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2448) Invertor

Gist

An inverter is an electronic device that converts direct current (DC) to alternating current (AC). This conversion is necessary to power standard household appliances and electronics, which run on AC power, from DC sources like solar panels or car batteries. Inverters are essential for applications like backup power systems, off-grid solar setups, and electric vehicles. 

An inverter's primary function is to convert direct current (DC) to alternating current (AC). This conversion is crucial for running standard household appliances, which require AC power, from DC sources like car batteries, solar panels, or an inverter's own battery during a power outage. Inverters are essential for making DC power usable for AC systems. 

Details

A power inverter, inverter, or invertor is a power electronic device or circuitry that changes direct current (DC) to alternating current (AC). The resulting AC frequency obtained depends on the particular device employed. Inverters do the opposite of rectifiers which were originally large electromechanical devices converting AC to DC.

The input voltage, output voltage and frequency, and overall power handling depend on the design of the specific device or circuitry. The inverter does not produce any power; the power is provided by the DC source.

A power inverter can be entirely electronic or a combination of mechanical effects (such as a rotary apparatus) and electronic circuitry.

Static inverters do not use moving parts in the conversion process.

Power inverters are primarily used in electrical power applications where high currents and voltages are present; circuits that perform the same function for electronic signals, which usually have very low currents and voltages, are called oscillators.

Input and output:

Input voltage

A typical power inverter device or circuit requires a stable DC power source capable of supplying enough current for the intended power demands of the system. The input voltage depends on the design and purpose of the inverter. Examples include:

* 12 V DC, for smaller consumer and commercial inverters that typically run from a rechargeable 12 V lead acid battery or automotive electrical outlet.
* 24, 36, and 48 V DC, which are common standards for home energy systems.
* 200 to 400 V DC, when power is from photovoltaic solar panels.
* 300 to 450 V DC, when power is from electric vehicle battery packs in vehicle-to-grid systems.
* Hundreds of thousands of volts, where the inverter is part of a high-voltage direct current power transmission system.

Output waveform

An inverter may produce a square wave, sine wave, modified sine wave, pulsed sine wave, or near-sine pulse-width modulated wave (PWM) depending on circuit design. Common types of inverters produce square waves or quasi-square waves. One measure of the purity of a sine wave is the total harmonic distortion (THD). Technical standards for commercial power distribution grids require less than 3% THD in the wave shape at the customer's point of connection. IEEE Standard 519 recommends less than 5% THD for systems connecting to a power grid.

There are two basic designs for producing household plug-in voltage from a lower-voltage DC source, the first of which uses a switching boost converter to produce a higher-voltage DC and then converts to AC. The second method converts DC to AC at battery level and uses a line-frequency transformer to create the output voltage.

Square wave

A 50% duty cycle square wave is one of the simplest waveforms an inverter design can produce, but adds ~48.3% THD to its fundamental sine wave. Thus, a square wave output can produce undesired "humming" noises when connected to audio equipment and is better suited to low-sensitivity applications such as lighting and heating.

Sine wave

A power inverter device that produces a multiple step sinusoidal AC waveform is referred to as a sine wave inverter. To more clearly distinguish the inverters with outputs of much less distortion than the modified sine wave (three-step) inverter designs, the manufacturers often use the phrase pure sine wave inverter. Almost all consumer grade inverters that are sold as a "pure sine wave inverter" do not produce a smooth sine wave output at all, just a less choppy output than the square wave (two-step) and modified sine wave (three-step) inverters. However, this is not critical for most electronics as they deal with the output quite well.

Where power inverter devices substitute for standard line power, a sine wave output is desirable because many electrical products are engineered to work best with a sine wave AC power source. The standard electric utility provides a sine wave, typically with minor imperfections but sometimes with significant distortion.

Sine wave inverters with more than three steps in the wave output are more complex and have significantly higher cost than a modified sine wave, with only three steps, or square wave (one step) types of the same power handling. Switched-mode power supply (SMPS) devices, such as personal computers or DVD players, function on modified sine wave power. AC motors directly operated on non-sinusoidal power may produce extra heat, may have different speed-torque characteristics, or may produce more audible noise than when running on sinusoidal power.

Modified sine wave

The modified sine wave is the sum of two square waves, one of which is delayed one-quarter of the period with respect to the other. The result is a repeated voltage step sequence of zero, peak positive, zero, peak negative, and again zero. The resultant voltage waveform better approximates the shape of a sinusoidal voltage waveform than a single square wave. Most inexpensive consumer power inverters produce a modified sine wave rather than a pure sine wave.

If the waveform is chosen to have its peak voltage values for half of the cycle time, the peak voltage to RMS voltage ratio is the same as for a sine wave. The DC bus voltage may be actively regulated, or the "on" and "off" times can be modified to maintain the same RMS value output up to the DC bus voltage to compensate for DC bus voltage variations. By changing the pulse width, the harmonic spectrum can be changed. The lowest THD for a three-step modified sine wave is 30% when the pulses are at 130 degrees width of each electrical cycle. This is slightly lower than for a square wave.

The ratio of on to off time can be adjusted to vary the RMS voltage while maintaining a constant frequency with a technique called pulse-width modulation (PWM). The generated gate pulses are given to each switch in accordance with the developed pattern to obtain the desired output. The harmonic spectrum in the output depends on the width of the pulses and the modulation frequency. It can be shown that the minimum distortion of a three-level waveform is reached when the pulses extend over 130 degrees of the waveform, but the resulting voltage will still have about 30% THD, higher than commercial standards for grid-connected power sources. When operating induction motors, voltage harmonics are usually not of concern; however, harmonic distortion in the current waveform introduces additional heating and can produce pulsating torques.

Numerous items of electric equipment will operate quite well on modified sine wave power inverter devices, especially loads that are resistive in nature such as traditional incandescent light bulbs. Items with a switched-mode power supply operate almost entirely without problems, but if the item has a mains transformer, this can overheat depending on how marginally it is rated.

However, the load may operate less efficiently owing to the harmonics associated with a modified sine wave and produce a humming noise during operation. This also affects the efficiency of the system as a whole, since the manufacturer's nominal conversion efficiency does not account for harmonics. Therefore, pure sine wave inverters may provide significantly higher efficiency than modified sine wave inverters.

Most AC motors will run on MSW inverters with an efficiency reduction of about 20% owing to the harmonic content. However, they may be quite noisy. A series LC filter tuned to the fundamental frequency may help.

A common modified sine wave inverter topology found in consumer power inverters is as follows: An onboard microcontroller rapidly switches on and off power MOSFETs at high frequency like ~50 kHz. The MOSFETs directly pull from a low voltage DC source (such as a battery). This signal then goes through step-up transformers (generally many smaller transformers are placed in parallel to reduce the overall size of the inverter) to produce a higher voltage signal. The output of the step-up transformers then gets filtered by capacitors to produce a high voltage DC supply. Finally, this DC supply is pulsed with additional power MOSFETs by the microcontroller to produce the final modified sine wave signal.

More complex inverters use more than two voltages to form a multiple-stepped approximation to a sine wave. These can further reduce voltage and current harmonics and THD compared to an inverter using only alternating positive and negative pulses; but such inverters require additional switching components, increasing cost.

Near sine wave PWM

An example of PWM voltage modulated as a series of pulses ■. Low pass filtering with series inductors and shunt capacitors is required to suppress the switching frequency. Once filtered, this results in a near sinusoidal waveform ■. The filtering components are smaller and more convenient than those required to smooth a modified sine wave to an equivalent harmonic purity.
Some inverters use PWM to create a waveform that can be low pass filtered to re-create the sine wave. These only require one DC supply, in the manner of the MSN designs, but the switching takes place at a far faster rate, typically many kHz, so that the varying width of the pulses can be smoothed to create the sine wave. If a microprocessor is used to generate the switching timing, the harmonic content and efficiency can be closely controlled.

Output frequency

The AC output frequency of a power inverter device is usually the same as standard power line frequency, 50 or 60 hertz. The exception is in designs for motor driving, where a variable frequency results in a variable speed control.

Also, if the output of the device or circuit is to be further conditioned (for example stepped up) then the frequency may be much higher for good transformer efficiency.

Output voltage

The AC output voltage of a power inverter is often regulated to be the same as the grid line voltage, typically 120 or 240 VAC at the distribution level, even when there are changes in the load that the inverter is driving. This allows the inverter to power numerous devices designed for standard line power.

Some inverters also allow selectable or continuously variable output voltages.

Output power

A power inverter will often have an overall power rating expressed in watts or kilowatts. This describes the power that will be available to the device the inverter is driving and, indirectly, the power that will be needed from the DC source. Smaller popular consumer and commercial devices designed to mimic line power typically range from 150 to 3000 watts.

Not all inverter applications are solely or primarily concerned with power delivery; in some cases the frequency and or waveform properties are used by the follow-on circuit or device.

Additional Information:

What is an inverter?

An inverter is an electronic device that converts direct current (DC) into alternating current (AC). It is commonly used to power household appliances and electronic devices that require AC power when only DC power sources are available, such as in solar power systems or car batteries. Inverters are essential for ensuring compatibility and efficient operation of a wide range of electrical equipment in different settings.

How does an inverter work?

An inverter converts DC power into AC power using electronic circuits. It typically involves switching and modulation techniques to create an AC waveform from a DC input. These circuits can include transistors, transformers, and control systems to manage the conversion process efficiently.

What are the different types of inverters?

There are several types of inverters, including pure sine wave inverters, modified sine wave inverters, and square wave inverters. Pure sine wave inverters produce high-quality AC power, suitable for sensitive electronics. Modified sine wave inverters are more cost-effective and suitable for less sensitive devices, while square wave inverters are the least expensive but may not work with all devices.

What is the difference between an inverter and a generator?

An inverter and a generator are both used to provide power, but they operate in fundamentally different ways and serve distinct purposes. An inverter converts direct current (DC) from sources like batteries or solar panels into alternating current (AC), which is used to power household appliances and electronic devices. It relies on stored or generated DC power and is often used in renewable energy systems or as a backup power solution in conjunction with batteries. In contrast, a generator produces AC power directly by converting mechanical energy into electrical energy through the combustion of fuels such as gasoline, diesel, or natural gas. Generators are typically used for providing power during outages, in remote locations without access to the grid, or for powering heavy-duty equipment. While inverters are quiet, environmentally friendly, and efficient for small to medium loads, generators can provide higher power output and are suitable for more demanding applications but can be noisy and produce emissions.

Can an inverter be used with solar panels?

Yes, inverters are commonly used in solar power systems to convert the DC electricity generated by solar panels into AC power for use in homes and businesses. This conversion is crucial for integrating solar energy into the existing electrical grid and for powering standard household appliances.

What is the efficiency of an inverter?

The efficiency of an inverter varies depending on its design and quality. High-quality inverters can have efficiencies of 90% or higher, meaning they lose only a small percentage of energy during the conversion process. Efficiency is a critical factor, as it affects the overall performance and energy savings of the system.

How do I choose the right inverter for your needs?

To choose the right inverter, consider factors such as the total wattage of the devices you plan to power, the type of waveform required (pure sine wave or modified sine wave), and the inverter's input and output voltage compatibility. Additionally, assess the inverter's capacity, ensuring it can handle peak loads and future expansion.

Can an inverter run continuously?

Yes, many inverters are designed for continuous operation. However, it’s important to ensure that the inverter is properly rated for the load it will be handling and that it has adequate cooling to prevent overheating. Continuous operation also depends on the availability of a reliable power source, such as a well-maintained battery or solar panel array.

What safety features should an inverter have?

Important safety features for inverters include overload protection, short circuit protection, over-voltage and under-voltage protection, and thermal protection to prevent overheating. These features help protect both the inverter and connected devices from damage due to electrical faults or excessive load.

How do I maintain an inverter?

Regular maintenance of an inverter includes keeping it clean and dust-free, ensuring adequate ventilation, checking connections and wiring for wear and tear, and periodically testing the inverter’s performance. Proper maintenance extends the inverter's lifespan and ensures reliable operation.

Can an inverter be used in vehicles?

Yes, inverters are often used in vehicles to power AC devices using the vehicle’s DC battery. This is useful for camping, road trips, or running equipment that requires AC power while on the move. Vehicle inverters come in various sizes and capacities, suitable for different applications.

Can an inverter be used with a battery backup system?

Yes, an inverter can be integrated with a battery backup system to provide power during outages. The battery stores DC power, and the inverter converts it to AC power to run household appliances and electronic devices. This setup ensures continuous operation even when the main power supply is unavailable, making it ideal for critical applications and areas prone to power interruptions.

What size inverter do I need for my home?

The size of the inverter you need depends on the total wattage of the appliances and devices you plan to power. Calculate the combined wattage of all devices and choose an inverter with a capacity slightly higher than the total wattage to ensure efficient operation and to accommodate any additional load. This approach prevents overloading and extends the inverter's lifespan.

How long can an inverter run on battery power?

The runtime of an inverter on battery power depends on the capacity of the battery and the power consumption of the connected devices. Larger batteries with higher amp-hour (Ah) ratings can provide power for a longer duration. Additionally, using energy-efficient devices can help extend the runtime, allowing for more extended periods of use during power outages or off-grid scenarios.

Are there any noise concerns with using an inverter?

Most modern inverters are designed to operate quietly, but some may produce a low-level humming sound due to the internal cooling fans and electronic components. The noise level is usually minimal and should not be disruptive in a typical home environment. For those sensitive to noise, it's advisable to choose inverters specifically marketed as silent or low-noise models. These models ensure a quieter operation, suitable for use in bedrooms, offices, or other noise-sensitive areas.

When should I consider upgrading my inverter?

You might consider upgrading your inverter if you plan to power more demanding devices or multiple devices simultaneously. Additionally, if you experience issues like power fluctuations or insufficient capacity, upgrading to a more powerful or higher-quality inverter could resolve these issues.

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2395) Robert Burns Woodward

Gist:

Work

Nature is full of organic substances—a large and highly diverse array of chemical compounds that contain the basic element carbon. Building, or synthesizing, organic substances using chemical methods is important in both scientific and industrial contexts. Synthesis often entails complicated, multistep processes. Robert Woodward mastered these processes and, in the 1950s and 1960s, successfully synthesized a large number of substances: quinine, cholesterol, cortisone, several antibiotic substances, and chlorophyll, the substance that gives leaves their green color.

Summary:

Robert Burns Woodward (born April 10, 1917, Boston, Mass., U.S.—died July 8, 1979, Cambridge, Mass.) was an American chemist best known for his syntheses of complex organic substances, including cholesterol and cortisone (1951), strychnine (1954), and vitamin B12 (1971). He was awarded the Nobel Prize for Chemistry in 1965, “for his outstanding achievements in the art of organic chemistry.”

Early life and education

Woodward’s early years are often told as the story of a boy-genius. He was an autodidact who, even as a child, had a passion for chemistry. At age 14, Woodward bought a copy of Ludwig Gattermann’s Practical Methods of Organic Chemistry and requested issues of chemistry journals from Verlag Chemie of Berlin. Later in life he did nothing to discourage a persistent legend that he had performed all the experiments in Gattermann’s book.

Woodward entered the Massachusetts Institute of Technology in 1933, then lost interest in, and patience with, the undergraduate routine and dropped out. Not wishing to lose such a gifted student, James Flack Norris, an organic chemistry professor, tracked down Woodward in the food technology department. Norris interceded, and Woodward was allowed to fulfill his course requirements by examination. In just four years Woodward obtained both bachelor’s and doctoral degrees. Upon graduation, he spent the summer of 1937 at the University of Illinois, leaving in the fall to join the chemistry department at Harvard University, where he remained until his death in 1979. Woodward was married in 1938 to Irja Pullman and in 1946 to Eudoxia Muller; he had two daughters from the first marriage and a daughter and son from the second.

Scientific career

The chemistry of natural products was Woodward’s base for a broad engagement in organic chemistry. During World War II, Woodward worked on the structural elucidation of penicillin, and he and William Doering sought synthetic routes to quinine. In 1948 Woodward published the structure of strychnine, beating English chemist Robert Robinson in the competition to solve this difficult chemical puzzle. During the 1950s, Woodward collaborated with the pharmaceutical company Pfizer, Inc., on the structural analysis of a new series of antibiotics: terramycin, aureomycin, and magnamycin.

Woodward was known among his colleagues for his aggressive use of the latest analytic tools. He strongly believed in the utility of instruments such as spectrophotometers in organic synthesis. Such instruments could routinely assist the chemist in the characterization of compounds, and they suggested new generalizations about the relationship of structure to physical properties. Indeed, Woodward’s early theoretical pursuits centred on the use of two types of physical data—ultraviolet absorption (1941–42) and optical rotatory dispersion (1961). Both of these generalizations about spectra and structure created new utility for routine spectroscopic measurements. These instrumental techniques altered the traditional, complementary relationship between synthesis and structural determination and reduced the latter to a relatively commonplace procedure.

Nevertheless, Woodward’s achievements in the field of structure determination remain milestones in organic chemistry: penicillin (1945), patulin (1948), strychnine (1947), ferrocene (1952), cevine (1954), gliotoxin (1958), ellipticine (1959), calycanthine (1960), oleandomycin (1960), streptonigrin (1963), and tetrodotoxin (1964). With the American biochemist Konrad Bloch, he also first proposed the correct biosynthetic pathway to the steroid hormones in living organisms.

Woodward undertook and completed one of the first total syntheses of the steroids cholesterol and cortisone (1951) and then the related terpene lanosterol (1954). In 1954 syntheses of strychnine and lysergic acid were announced, followed in 1956 by a synthesis of reserpine that has become a model of elegant technique and has been used for the commercial production of this tranquilizer. Subsequent achievements included the synthesis of chlorophyll (1960), tetracycline (1962), colchicine (1963), and cephalosporin C (1965). In a large-scale collaboration with Albert Eschenmoser of the Federal Institute of Technology in Zürich, Woodward completed in 1971 the synthesis of the complicated coenzyme vitamin B12 (cyanocobalamin) by a sequence of more than 100 reactions. The work on vitamin B12 led to the recognition and formulation, with the American chemist Roald Hoffmann, of the concept of conservation of orbital symmetry, explicating a broad group of fundamental reactions. These Woodward-Hoffman rules were probably the most important theoretical advance of the 1960s in organic chemistry. At the time of his death, Woodward was working on the synthesis of erythromycin.

Woodward lived between the worlds of academy and industry. During his career, he held consultancies with Eli Lilly and Company, Merck & Co., Inc., Mallinckrodt Pharmaceuticals, Monsanto Company, Polaroid Corporation, and Pfizer. In 1963 Ciba (later Ciba-Geigy Ltd., now Novartis International AG), a Swiss pharmaceutical firm, set up the Woodward Research Institute in Basel. He then held dual appointments as director of the institute and as Donner Professor of Science at Harvard. Between Basel and Cambridge, more than 400 graduate and postdoctoral students trained in Woodward’s laboratories.

The Woodward style

Woodward’s talks and lectures on organic chemistry were fastidious, well prepared, and long. Careful precision was the hallmark of his chemical work as well. Woodward was known for his innovative thinking on the theory of organic chemistry. Throughout his career, he demonstrated that the understanding of chemical reaction mechanisms made possible the planning and successful execution of extended sequences of reactions to build up complex compounds. The requisite intellectual discipline, largely initiated by Woodward, did indeed become a major endeavour in organic chemistry.

Woodward’s genius lay not in the creation of new reagents—that is, new synthetic methods—but in his power to marshal all the available facts and solve even the most intricate of puzzles. He had an enormous capacity for information and superb mental organization. Given the set of data on a structure or the planning of a synthesis, Woodward brought to bear a most remarkable ability to see the entire problem at once and to solve it systematically. His brilliance lay in the quality and depth of his thought, his painstaking preparations, and his chemical intuition. Woodward’s work was central to the chemical thought of the times, and his influence on other organic chemists was arguably greater than that of any other in his era.

Details

Robert Burns Woodward (April 10, 1917 – July 8, 1979) was an American organic chemist. He is considered by many to be the preeminent synthetic organic chemist of the twentieth century, having made many key contributions to the subject, especially in the synthesis of complex natural products and the determination of their molecular structure. He worked closely with Roald Hoffmann on theoretical studies of chemical reactions. He was awarded the Nobel Prize in Chemistry in 1965.

Early life and education

Woodward was born in Boston, Massachusetts, on April 10, 1917. He was the son of Margaret Burns (an immigrant from Scotland who claimed to be a descendant of the poet, Robert Burns) and her husband, Arthur Chester Woodward, himself the son of Roxbury apothecary, Harlow Elliot Woodward.

His father was one of the many victims of the 1918 influenza pandemic.

From a very early age, Woodward was attracted to and engaged in private study of chemistry while he attended a public primary school, and then Quincy High School, in Quincy, Massachusetts. By the time he entered high school, he had already managed to perform most of the experiments in Ludwig Gattermann's then widely used textbook of experimental organic chemistry. In 1928, Woodward contacted the Consul-General of the German consulate in Boston (Baron von Tippelskirch), and through him, managed to obtain copies of a few original papers published in German journals. Later, in his Cope lecture, he recalled how he had been fascinated when, among these papers, he chanced upon Diels and Alder's original communication about the Diels–Alder reaction. Throughout his career, Woodward was to repeatedly and powerfully use and investigate this reaction, both in theoretical and experimental ways. In 1933, he entered the Massachusetts Institute of Technology (MIT), but neglected his formal studies badly enough to be excluded at the end of the 1934 fall term. MIT readmitted him in the 1935 fall term, and by 1936 he had received the Bachelor of Science degree. Only one year later, MIT awarded him the doctorate, when his classmates were still graduating with their bachelor's degrees. Woodward's doctoral work involved investigations related to the synthesis of the female sex hormone estrone. MIT required that graduate students have research advisors. Woodward's advisors were James Flack Norris and Avery Adrian Morton, although it is not clear whether he actually took any of their advice. After a short postdoctoral stint at the University of Illinois, he took a Junior Fellowship at Harvard University from 1937 to 1938, and remained at Harvard in various capacities for the rest of his life. In the 1960s, Woodward was named Donner Professor of Science, a title that freed him from teaching formal courses so that he could devote his entire time to research.

Research and career:

Early work

The first major contribution of Woodward's career in the early 1940s was a series of papers describing the application of ultraviolet spectroscopy in the elucidation of the structure of natural products. Woodward collected together a large amount of empirical data, and then devised a series of rules later called the Woodward's rules, which could be applied to finding out the structures of new natural substances, as well as non-natural synthesized molecules. The expedient use of newly developed instrumental techniques was a characteristic Woodward exemplified throughout his career, and it marked a radical change from the extremely tedious and long chemical methods of structural elucidation that had been used until then.

In 1944, with his post doctoral researcher, William von Eggers Doering, Woodward reported the synthesis of the alkaloid quinine, used to treat malaria. Although the synthesis was publicized as a breakthrough in procuring the hard to get medicinal compound from Japanese occupied southeast Asia, in reality it was too long and tedious to adopt on a practical scale. Nevertheless, it was a landmark for chemical synthesis. Woodward's particular insight in this synthesis was to realize that the German chemist Paul Rabe had converted a precursor of quinine called quinotoxine to quinine in 1905. Hence, a synthesis of quinotoxine (which Woodward actually synthesized) would establish a route to synthesizing quinine. When Woodward accomplished this feat, organic synthesis was still largely a matter of trial and error, and nobody thought that such complex structures could actually be constructed. Woodward showed that organic synthesis could be made into a rational science, and that synthesis could be aided by well-established principles of reactivity and structure. This synthesis was the first one in a series of exceedingly complicated and elegant syntheses that he would undertake.

Later work and its impact

Culminating in the 1930s, the British chemists Christopher Ingold and Robert Robinson among others had investigated the mechanisms of organic reactions, and had come up with empirical rules which could predict reactivity of organic molecules. Woodward was perhaps the first synthetic organic chemist who used these ideas as a predictive framework in synthesis. Woodward's style was the inspiration for the work of hundreds of successive synthetic chemists who synthesized medicinally important and structurally complex natural products.

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