circuitry were our design challenges. A Texas Instruments TMS320C6713B performs high speed floating point calculations in support of the measurement functions.
Orchid Technologies: Electronics Redesign
The development of custom electronic products for our OEM clients is Orchid's entire business. The redesign of high performance instrumentation with rapid design cycles, demanding technical requirements, and unforgiving schedules sets us apart. View recent designs at www.orchid-tech.com
About the Author
Paul Nickelsberg, President and CTO of Orchid Technologies Engineering and Consulting, Inc., has 20 years experience in electronic products design. He can be reached at paul@orchid-tech.com or 978-461-2000 X111.
 |
 New Handheld bridge LCR Meter 0.3% accuracy TH2821B  US $152.99
|
 Leader LCR-740 9V battery operated LCR Bridge with Manual US $75.00
|
 Precision Multimeter Bridge LCR & LC Meter OHM Tester US $69.98
|
 inductance capacitance LCR4070 digital LCR Bridge Meter US $49.00
|
 New Protable handheld bridge LCR Meter 1KHz 0.25% DMM US $199.99
|
 NEW BRIDGE,CONTOUR,CY ACB4224LCR US $226.99
|
 Leader LCR Bridge LCR-740 Instruction Manual US $29.99
|
 Protable handheld bridge LCR RCL LRC RLC meter TH2821B US $148.22
|
 Handheld bridge LCR Meter 0.3% accuracy 0.1% re TH2821 US $152.99
|
 10Khz Precision Digital LCR Bridge D Q Meter with clip US $210.00
|
 Handheld bridge LCR Meter 0.3% accuracy + 0.1% TH2821A US $259.99
|
 Handheld bridge LCR Meter 0.3% accuracy + 0.1% TH2821 US $199.99
|
 Protable handheld bridge LCR RCL LRC RLC meter TH2821 US $146.99
|
 TH2811D Desktopl LCR Bridge Meter 10Khz 0.2% Kelvin USG US $451.00
|
 TH2811D Desktop LCR Bridge Meter 10Khz 0.2% Kelvin UKG US $429.84
|
 TH2811D LCR Bridge Meter 10Khz Bench Top US $399.99
|
 NEW BRIDGE,CONTOUR,CY BTB4824LCR US $154.99
|
 RACAL DANA 9343M LCR AUTOMATIC BRIDGE US $308.16
|
 Protable handheld bridge LCR RCL LRC RLC meter TH2821 US $169.99
|
 Portable Handheld Bridge LCR RCL LRC RLC Meter TH2821 US $189.99
|
 New Protable handheld bridge LCR Meter 1KHz 0.25% DMM US $199.99
|
 NEW MAYLINE ACB4224LCR Aberdeen Series Laminate Contour Bridge, 42w x 24d x US $354.56
|
 Portable Digital LCR Electric Bridge LC Meter BRAND NEW Ship From US US $83.88
|
| Powered by phpBay Pro |
Step Down
Step Down
Taking, Believing, and Understanding theTwelve Steps
Taking, Believing, and Understanding the Twelve Steps
By Dick B.
© 2011 Anonymous. All rights reserved
Why Take Them Before You Know What the A.A. Cofounders Said about Them?
Both Bill Wilson and Dr. Bob Smith, the cofounders of A.A., spoke explicitly on where the 12 Steps came from. In sum, they stated that the basic ideas came from: (1) the Bible; (2) Dr. William D. Silkworth; (3) Professor William James; and (4) Reverend Samuel M. Shoemaker, Jr.
As we will see in this article, that is not the whole story. But here's what A.A.'s cofounders said:
In his last major address to AAs, delivered in Detroit in 1948, A.A. cofounder Dr. Bob stated:
When we started in on Bill D., we had no Twelve Steps . . . we had no Traditions. But we were convinced that the answer to our problems was in the Good Book. To some of us older ones, the parts that we found absolutely essential were the Sermon on the Mount, the thirteenth chapter of First Corinthians, and the Book of James. [The Co-Founders of Alcoholics Anonymous: Biographical Sketches: Their Last Major Talks (NY: Alcoholics Anonymous World Services, Inc., 1972, 1975), 13.]
It wasn't until 1938 that the teachings and efforts and studies that had been going on were crystallized in the form of the Twelve Steps. I didn't write the Twelve Steps. I had nothing to do with the writing of them. But I think I probably had something to do with them indirectly. . . . We already had the basic ideas, though not in terse and tangible form. We got them, as I said, as the result of our study of the Good Book. [The Co-Founders, 14.]
In The Language of the Heart: Bill W.'s Grapevine Writings (NY: The A.A. Grapevine, Inc., 1988), A.A. cofounder Bill W. stated:
So, then, how did we first learn that alcoholism is such a fearful sickness as this? Who gave us this priceless piece of information on which the effectiveness of Step One of our program so much depends? Well, it came from my own doctor, "the little doctor who loved drunks," William Duncan Silkworth. [p. 297]
Who, then, first told us about the utter necessity for such an awakening, for an experience that not only expels the alcohol obsession, but which also makes effective and truly real the practice of spiritual principles "in all our affairs"? Well, this life-giving idea came to us of AA through William James, the father of modern psychology. It came through his famous book, Varieties of Religious Experience. . . . William James also heavily emphasized the need for hitting bottom. Thus did he reinforce AA's Step One, and so did he supply us with the spiritual essence of today's Step Twelve. [pp. 297-98]
Having now accounted for AA's Steps One and Twelve, it is natural that we should next ask, "Where did the early AAs find the material for the remaining ten Steps? Where did we learn about moral inventory, amends for harm done, turning our wills and lives over to God? Where did we learn about meditation and prayer and all the rest of it?" The spiritual substance of our remaining ten Steps came straight from Dr. Bob's and my own earlier association with the Oxford Groups, as they were then led in America by that Episcopal rector, Dr. Samuel Shoemaker. [p. 298]
What God was Bill Wilson speaking of? In The Language of the Heart, Bill wrote at page 284:
And then the great thought burst upon me: "Bill, you are a free man: This is the God of the Scriptures."
What God was Dr. Bob Smith speaking of? In Alcoholics Anonymous, 4th ed. (NY: Alcoholics Anonymous World Services, Inc., 2001), Dr. Bob wrote at page 181:
Your Heavenly Father will never let you down!
In 1975, Harper & Row published Robert Thomsen's biography of A.A. cofounder Bill Wilson under the title Bill W. – 50th Anniversary Edition – Commemorating the 1935 Meeting Between Bill W. and Dr. Bob that Launched Alcoholics Anonymous (NY: Harper & Row, Publishers, 1975). In it, Thomsen wrote:
Ever since he [Bill W.] and [Dr.] Bob had tried to shape a program, their ideas had been based on Oxford Group principles: first admitting they were powerless over alcohol, then making a moral inventory, confessing their shortcomings to another, making amends whenever possible, and finally praying for the power to carry out these concepts and to help other drunks. [p. 282]
The difficulty with all these somewhat-conflicting statements is that the Twelve Steps themselves came from a much broader group of resources than any of the writers stated.
Why Take the 12 Steps Before You Know the Details about Their 26 Sources?
There are three different types of roots of the sources of the 12 Steps. Two of the three are detailed in a recent title my son Ken and I wrote: Dick B. and Ken B., The Dick B. Christian Recovery Guide: Historical Perspectives and Effective Modern Application, 3rd ed. (Kihei, HI: Paradise Research Publications, Inc., 2010). They are:
- The Seven-Point Summary of the Original Akron A.A. "Christian Fellowship" Program: Page 54 of The Dick B. Christian Recovery Guide, 3rd ed., quotes verbatim the seven-point summary of the original A.A. "Christian fellowship" program in Akron developed by Bill W. and Dr. Bob beginning during the summer of 1935. This original A.A. program, documented in late February, 1938, by Rockefeller agent Frank Amos, is recorded on page 131 of the A.A. General Service Conference-approved book DR. BOB and the Good Oldtimers (NY: Alcoholics Anonymous World Services, Inc., 1980).
- The 14 Specific Practices of the Akron A.A. Christian Pioneers: Pages 56-58 of The Dick B. Christian Recovery Guide, 3rd ed., discuss in some detail the 14 actual practices employed by the Akron pioneers in their implementation of the original, seven-point, A.A. Program documented by Frank Amos. With my son Ken's help, I unearthed and reported on these 14 practices in conjunction with our 20 years of research on the origins of Alcoholics Anonymous.
So what are these 26 wellsprings or sources of the 12 Steps upon which Bill Wilson drew when he put together the Big Book published in 1939? In three of my recent titles, I listed and explained what are at least 16 different sources of the ideas Bill Wilson finally incorporated into the Twelve Step program he fashioned and presented in the first edition of Alcoholics Anonymous. Yet the more one searches for specifics, and the more one researches, the more the fullness of the wellspring details becomes
In brief, there are 26 wellspring ideas incorporated into the Twelve Steps as presented in the text of the first edition of Alcoholics Anonymous, published by Works Publishing Company in 1939. These sources include:
- The King James Version of the Bible (affectionately called "The Good Book.").
- William D. Silkworth, M.D. (Bill Wilson's psychiatrist).
- Professor William James of Harvard, whose book Bill Wilson and Dr. Bob had read.
- Dr. Carl Gustav Jung of Switzerland, who told Bill's mentor, Rowland Hazard, that—because he had the "mind of a chronic alcoholic"—a religious conversion might help him overcome drinking.
- The Oxford Group, to which Bill Wilson and his wife Lois belonged and with which Dr. Bob and his wife Anne were associated in Akron. Its 28 life-changing ideas influenced all four people.
- The teachings of Rev. Samuel M. Shoemaker, Jr., with whom Bill had worked on his proposed program and whom Bill called a "co-founder" of A.A.
- The "no-cure" ideas and language of the lay therapist Richard Peabody, whose book, The Common Sense of Drinking, both Bill and Bob read.
- The teachings of Dr. Bob's wife, Anne Ripley Smith, who compiled and shared with early AAs and their families her personal journal which she wrote between 1933 and 1939.
- The Christian books, other religious literature, and devotionals, circulated by Dr. Bob among early AAs.
10. "Quiet Time" and the guidance of God.
11. Belief in, and conversion to, God through Jesus Christ.
12. Qualification of newcomers as to their decision to quit permanently, and as to their willingness to go to any lengths in order to get and stay sober.
13. Medical help for, or hospitalization of, newcomers.
14. New Thought writings and ideas.
15. Intensive work helping newcomers get straightened out.
16. Recommended social and religious comradeship.
17. Recommended weekly attendance at a religious service.
18. Evangelists like Dwight Moody, Ira Sankey, and Billy Sunday.
19. Lay workers of the Young Men's Christian Association (the YMCA).
20. The Salvation Army.
21. Gospel or rescue missions.
22. The Young People's Society of Christian Endeavor.
23. Dr. Bob's extensive Christian upbringing and Bible study as a youngster in Vermont.
24. Bill Wilson's extensive Christian upbringing, YMCA participation, and Bible study as a youngster in Vermont.
25. The "Farther Out" ideas manifested in Big Book language, and in the practices and experiments of Bill Wilson, and seemingly emanating from Bill's extensive involvement in the Swedenborgian sect, in psychic experiments, in Richard Maurice Bucke's Cosmic Consciousness book, in spiritualism, and in mysticism.
26. The idea of self-made religion, a self-made deity, and choosing one's own conception of an "higher power."
Through the years of my research and writing, all of the foregoing 26 ideas have been discussed; and today, substantial documentation can be found in several of my titles, including: (1) Dick B. and Ken B., Dr. Bob of Alcoholics Anonymous: His Excellent Training in the Good Book As a Youngster in Vermont (Kihei, HI: Paradise Research Publications, Inc., 2008), 275-99; (2) Dick B., A New Way Out: New Path—Familiar Road Signs—Our Creator's Guidance (Kihei, HI: Paradise Research Publications, Inc., 2006), 14-32; and (3) Dick B. and Ken B., The Dick B. Christian Recovery Guide, 3rd ed.
Materials on the last two sources are discussed, from various viewpoints, in the following titles (among others): (1) Mel B., My Search for Bill W. (Center City, MN: Hazelden, 2000); (2) Mel B., New Wine: The Spiritual Roots of the Twelve Step Miracle (Center City, MN: Hazelden, 1991); (3) Susan Cheever, My Name is Bill: Bill Wilson—His Life and the Creation of Alcoholics Anonymous (NY: Washington Square Press, 2004); and (4) William G. Borchert, The Lois Wilson Story When Love is Not Enough: A Biography of the Cofounder of Al-Anon (Center City, MN: Hazelden, 2005).
Why Take the 12 Steps but Avoid the Prime Source of Instruction?
It would appear that today's AAs and A.A. critics are stuck with ideas and approaches which seem to fill their individual beliefs, unbelief, or creeds—which sadly do not point them to the one place where the initial instructions for taking the Twelve Steps can be found.
We will suggest an approach, particularly for Christians, in a subsequent article. But it would be well to point to several inconsistent approaches today that leave something to be desired—by all concerned.
ñ Follow the instructions in Alcoholics Anonymous.
ñ Study the "Personal Stories" in the Big Book—including the original stories in the first edition (1939), all but three of which are omitted from the fourth edition (2001).
ñ Use one of the many secular "Step guides" that have all sorts of interpretations and have been published by Joe and Charlie from the Big Book Seminars, Hazelden (in a variety of forms), and a host of individuals.
ñ Use one of the so-called "Recovery Bibles": Life Recovery Bible, Serenity: A Companion for Twelve Step Recovery, Recovery Devotional Bible, and the Celebrate Recovery Bible. Most are filled with page after page of attempted correlation of the Steps to the verse or section of scripture being read at any given time.
ñ Use one of the innumerable "Christian Step Guides" now in print, most of which append a writer's view of one or more Bible verses deemed to be relevant to the Step under study.
Can any or all of the foregoing and other approaches be reconciled with the Bible and the Big Book? Can the Big Book and the Bible be reconciled at all? Can the Steps be used as life-changing guides emanating from biblical basics? Can the accuracy and integrity of the Word of God be preserved by a Big Book-Bible student who would like to utilize the Steps, the A.A. Fellowship, and the Bible in recovery? Can one study the Bible in conjunction the Big Book presentation of the Twelve Steps and meet the "requirement" of the Book of James—"But be ye doers of the word and not hearers only, deceiving your own selves" (James 1:22)
When we address these issues in the next article, we will begin with the way in which Bill W. and Dr. Bob—though differing in theological viewpoints and religious backgrounds—were able to collaborate in the use of the Steps, build on the Bible basics, discuss A.A. history, and retain their own convictions as to how these elements could be used to help drunks.
Gloria Deo
About the Author
Dick B. is a writer, historian, retired attorney, Bible student, CDAAC, and an active and recovered member of the A.A. Fellowship. He is the author of 42 titles and over 500 articles on the history and biblical roots of A.A.
|
 REALLY 12V OUTPUT! In20-72V Out12V Step-down Converter US $15.90
|
 Industry Grade DC 12V To DC 3.3V 4A Step-Down Converter US $8.00
|
 Industry Grade DC 12V To DC 9V 2A Step-Down Converter US $8.00
|
 Industry Grade DC 24V To DC 12V 20A Step-Down Converter US $23.00
|
 5pcs 30V 1.2A Step-down HB LED Driver 5000:1 Dimming US $9.99
|
 NEW LM2596 DC Step-Down Adjustable Converter Power Module B5 US $4.01
|
 LM2596S DC-DC Adjustable Step-down Power Supply Module Hi-Q #03598 US $.99
|
 DC 8-40V To DC 12V 6A Step-up&down Converter US $24.70
|
 Industry Grade DC 12V To DC 7.5V 2A Step-Down Converter US $8.00
|
 Industry Grade DC 48V To DC 12V 10A Step-Down Converter US $24.80
|
| Powered by phpBay Pro |
Converter Variable Frequency
Converter Variable Frequency
Over View and Technical Analysis of Multilevel Converters
1. Unified Converter Theory
In the preface of his book Switching Power Converters, Wood introduces the concept of a unified converter theory. There he states: “Most traditional views of the field have seemed somewhat disjointed; converters were largely regarded as related only because they all use semiconductor switches and have certain topological similarities. . . . the view expounded herein (is that) switching power converters are related by function and behavior; their basic characteristics do not in any way depend on the types of switches used, nor on the applications to which they are put, nor on the topologies in which they are realized.”. According to this unified theory, any power electronic converter can be viewed as a matrix of switches which connects its input nodes to its output nodes. These nodes may be either DC or AC, and either inductive or capacitive; and the power flow may be in either direction. Two obvious restrictions are enforced by some basic laws of electricity.
• If one set of nodes (input or output) is inductive, the other set must be capacitive, so as not to create a cut set of voltage or current sources when the switches are closed.
• The combination of open and closed switches should never open circuit an inductor, or short circuit a capacitor.
2. Inverter or Rectifier? Voltage or Current Source?
This unified set of converters is generally broken into a number of subsets. The term rectifier is used when the power flow is predominately from the AC port to the DC port and the term inverter is used when power flow is predominately from the DC port to the AC port. The term converter is used either when there is no predominant direction of power flow or as a general term to encompass both rectifiers and inverters. In a Voltage Source Converter (VSC), the DC port is the capacitive port and is voltage stiff (i.e. a large DC bus capacitor). The voltages in such a converter are well defined by this port and are generally considered independent of the converter’s operation. The value of the AC side inductance is comparatively small and modulation of the converter controls these AC side inductor currents. Should the voltage source converter be responsible for the control of the DC bus capacitor voltage, then this voltage is indirectly controlled by controlling the net current flow in the capacitor.
The switches in such a converter must block a unidirectional voltage, but be able to conduct current in either direction if bidirectional power flow is desired. The converse is true in a Current Source Converter (CSC) — the DC port is inductive and current stiff. The current in this port (and hence the converter) is well defined and slow to change. The voltage (particularly at the AC port) is considered the variable directly controlled by the converter modulation. Since the AC port usually has significant line or load inductance, line to line capacitors must be placed on the AC port. The switches must block either voltage polarity, but are only required to conduct current in one direction. This naturally suits thyristors and symmetrical GTOs.
Figure 2.1. A voltage source rectifier - inverter cascade (top) and a current source rectifier - inverter cascade
Since the AC line and AC motor loads are both inductive, Voltage Source Rectifier – Inverter cascades (Fig. 2.1) are usually used for small and now increasingly for large motor drives and similar applications, as GTOs and IGBTs have matured. Larger converters have traditionally been current source converters, both because this best suits the characteristics of the thyristors and because it requires a large DC bus inductor, which was preferred to a large capacitor. Some converters do not easily fall, or cannot be placed into either category. The matrix or Venturini converter [1] is one example (Fig. 2.2). Both input and output ports are AC, and the definition of voltage stiff or current stiff (and hence voltage or current source) becomes somewhat arbitrary. Both input and output ports are
Figure 2.2. The matrix converter, with one possible implementation of the bidirectional switches.
3. The General Multilevel Converter
The next refinement is to define the meaning of multilevel. The following definition of a multilevel converter is offered:
A multilevel converter can switch either its input or output nodes (or both) between multiple (more than two) levels of voltage or current. The term “two-level” will be used where it is necessary to refer specifically to a converter which is not multilevel. This simple definition is deliberately quite broad and inclusive, in keeping with the spirit of the unified converter theory. For example, the multi-phase matrix converter (Fig. 2.2) is, strictly speaking, a multilevel converter, according to this definition. Consider the three phase to three phase matrix converter, with voltage source inputs and an inductive load. Any single output can be switched to one of three different voltage levels (the voltages of the three input phases) and similarly, any input can be switched to one of four current levels (including zero). In this preceding example, both the input and the output nodes are AC periodic varying quantities and so these levels can only be considered stationary for an interval much shorter than their AC period.
Figure 2.3. The current source converter (top right), voltage source converter (bottom left) and a simple three level voltage source converter (bottom right) can all be derived from the general topology of the matrix converter
Both the voltage source and current source converters can be derived from the general matrix converter by setting one port to be either a two terminal DC voltage stiff or DC current stiff port [70, 30]. Retaining the third terminal leads to a simple and more conventional multilevel converter (Fig. 2.3). Note that now one of the ports has been made DC and voltage or current stiff, only one port will experience the multilevel stepped waveforms. The other will still have a continuous waveform similar to that of an equivalent two level converter.
For example, a converter with an appropriate structure may create a stepped multilevel voltage waveform at the inductive nodes, but will always have a continuous voltage waveform at its capacitive nodes. Similarly a different converter may create a stepped multilevel current waveform at its capacitive nodes, but must have a continuous current waveform at its inductive nodes.
4. The Traditional Multilevel Converter
The traditional understanding of what constitutes a multilevel converter follows this more narrow definition. One of the ports has multiple (more than two) voltage or current stiff DC nodes or terminals, while the second port has a conventional single or three phase set of terminals which are switched to these multiple levels.
Most multilevel converters discussed in the literature step between multiple voltage levels. This is usually the most useful configuration for a high power converter, as reducing conduction losses in both converter and machines will always favour increasing the voltage rating rather than the current rating of the converter. Also as power levels increase, the input and output voltage levels presented to the converter increase. The structures of these multilevel converters place the switches in series to share the duty of blocking these higher voltages. Equally however, for high current applications, many switches can be placed in parallel, with their current summed by inductors. When switched separately, multilevel current waveforms result. As expected, multilevel converters can be DC-DC, DC-AC and as explained, in the broadest sense, even AC-AC.
5. Multilevel Topologies
Generally multilevel topologies can be divided into two groups, although in some cases the dividing line is indistinct. The first approach relies on summing the outputs of a number of conventional two-level converters, to produce a resultant multilevel output. The second group replaces the two-level switch structure with a multilevel switch topology within an otherwise conventional converter. These two groups will be distinguished by the terms multi-bridge converter and multilevel converter respectively. Any of the basic DC-DC converters (buck, boost, buck-boost, Cuk) can be extended to a multilevel topology. Often these are not called or perhaps even recognized as multilevel converters, but rather simply described as, for example, paralleled converters with interleaved switching instants. Two recent examples cited are multilevel boost converters used for power factor correction. In both of these examples, the switches are effectively placed in parallel and their contributions summed by separate boost inductors. They present multilevel current waveforms to the input and reduced voltage ripple at the output. Multilevel DC-AC converters range from the simplest single phase, full bridge driven with unipolar voltage switching to complex multi-phase converters. These are the most commonly recognized and reported multilevel converters and will be further categorized and referenced in the next section. Even multilevel AC-AC matrix converters have been shown to be at least theoretically possible.
6. Three Phase Multilevel Voltage Source Converters
At this point in the chapter, we will narrow the focus to that of three phase voltage source multilevel converters. Although this may seem somewhat limiting, it encompasses most of the higher power multilevel converters both in the published literature and in actual use. There are some examples of single phase converters functioning as AC-DC switching rectifiers, either in traction, computer or telecommunications power supplies. These Power Factor Correction rectifiers have lower inherent distortion and require less filtering because of their multilevel topology. There are four main voltage source DC-AC multilevel topologies which have been distinguished here and in the literature.
These are:
Ø Multiple bridge using transformer or inductor summing;
Ø Multiple bridge using direct series connection;
Ø Multilevel diode-clamped converter; and
Ø Multilevel flying capacitor converter.
Each of these will be examined in turn. Each of the diagrams presented are of a five-level converter, which can produce a nine-level phase to phase voltage waveform.
7. Transformer/Inductor summed Multiple Bridge Converter
As the title suggests, these multilevel converters are simply a number of conventional two-level bridges, whose inputs or outputs are summed using transformers or inductors. The multiple transformer secondary’s force voltage sharing between the switches (Fig. 2.4). The most common and well known example of a multi-bridge converter is the twelve pulse thyristor converter, well covered in most power electronic textbooks [49]. Harmonic cancellation in these converters is achieved through the phase displacement of the voltage waveforms of the star and delta transformer secondary’s.
Figure 2.4. A five-level Transformer coupled multiple bridges, which produces nine level phase-phase waveforms on the transformer primary.
This 30? phase shift between transformer secondaries allows identical secondary switching instants and current waveforms to appear interleaved on the transformer primary. A series connection is used for HVDC; a parallel connection for high current applications such as electrolysis and electro-plating. The technique can and is extended to many bridges each with a transformer secondary connection of the appropriate phase shift to achieve cancellation of the further low order harmonics in the primary. By clever connection of the transformer primaries, current as well as voltage sharing can be ensured.
A good example of the next degree of complexity and flexibility is seen in a 10 MW battery energy storage plant. The GTO converters operate in square wave mode and still rely on the transformer phasing for harmonic cancellation. However because forced commutation is used; now both the magnitude and the phase (real and reactive power) can be separately controlled. An extension of this approach to 48 pulse operation is achieved by eight GTO bridges operating in square wave mode, with reliance on the transformer for harmonic cancellation. The cancellation of switching harmonics can also be achieved by switching strategies, rather than relying on the transformer secondary’s for the necessary phase shifting. The simplest case — the series or parallel connection of two PWM bridges — has been investigated by a number of researchers. By the use of appropriate PWM modulation for each bridge, the odd multiples of the PWM carrier and sidebands, including the first cluster, were entirely removed from the output spectrum. This improvement is better than can be achieved by merely doubling the carrier frequency as the carrier which remains has lower amplitude. A particularly good example of a six bridge, transformer summed multilevel converter is used as an active filter for arc furnace static flicker compensation [71].
The AC connections of these bridges are summed by separate transformer secondaries, which allow either a series or parallel DC connection. Since the transformer no longer provides phase shifting, it may seem possible to remove the transformer entirely and place the converters directly in parallel (for a parallel connection). However, while no difference exists between the desired input and output components of the two converters, the undesired switching components are by definition exactly out of phase. Kirchhoff’s laws would be violated if the converters were directly connected.
The solution is to use inter-phase reactors (current sharing reactors) or interphase transformers on either the input or output of the converters. Although these reactors see the full combined converter current (and so have similar copper volume and copper losses), they only experience the difference in voltage between the converters. The volts-second component of this voltage is smaller and so the iron content of these reactors can be reduced in comparison to the transformers which would be required for full isolation. Normally the inductors are placed on the AC side, which is already the inductive port of a voltage source converter. Research on a five level three-phase motor drive which used this technique was conducted by Matsui et al . The outputs of two half bridge legs were summed with a current sharing reactor to form a three level intermediate output. This and another similarly formed three level output were summed by a third reactor to form the final five level phase output. One further solution is to sum the outputs of two converters across a bridge connected source or load. Both ends of the transformer or motor winding are brought out and the winding must be fully floating. One converter is driven with a phase inverted signal, so that twice the desired converter output is impressed across the floating load. If the carriers are appropriately phased, part of the undesired carrier component will appear as a common mode component to the load. Of course, this technique can only be applied for two converters.
To summarize, the transformer or inductor summed approach has the following advantages:
• The voltages within the individual converters and thus across the switches are well defined by the stiff voltage source output of the transformer secondaries.
• Should a converter module fail, or be removed for service, the converter may continue operating at full voltage, but at reduced current. • Other than the transformer (inductors), the structure is modular, which allows easier maintenance and reduced spares.
• Its mode of operation is easily understood and, again because of its modular structure, control is more easily applied. but also the following disadvantages:
• The transformer itself, if not needed for isolation, adds significantly to the cost of the converter and is one more item to maintain and potentially, to fail.
• The transformer requires multiple secondary windings, which must be isolated from one another and from ground. This is a significant problem at high voltages. This also increases the cost of the transformer.
8. Series Connected Isolated Multiple Bridge Converter
A second topology, which is really only a variation on the first, is that of series connected bridge converters (Fig. 2.5). Each phase leg consists of series connected single phase full bridges, the series connection being made directly (not by transformer as in the first case) on the AC side. A three phase converter can be constructed by connecting three of these single phase series strings to form a star or delta. Since this topology requires each full bridge to have an isolated DC bus, this connection has not been considered useful until recently re-examined. Now this topology is being considered for applications where no real power transfer is involved, such as for active power filtering and VAR correction. Then only a floating DC bus capacitor is required on each floating DC bus.
Some other sources of power which could easily be made modular and floating are batteries for battery energy storage systems (BESS) used for load leveling, or alternative energy sources such as solar panels. It is of course possible to power the isolated bridges from multiple isolated transformer secondaries, each with their own rectifier . By appropriate phase shifting of the transformer secondary windings, harmonic cancellation can be achieved on the primary side, as described previously, as well as at the multilevel output of the multi-bridge converter. However the disadvantages of a transformer with multiple isolated secondaries return. This multilevel converter structure has some very significant advantages, if its limitations are acceptable.
Its advantage is it has perhaps the simplest architecture and the lowest component count. No transformer is needed, so capital costs are low.
9. Applications of Multilevel Converters
At this point it should be clear that one of the major advantages of a multilevel converter, regardless of topology, is increased power rating. A converter need not be limited in size by the prevailing semiconductor technology, since a multilevel converter allows the voltage and/or the current to be shared among a number of switches. This advantage has traditionally justified the extra complexity of multilevel converters only at very high power levels, for large motor drives and utility applications. As the understanding and acceptance of multilevel converters has increased, these converters are being used at all power levels to extend the useful power range of semiconductor switches. For example, using multilevel topologies, IGBTs are challenging traditional GTO converters in motor drive and traction applications and MOSFETs are displacing IGBTs in some larger Switch Mode Power Supplies. The more stringent harmonic standards now being legislated also advantage multilevel converters, since they produce lower switching harmonic spectral components for a given switching frequency limit.
10. Conclusion
The aim of this chapter has been to demonstrate the diversity of possible multilevel converter topologies. Each has its own mixture of advantages and disadvantages and for any one particular application, one topology will be more appropriate than the others. Often, topologies are chosen based on what has gone before, even if that topology may not be the best choice for the application. The advantages of the body of research and familiarity within the engineering community may outweigh other technical disadvantages. Despite the diversity, these different topologies contain common underlying links. Usually the modulation and, to a lesser extent, control strategies can be developed independently of the converter’s topology and then subsequently applied with little or no modification. In subsequent chapters, the simplest case of the transformer connected multi-bridge converter will be used as the implied default multilevel converter topology. Required variations on modulation and control strategies will be explained after the general technique has been presented.
About the Author
Assistant professor in lord venkateswara engineering college.I am doing phd in sathyabama university, Tamil Nadu,India.
|
| Powered by phpBay Pro |
Volt Semiconductor
Volt Semiconductor
|
![Mersen Ferraz Protistor Semiconductor Fuse X300032 450A amp 700V volt [1Z11202]](http://www.forkinsocket.com/images/e/140725055961_0.jpg)
 BUSS FWX 12 FUSE FWX12 SEMICONDUCTOR 250 VOLT 12 AMP US $11.88
|
 BUSS FWP-20A14F FUSE 20 AMP 700 VOLT SEMICONDUCTOR FWP-20A 14F US $13.50
|
 BUSS FWP-40 FUSE FWP 40 SEMICONDUCTOR 700 VOLT 40 AMP US $19.80
|
 BUSS FWP250A FUSE FWP 250 AMP 700 VOLT SEMICONDUCTOR US $45.00
|
 Buss Semiconductor FWH200AMP Fuse 500 Volt FWH-200 Amp US $16.95
|
 Buss Semiconductor FWH100AMP Fuse 500 Volt US $9.95
|
 BUSSMAN FWP-250A 700 VOLT SEMICONDUCTOR FUSE *FREE SAME DAY SHIPPING USA** US $44.88
|
| Powered by phpBay Pro |
Voltage Tester Short
Voltage Tester Short
|
 UT15C Multifunction Voltage/Short Circuit Tester LCD US $45.00
|
 Uni-T Multifunction Voltage Tester Short Circuit UT-15B US $37.99
|
 UT15B Multifunction Voltage / Short Circuit Tester Step US $36.00
|
 New Uni-T Digital Voltage Tester Short Circuit UT-15B US $28.99
|
 Uni-T Multifunction Voltage Tester Short Circuit UT15B US $36.99
|
| Powered by phpBay Pro |