Carnegie, Rockefeller, Ford, Westinghouse, Boeing, Gates and Tariffs

Posted by PITHOCRATES - September 10th, 2013

History 101

Ford brought the Price of Cars down and Paid his Workers more without Tariff Protection

Andrew Carnegie grew a steel empire in the late 19th century.  With technological innovation.  He made the steel industry better.  Making steel better.  Less costly.  And more plentiful.  Carnegie’s steel built America’s skylines.  Allowing our buildings to reach the sky.  And Carnegie brought the price of steel down without tariff protection.

John D. Rockefeller saved the whales.  By making kerosene cheap and plentiful.  Replacing whale oil pretty much forever.  Then found a use for another refined petroleum product.  Something they once threw away.  Gasoline.  Which turned out to be a great automotive fuel.  It’s so great that we use it still today.  Rockefeller made gasoline so cheap and plentiful that he put the competition out of business.  He was making gasoline so cheap that his competition went to the government to break up Standard Oil.  So his competition didn’t have to sell at his low prices.  And Rockefeller made gasoline so inexpensive and so plentiful without tariff protection.

Henry Ford built cars on the first moving assembly line.  Greatly bringing the cost of the car down.  Auto factories have fixed costs that they recover in the price of the car.  The more cars a factory can make in a day allows them to distribute those fixed costs over more cars.  Bringing the cost of the car down.  Allowing Henry Ford to do the unprecedented and pay his workers $5 a day.  Allowing his workers to buy the cars they assembled.  And Ford brought the price of cars down and paid his workers more without tariff protection.

George Westinghouse decreased the Cost of Electric Power without Tariff Protection

George Westinghouse gave us AC power.  Thanks to his brilliant engineer.  Nikola Tesla.  Who battled his former employer, Thomas Edison, in the Current Wars.  Edison wanted to wire the country with his DC power.  Putting his DC generators throughout American cities.  While Westinghouse and Tesla wanted to build fewer plants and send their AC power over greater distances.  Greatly decreasing the cost of electric power.  Westinghouse won the Current Wars.  And Westinghouse did that without tariff protection.

After losing out on a military contract for a large military transport jet Boeing regrouped and took their failed design and converted it into a jet airliner.  The Boeing 747.  Which dominated long-haul routes.  Having the range to go almost anywhere without refueling.  And being able to pack so many people into a single airplane that the cost per person to fly was affordable to almost anyone that wanted to fly.  And Boeing did this without tariff protection.

Bill Gates became a billionaire thanks to his software.  Beginning with DOS.  Then Windows.  He dominated the PC operating system market.  And saw the potential of the Internet.  Bundling his browser program, Internet Explorer, with his operating system.  Giving it away for free.  Consumers loved it.  But his competition didn’t.  As they saw a fall in sales for their Internet browser programs.  With some of their past customers preferring to use the free Internet Explorer instead of buying another program.  Making IE the most popular Internet browser on the market.  And Gates did this without tariff protection.

Tariff Protection cost American Industries Years of Innovation and Cost Cutting Efficiencies

Carnegie Steel became U.S. Steel.  Which grew to be the nation’s largest steel company.  Carnegie had opposed unions to keep the cost of his steel down.  U.S. Steel had a contentious relationship with labor.  During the Great Depression U.S. Steel unionized.  But there was little love between labor and management.  There were a lot of strikes.  And a lot of costly union contracts.  Which raised the price of U.S. manufactured steel.  Opening the door for less costly foreign imports.  Which poured into the country.  Taking a lot of business away from domestic steel makers.  Making it more difficult to honor those costly union contracts.  Which led the U.S. steel producers to ask the government for tariff protection.  To raise the price of the imported steel so steel consumers would not have a less costly alternative.

During World War II FDR was printing so much money to pay for both the New Deal and the war the FDR administration was worried about inflation.  So they put ceilings on what employers could pay their employees.  With jobs paying the same it was difficult to attract the best employees.  Because you couldn’t offer more pay.  So General Motors started offering benefits.  Health care.  And pensions.  Agreeing to very generous union contracts.  Raising the price of cars.  Which wasn’t a problem until the imports hit our shores.  Then those union contracts became difficult to honor.  Which led the U.S. auto makers to ask the government for tariff protection.  To raise the price of those imported cars so Americans would not have a less costly alternative.

These two industries received their tariffs.  And other government protections.  Allowing them to continue with business as usual.  Even though business as usual no longer worked.  So while the foreign steel producers and auto makers advanced their industries to further increase quality and lower their costs the protected U.S. companies did not.  Because they didn’t have to.  For thanks to the government they didn’t have to please their customers.  As the government simply forced people to be their customers.  For awhile, at least.  The foreign products became better and better such that the tariff protection couldn’t make the higher quality imports costly enough to keep them less attractive than the inferior American goods.  With a lot of people even paying more for the better quality imports.  Losing years of innovation and cost cutting efficiencies due to their tariff protection these American industries that once dominated the world became shells of their former selves.  With General Motors and Chrysler having to ask the government for a bailout because of the health care and pension costs bankrupting them.  Something Carnegie, Rockefeller, Ford, Westinghouse, Boeing or Gates never had to ask.

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DC Power Supply

Posted by PITHOCRATES - February 13th, 2013

Technology 101

Every DC Power Supply has a Transformer, a Rectifier Circuit and a Voltage Regulation Circuit

Alternating current (AC) power is one of the greatest technological developments of mankind.  It gives us the modern world we live in.  We can transmit it over very long distances.  Allowing a few power plants to power large geographic areas.  Something Thomas Edison’s direct current (DC) power just couldn’t do.  Which is a big reason why he lost the War of Currents to George Westinghouse and Nikola Tesla.  AC power also allows the use of transformers.  Allowing us to take the one voltage produced by a power plant and convert it to any voltage we need.

AC power can power our home lighting.  Our air conditioning.  Our electric stove.  Our refrigerator.  Our doorbell.  Pretty much all of the non-fun things in our house.  Things with electric motors in them.  Heating elements.  Or solenoids.  But one thing AC power can’t do is power the fun things in our homes.  Televisions.  Our audio equipment.  Our cable/satellite boxes.  Pretty much anything that doesn’t have an electric motor, heating element or solenoid in it.  These things that process information or audio and video signals.  Or all of the above.  Things that have circuit boards.  With electronic components.  The kind of things that only work with DC power.

Of course all of these things in our homes plug into AC wall receptacles.  Even though they are DC devices.  So what gives?  How can we use AC power to operate DC devices?  With a little something we call a DC power supply.  And every one of those fun things has one.  Either one built-in.  Or an external power pack at the end of a cord.  Every DC power supply has three parts.  There is a transformer to step down the AC voltage.  A rectifier circuit.  And a voltage regulation circuit.

A Diode is a Semiconductor Device that allows a Current to pass through when there is a Forward Bias

The typical electrical receptacle in a house is 120 volt AC.  An AC power cord brings that into our electronic devices.  And the first thing it connects to is a transformer.  Such as a 120:24 volt transformer.  Which steps the 120 volts down to 24 volts AC.  Where the waveform looks like this.

DC Power Supply AC Input

The voltage of AC power rises and falls.  It starts at zero.  Rises to a maximum positive voltage.  Then falls through zero to a maximum negative voltage.  Then rises back to zero.  This represents one cycle.  It does this 60 times a second.  (In North America, at least.  In Europe it’s 50 times a second.)  As most electronic devices are made from semiconductors this is a problem.  For semiconductor devices use low DC voltages to cause current to flow through PN junctions.  A voltage that swings between positive and negative values would only make those semiconductor devices work half of the time.  Sort of like a fluorescent light flickering in the cold.  Only these circuits wouldn’t work that well.  No, to use these semiconductors we need to first get rid of those negative voltages.  By rectifying them to positive voltages.  When we do we get a waveform that looks like this.

DC Power Supply Rectified

A diode is a semiconductor device that allows a current to pass through when there is a forward bias.  And it blocks current from passing through when there is a reverse bias.  An alternating voltage across a diode alternates the bias back and forth between forward bias and reverse bias. Using one diode would produce a waveform like in the first graph above only without the negative parts.  If we use 4 diodes to make a bridge rectifier we can take those negative voltages and make them positive voltages.  Basically flipping the negative portion of the AC waveform to the positive side of the graph.  So it looks like the above waveform.

All Electronic Devices have a Section built Inside of them called a Power Supply

The rectified waveform is all positive.  There are no negative voltages.  But the voltage is more of a series of pulses than a constant voltage.  Varying between 0 and 24 volts.  But our electronic devices need a constant voltage.  So the next step is to smooth this waveform out a little.  And we can do this by adding a capacitor to the output of the bridge rectifier.  Which sort of acts like a reservoir.  It stores charge at higher voltages.   And releases charge at lower voltages.  As it does it smooths out the waveform of our rectified voltage.  Making it less of a series of pulses and more of a fluctuating voltage above and below our desired output voltage.  And looks sort of like this.

DC Power Supply Capacitor

This graph is exaggerated a little to show clearly the sinusoidal waveform.  In reality it may not fluctuate quite so much.  And the lowest voltage would not fall below the rated DC output of the DC power supply.  Please note that now we have a voltage that is always positive.  And never zero.  As well as fluctuating in a sinusoidal waveform at twice the frequency of the original voltage.  The last step in this process is voltage regulation.  Another semiconductor device.  Typically some transistors forming a linear amplifier.  Or an integrated circuit with three terminals.  An input, an output and a ground.  We apply the above waveform between the input and ground.  And these semiconductor devices will change voltage and current through the device to get the following output voltage (for a 12 volt DC power supply).

DC Power Supply DC Output

All electronic devices that plug into a wall outlet with a standard AC power cord have a section built inside of them called a power supply.  (Or there is an external power supply.  Small ones that plug into wall outlets.  Or bigger ones that are located in series with the power cord.)  And this is what happens inside the power supply.  It takes the 120 volt AC and converts it to 12 volts DC (or whatever DC voltage the device needs).  Wires from this power supply go to other circuit boards inside these electronic devices.  Giving the electronic components on these circuit boards the 12 volt DC power they need to operate.  Allowing us to watch television, listen to music or surf the web.

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Electric Power, Alternating Current, Transformers, Magnetic Flux, Turns Ratio, Electric Panel and Circuit Breakers

Posted by PITHOCRATES - February 6th, 2013

Technology 101

AC Power is Superior to DC Power because it can Travel Farther and it Works with Transformers

Thanks to Nikola Tesla and his alternating current electric power we live in the world we have today.  The first electric power was direct current.  The stuff that Thomas Edison gave us.  But it had some serious drawbacks.  You needed a generator for each voltage you used.  The low-voltage of telephone systems would need a generator.  The voltage we used in our homes would need another generator.  And the higher voltages we used in our factories and businesses would need another generator.  Requiring a lot of power cables to hang from power poles along our streets.  Almost enough to block out the sun.

Another drawback is that direct currents travel a long way.  And spend a lot of time moving through wires.  Generating heat.  And dropping some power along the way due to the resistance in the wires.  Greatly minimizing the area a power plant can provide power to.  Requiring many power plants in our cities and suburbs.  Just imagine having three coal-fired power plants around your neighborhood.  The logistics and costs were just prohibitive for a modern electric world.  Which is why Thomas Edison lost the War of Currents to Nikola Tesla.

So why is alternating current (AC) superior to direct current (DC) for electric power?  AC is more like a reciprocating motion in an internal combustion engine or a steam locomotive.  Where short up & down and back & forth motion is converted into rotation motion.  Alternating current travels short distances back and forth in the power cables.  Because they travel shorter distances in the wires they lose less power in power transmission.  In fact, AC power lines can travel great distances.  Allowing power plants tucked away in the middle of nowhere power large geographic areas.  But there is another thing that makes AC power superior to DC power.  Transformers.

The Voltage induced onto the Secondary Windings is the Primary Voltage multiplied by the Turns Ratio

When an alternating current flows through a coiled wire it produces an alternating magnetic flux.  Magnetic flux is a measure of the strength and concentration of the magnetic field created by that current.  When this flux passes through another coiled wire it induces a voltage on that coil.  This is a transformer.  A primary and secondary winding where an alternating current applied on the primary winding induces a voltage on the secondary winding.  Allowing you to step up or step down a voltage.  Allowing one generator to produce one voltage.  While transformers throughout the power distribution network can produce the many voltages needed for doorbells, electrical outlets in our homes and the equipment in our factories and businesses.  And any other voltage for any other need.

We accomplish this remarkable feat by varying the number of turns in the windings.  If the number of turns is equal in the primary and the secondary windings then so is the voltage.  If the number of turns in the primary windings is greater than the number of turns in the secondary windings the transformer steps down the voltage.  If the number of turns in the secondary windings is greater than the number of turns in the primary windings the transformer steps up the voltage.  To determine the voltage induced onto the secondary windings we divide the secondary turns by the primary turns.  Giving us the turns ratio.  Multiplying the turns ratio by the voltage applied to the primary windings gives us the voltage on the secondary windings.  (Approximately.  There are some losses.  But for the sake of discussion assume ideal conditions.)

If the turns ratio is 20:1 it means the number of turns on the primary windings is twenty times the turns on the secondary windings.  Which means the voltage on the primary windings will be twenty times the voltage on the secondary windings.  Making this a step-down transformer.  So if you connected 4800 volts to the primary windings the voltage across the secondary windings will be 240 volts (4800/20).  If you attached a wire to the center of the secondary coil you can get both a 20:1 turns ratio and a 40:1 turns ratio.  If you measure a voltage across the entire secondary windings you will get 240 volts.  If you measure from the center of the secondary and either end of the secondary windings you will get 120 volts.

The Power Lines running to your House are Two Insulated Phase Conductors and a Bare Neutral Conductor

This is a common transformer you’ll see atop a pole in your backyard.  Where it is common to have 4800-volt power lines running at the top of poles running between houses.  On some of these poles you will see a transformer mounted below these 4800-volt lines.  The primary windings of these transformers connect to the 4800-volt lines.  And three wires from the secondary windings connect to wires running across these poles below the transformers.  Two of these wires (phase conductors) connect to either end of the secondary windings.  Providing 240 volts.  The third wire attaches to the center of the secondary windings (the neutral conductor).  We get 120 volts between a phase conductor and the neutral conductor.

The power lines running to your house are three conductors twisted together in a triplex cable.  Two insulated phase conductors.  And a bare neutral conductor.  These enter your house and terminate in an electric panel.  The two phase conductors connect to two bus bars inside the panel.  The neutral conductor connects to a neutral bus inside the panel.  Each bus feeds circuit breaker positions on both sides of the panel.  The circuit breaker positions going down the left side of the panel alternate between the two buss bars.  Ditto for the circuit breaker positions on the right side.

A single-pole circuit breaker attaches to one of the bus bars.  Then a wire from the circuit breaker and a wire from the neutral bus leave the panel and terminate at an electrical load.  Providing 120 volts to things like wall receptacles where you plug things into.  And your lighting.  A 2-pole circuit breaker attaches to both bus bars.  Then two wires from the circuit breaker leave the panel and attach to an electrical load.  Providing 240 volts to things like an electric stove or an air conditioner.  Then a reciprocating (push-pull) alternating current runs through these electric loads.  Driven by the push-pull between the two bus bars.  And between a bus bar and the neutral bus.  Which is driven by the push-pull between the conductors of the triplex cable.  Driven by the push pull of secondary windings in the transformer.  Driven by the push-pull of the primary windings.  Driven by the push-pull in the primary cables connected to the primary windings.  And all the way back to the push-pull of the electric generator.  All made possible thanks to Nikola Tesla.  And his alternating current electric power.

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The Horse, Waterwheel, Steam Engine, Electricity, DC and AC Power, Power Transmission and Electric Motors

Posted by PITHOCRATES - December 26th, 2012

Technology 101

(Original published December 21st, 2011)

A Waterwheel, Shaft, Pulleys and Belts made Power Transmission Complex

The history of man is the story of man controlling and shaping our environment.  Prehistoric man did little to change his environment.  But he started the process.  By making tools for the first time.  Over time we made better tools.  Taking us into the Bronze Age.  Where we did greater things.  The Sumerians and the Egyptians led their civilization in mass farming.  Created some of the first food surpluses in history.  In time came the Iron Age.  Better tools.  And better plows.  Fewer people could do more.  Especially when we attached an iron plow to one horsepower.  Or better yet, when horses were teamed together to produce 2 horsepower.  3 horsepower.  Even 4 horsepower.  The more power man harnessed the more work he was able to do.

This was the key to controlling and shaping our environment.  Converting energy into power.  A horse’s physiology can produce energy.  By feeding, watering and resting a horse we can convert that energy into power.  And with that power we can do greater work than we can do with our own physiology.  Working with horse-power has been the standard for millennia.  Especially for motive power.  Moving things.  Like dragging a plow.  But man has harnessed other energy.  Such as moving water.  Using a waterwheel.  Go into an old working cider mill in the fall and you’ll see how man made power from water by turning a wheel and a series of belts and pulleys.  The waterwheel turned a main shaft that ran the length of the work area.  On the shaft were pulleys.  Around these pulleys were belts that could be engaged to transfer power to a work station.  Where it would turn another pulley attached to a shaft.  Depending on the nature of the work task the rotational motion of the main shaft could be increased or decreased with gears.  We could change it from rotational to reciprocating motion.  We could even change the axis of rotation with another type of gearing.

This was a great step forward in advancing civilization.  But the waterwheel, shaft, pulleys and belts made power transmission complex.  And somewhat limited by the energy available in the moving water.  A great step forward was the steam engine.  A large external combustion engine.  Where an external firebox heated water to steam.  And then that steam pushed a piston in a cylinder.  The energy in expanding steam was far greater than in moving water.  It produced far more power.  And could do far more work.  We could do so much work with the steam engine that it kicked off the Industrial Revolution.

Nikola Tesla created an Electrical Revolution using AC Power

The steam engine also gave us more freedom.  We could now build a factory anywhere we wanted to.  And did.  We could do something else with it, too.  We could put it on tracks.  And use it to pull heavy loads across the country.  The steam locomotive interconnected the factories to the raw materials they consumed.  And to the cities that bought their finished goods.  At a rate no amount of teamed horses could equal.  Yes, the iron horse ended man’s special relationship with the horse.  Even on the farm.  Where steam engines powered our first tractors.  Giving man the ability to do more work than ever.  And grow more food than ever.  Creating greater food surpluses than the Sumerians and Egyptians could ever grow.  No matter how much of their fertile river banks they cultivated.  Or how much land they irrigated.

Steam engines were incredibly powerful.  But they were big.  And very complex.  They were ideal for the farm and the factory.  The steam locomotive and the steamship.  But one thing they were not good at was transmitting power over distances.  A limitation the waterwheel shared.  To transmit power from a steam engine required a complicated series of belts and pulleys.  Or multiple steam engines.  A great advance in technology changed all that.  Something Benjamin Franklin experimented with.  Something Thomas Edison did, too.  Even gave us one of the greatest inventions of all time that used this new technology.  The light bulb.  Powered by, of course, electricity.

Electricity.  That thing we can’t see, touch or smell.  And it moves mysteriously through wires and does work.  Edison did much to advance this technology.  Created electrical generators.  And lit our cities with his electric light bulb.  Electrical power lines crisscrossed our early cities.  And there were a lot of them.  Far more than we see today.  Why?  Because Edison’s power was direct current.  DC.  Which had some serious drawbacks when it came to power transmission.  For one it didn’t travel very far before losing much of its power. So electrical loads couldn’t be far from a generator.  And you needed a generator for each voltage you used.  That adds up to a lot of generators.  Great if you’re in the business of selling electrical generators.  Which Edison was.  But it made DC power costly.  And complex.  Which explained that maze of power lines crisscrossing our cities.  A set of wires for each voltage.  Something you didn’t need with alternating current.  AC.  And a young engineer working for George Westinghouse was about to give Thomas Edison a run for his money.  By creating an electrical revolution using that AC power.  And that’s just what Nikola Tesla did.

Transformers Stepped-up Voltages for Power Transmission and Stepped-down Voltages for Electrical Motors

An alternating current went back and forth through a wire.  It did not have to return to the electrical generator after leaving it.  Unlike a direct current ultimately had to.  Think of a reciprocating engine.  Like on a steam locomotive.  This back and forth motion doesn’t do anything but go back and forth.  Not very useful on a train.  But when we convert it to rotational motion, why, that’s a whole other story.  Because rotational motion on a train is very useful.  Just as AC current in transmission lines turned out to be very useful.

There are two electrical formulas that explain a lot of these developments.  First, electrical power (P) is equal to the voltage (V) multiplied by the current (I).  Expressed mathematically, P = V x I.  Second, current (I) is equal to the voltage (V) divided by the electrical resistance (R).  Mathematically, I = V/R.  That’s the math.  Here it is in words.  The greater the voltage and current the greater the power.  And the more work you can do.  However, we transmit current on copper wires.  And copper is expensive.  So to increase current we need to lower the resistance of that expensive copper wire.  But there’s only one way to do that.  By using very thick and expensive wires.  See where we’re going here?  Increasing current is a costly way to increase power.  Because of all that copper.  It’s just not economical.  So what about increasing voltage instead?  Turns out that’s very economical.  Because you can transmit great power with small currents if you step up the voltage.  And Nikola Tesla’s AC power allowed just that.  By using transformers.  Which, unfortunately for Edison, don’t work with DC power.

This is why Nikola Tesla’s AC power put Thomas Edison’s DC power out of business.  By stepping up voltages a power plant could send power long distances.  And then that high voltage could be stepped down to a variety of voltages and connected to factories (and homes).  Electric power could do one more very important thing.  It could power new electric motors.  And convert this AC power into rotational motion.  These electric motors came in all different sizes and voltages to suit the task at hand.  So instead of a waterwheel or a steam engine driving a main shaft through a factory we simply connected factories to the electric grid.  Then they used step-down transformers within the factory where needed for the various work tasks.  Connecting to electric motors on a variety of machines.  Where a worker could turn them on or off with the flick of a switch.  Without endangering him or herself by engaging or disengaging belts from a main drive shaft.  Instead the worker could spend all of his or her time on the task at hand.  Increasing productivity like never before.

Free Market Capitalism gave us Electric Power, the Electric Motor and the Roaring Twenties

What electric power and the electric motor did was reduce the size and complexity of energy conversion to useable power.  Steam engines were massive, complex and dangerous.  Exploding boilers killed many a worker.  And innocent bystander.  Electric power was simpler and safer to use.  And it was more efficient.  Horses were stronger than man.  But increasing horsepower required a lot of big horses that we also had to feed and care for.  Electric motors are smaller and don’t need to be fed.  Or be cleaned up after, for that matter.

Today a 40 pound electric motor can do the work of one 1,500 pound draft horse.  Electric power and the electric motor allow us to do work no amount of teamed horses can do.  And it’s safer and simpler than using a steam engine.  Which is why the Roaring Twenties roared.  It was in the 1920s that this technology began to power American industry.  Giving us the power to control and shape our environment like never before.  Vaulting America to the number one economic power of the world.  Thanks to free market capitalism.  And a few great minds along the way.

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Silicon, Semiconductor, LED, Photon, Photovoltaic Effect, Photocell, Solar Panel, Converter, Battery and Solar Power Plant

Posted by PITHOCRATES - July 4th, 2012

Technology 101

A Photocell basically works like a Light Emitting Diode (LED) in Reverse

Solar power is based on the same technology that that gave us the electronic world.  Silicon.  That special material in the periodic table that has four electrons in its valence (i.e., outer most) shell.  And four holes that can accept an electron.  Allowing it to form a perfect silicon crystal.  When these silicon atoms come together their four valence electrons form covalent bonds with the holes in neighboring silicon atoms.  These silicon atoms share their valence electrons so that each silicon atom now has a full valence shell of eight electrons (with four of their own electrons and four shared electrons).  Making that perfect crystal structure.  Which is pretty much useless in the world of semiconductors.  Because you need free electrons to conduct electricity.

When we add impurities (called ‘doping’) to silicon is where the magic starts.  If we add a little bit of an element with five electrons in its valence shell we introduce free electrons into the silicon crystal.  Giving it a negative charge.  If we instead add a little bit of an element with 3 electrons in its valence shell we introduce extra holes looking for an electron to fill it.  Giving it a positive charge.  When we bring the positive (P) and the negative (N) materials together they from a P-N junction.  The free electrons cross the junction to fill the nearby holes.  Creating a neutrally charged depletion zone between the P and the N material.  This is a diode.  If we apply a forward biased voltage (positive battery terminal to the P side and the negative battery terminal to the N side) across this junction current will flow.  Like charges repel each other.  The negative charge pushes the free electrons on the N side of the junction towards the junction.  And the positive charge pushes the holes on the P side of the junction towards the junction.  Where they meet.  With free electrons filling available holes causing current to flow.  A reverse bias does the reverse.  Pulls the holes and electrons away from the junction so they can’t combine and cause current to flow.

It takes energy to move an electron out of its ‘hole’.  And when an electron combines with a hole it emits energy.  Typically this energy is not in a visible wavelength so we see nothing.  However, with the proper use of materials we can shift this wave length into the visible spectrum.  So we can see light.  Or photons.  This is the principle behind the light emitting diode.  Or LED.  An electric current through a P-N junction causes electrons to leave their holes and then recombine with holes.  And when they recombine they give off a photon in the visible spectrum of light.  Which is what we see.  A photocell basically works the other way.  Instead of using voltage and current to create photons we use photons from the sun to create voltage and current.

A Solar Array that could Produce 12,000 Watts under Ideal Conditions may only Produce 2,400 Watts in Reality

When we use the sun to bump electrons free from their shells we call this the photovoltaic (PV) effect.  This produces a small direct current (DC) at a low voltage.  A PV cell (or solar cell) then is basically a battery when hit with sunlight.  Electric power is the product of voltage and current.  So a small DC current and a low voltage won’t power much.  So like batteries in a flashlight we have to connect solar cells together to increase the available power.  So we connect solar cells into modules and modules into arrays.  Or what we commonly call solar panels.  Small panels can power small loads.  Like emergency telephones along the highway that are rarely used.  To channel buoys that can charge a battery during the day to power a light at night.  And, of course, the electronics on our spacecraft.  Where PV cells are very useful as there are no utility lines that run into space.

These work well for small loads.  Especially DC loads.  But it gets a little complicated for AC loads.  The kind we have in our homes.  A typical 1,000 square foot home may have a 100 amp electric service at 240 volts.  Let’s assume that at any given time there could be as much as half of that service (50 amps) in use at any one time.  That’s 12,000 watts.  Assuming a solar panel array generates about 10 watts per square foot that means this house would need approximately 1,200 square feet of solar panels (such as a 60 foot by 20 foot array or a 40 foot by 30 foot array).  But it’s not quite that simple.

The sun doesn’t shine all of the time.  The capacity factor (the percentage of actual power produced divided by the total possible it could produce under the ideal conditions) is only about 15-20%.  Meaning that a 1,200 square foot solar array that could produce 12,000 watts under ideal conditions may only produce 2,400 watts (at a 20% capacity factor).  Dividing this by 120 volts gives you 20 amps.  Or approximately the size of a single circuit in your electrical panel.  Which won’t power a lot.  And it sure won’t turn on your air conditioner.  Which means you’re probably not going to be able to disconnect from the electric grid by adding solar panels to your house.  You may reduce the amount of electric power you buy from your utility but it will come at a pretty steep cost.

Solar Power Plants can be Costly to Build and Maintain even if the Fuel is Free 

Everything in your house that uses electricity either plugs into a standard 120V electrical outlet, a special purpose 240V outlet (such as an electric stove) or is hard-wired to a 240V circuit (such as your central air conditioner).  All of these circuits go back to your electrical panel.  Which is wired to a 240V AC electrical service.  A lot of electronic devices actually operate on DC power but even these still plug into an AC outlet.  Inside these devices there is a power supply that converts the AC power into DC power.  So you’ll need to convert all that DC power generated by solar panels into useable AC power with a converter.  Which is costly.  And reduces the efficiency of the solar panels.  Because when you convert energy you always end up with less than you started with.  The electronics in the converters will heat up and dissipate some of that generated electric power as heat.  If you want to use any of this power when the sun isn’t shining you’ll need a battery to store that energy.  Another costly device.  Another place to lose some of that generated electric power.  And something else to fail.

We typically build large scale solar power plants in the middle of nowhere so there is nothing to shade these solar panel arrays.  From sun up to sun down they are in the sunlight.  They even turn and track the sun as it rises overhead, travels across the sky and sets.  To maximize the amount of sunlight hitting these panels.  Of course the larger the installation the larger the maintenance.  And the panels have to be clean.  That means washing these arrays to keep them dirt and bird poop free.  Some of the biggest plants in service today have about 200 MW of installed solar arrays.  One of the largest is in India.  Charanka Solar Park.  When completed it will have 500 MW of PV arrays on approximately 7.7 square miles of land.  With a generous capacity factor of 30% that comes to 150 MW.  Or about 19 MW/square mile.  The coal-fired Robert W. Scherer Electric Generating Plant in Georgia, on the other hand, generates 3,520 MW on approximately 18.75 square miles.  At a capacity factor of about 90% for coal that comes to about 3,168 MW.  Or about 169 MW/square mile.  About 9 times more power generated per square mile of land used.

 So you can see the reason why we use so much coal to generate our electric power.  Because coal is a highly concentrated source of fuel.  The energy it releases creates a lot of reliable electricity.  Day or night.  Summer or winter.  A large coal-fired electric generating facility needs a lot of real estate but the plants themselves don’t.  Unlike a solar plant.  Where the only way to generate more power is to cover more land with PV solar panels.  To generate, convert and store as much electric power as possible.  All with electronic equipment full of semiconductors that don’t operate well in extreme temperatures (which is why our electronics have vents, heat sinks and cooling fans).  So the ideal conditions to produce electricity are not the ideal conditions for the semiconductors making it all work.  Causing performance and maintenance issues.  Which makes these plants very costly.  Even if the fuel is free. 

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Windmills, Rotational Energy, Wing, Lift, Rotary Wing, Angle of Attack, Variable-Pitch Propellers, Drag, AC Power and Wind Turbine

Posted by PITHOCRATES - June 27th, 2012

Technology 101

When an Aircraft Rotates for Takeoff it increases the Angle of Attack of the Wing to Create more Lift

Early windmills turned when the wind pushed a sail or vane.  Thereby converting wind energy into rotational energy.  Mechanical linkages and shafts transferred this rotational motion to power a mill.  Or pump water.  As well as an assortment of other tasks.  Whatever the task it was important to regulate the speed at which the shaft rotated.  Which meant turning the windmill into the wind.  And adjusting the amount of sail catching the wind.  Much like on a sailing ship.  At first by shutting the windmill down and manually adjusting the sails.  Then later automating this process while the windmill was turning.  If the winds were too strong they’d lock the windmill to prevent it from turning.  To prevent damaging the windmill.

They regulated the speed to protect the equipment attached to the windmill, too.  To prevent a mill stone from spinning too fast.  Risking damage to it.  And harm to the people working with the equipment.  Or to protect a water pump form pumping too fast.  Even the small farm windmills had over-speed protection.   These sat atop a well.  The windmill drove a small piston to pump the water up the well shaft.  To prevent this windmill from flying apart in high winds over-speed features either furled the blades or rotated the windmill parallel to the wind.  Shutting the pump down.

But wind just doesn’t push.  It can also lift.  A lateen (triangular) sail on a sailing vessel is similar to an aircraft wing.  The leading edge of the sail splits the wind apart.  Part of it fills the sail and pushes it.  Bowing it out into a curved surface.  The wind passing on the other side of the sail travels across this curved surface and creates lift.  Similar to how a wing operates during takeoff on a large aircraft.  With the trailing edge flaps extended it creates a large curve in the wing.  When the aircraft rotates (increasing the angle of attack of the wing) to take off wind passing under the wing pushes it up.  And the wind travelling over the wing pulls it up.  These lift forces are so strong that planes carry their fuel in the wings and mount engines on the wing to keep the wings from bending up too much from these forces of lift.

A Pilot will Feather the Propeller on a Failed Engine in Flight to Minimize Drag 

When an aircraft carrier launches its aircraft it turns into the wind.  To maximize the wind speed travelling across the wings of the aircraft.  For the faster the wind moves across the wing the great lift it creates.  Commercial airports don’t have the luxury of turning into the wind.  So they lay their runways out to correspond to the prevailing wind directions.  As weather systems move through the region they often reverse the direction of the wind.  When they do planes take off in the other direction.  If the winds are somewhere in between these two extremes some airports have another set of runways called ‘crosswind’ runways.  Or trust in the highly skilled pilots flying out of their airports to adjust the control surfaces on their planes quickly and delicately to correct for less than optimal winds.

Helicopters don’t have this problem.  They can take off facing in any direction.  Because that big propeller on top is a rotary wing.  Or rotor.  A fixed wing airplane needs forward velocity to move air over their wings to create lift.  A helicopter moves air over its rotary wing by spinning it through the air.  To create lift the pilot tilts the rotor blades to change their angle of attack.  And tilts the whole rotor in the direction of travel.  The helicopter’s engine runs at a constant RPM.  To increase lift the angle of attack is increased.  This also creates drag that increases the load on the engine, slowing it down.  So the pilot increases the throttle of the engine to return the rotor to that constant RPM.

Propeller-powered airplanes also have variable-pitch propellers.  To create the maximum possible lift at the lowest amount of drag.  So it’s not just engine speed determining aircraft speed.  When running up the engines while on the ground the pilot will feather the propellers.  So that the blade pitch is parallel to the airflow and moves no air.  This allows the engines to be run up to a high RPM without producing a strong blast of air behind it.  A pilot will also feather the prop on a failed engine in flight to minimize drag.  Allowing a single-engine plane to glide and a multiple engine plane to continue under the power of the remaining engines.  A pilot can even reverse the pitch of the propeller blades to reverse the direction of airflow through the propeller.  Helping planes to come to a stop on short runways.

By varying the Blade Pitch for Different Wind Speeds Wind Turbines can Maintain a Constant RPM

Thomas Edison developed DC electrical power.  George Westinghouse developed AC electrical power.  And these two went to war to prove the superiority of their system.  The War of the Currents.  Westinghouse won.  Because AC is economically superior.  One power plant can power a very large geographic area.  Because alternating current (AC) works with transformers.  Which stepped up voltages for long-distance power transmission.  And then stepped them back down to the voltages we use.  Power equals voltage times current.  Increasing the voltages allows lower currents.  Which allows thinner wires.  And fewer generating plants.  Which saves money.  Hence the economic superiority of AC power.

Alternating current works with transformers because the current alternates directions 60 times a second (or 60 cycles or hertz).  Every time the currents reverse an electrical field collapses in one set of windings of a transformer, inducing a voltage in another set of windings.  A generator (or, alternator) creates this alternating current by converting rotational energy into electrical energy.  Which brings us back to windmills.  A source of rotational energy.  Which we can also use to generate electrical energy.  But unlike windmills of old, today’s windmills, or wind turbines, turn from lift.   The wind doesn’t push the blades.  The wind passes over them producing lift.  Like on a wing.  Pulling them into rotation.

The typical wind turbine design is a three-bladed propeller attached to a nacelle sitting on top of a tall pylon.  The nacelle is about as large as a big garden shed or a small garage.  Inside the nacelle are the alternator and a gearbox.  And various control equipment.  Like windmills of old wind turbines still have to face into the wind.  We could do this easily and automatically by placing the propeller on the downwind side of the nacelle.  Making it a weathervane as well.  But doing this would put the pylon between the wind and the blades.  The pylon would block the wind causing uneven loading on the propeller producing vibrations and reducing the service life.  So they mount the propeller on the upwind side.  And use a complex control system to turn the wind turbine into the wind.

When it comes to electrical generation a constant rotation is critical.  How does this happen when the wind doesn’t blow at a constant speed?  With variable-pitched blades on the propeller.  By varying the blade pitch for different wind speeds they can maintain a constant number of revolutions per minute (RPM).  For a limited range of wind conditions, that is.  If the wind isn’t fast enough to produce 60 hertz they shut down the wind turbine.  They also shut them down in high winds to prevent damaging the wind turbine.  They can do this by feathering the blades.  Turning the propeller blades parallel to the wind.  Or with a mechanical brake.  The actual rotation of the propeller is not 60 cycles per second.  But it will be constant.  And the gearbox will gear it up to turn the alternator at 60 cycles per second.  Allowing them to attach the power they produce to the electric grid.

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Thomas Edison, Patents, Intellectual Property Rights, Nikola Tesla, George Westinghouse, DC, AC and the War of Currents

Posted by PITHOCRATES - March 27th, 2012

History 101

Thomas Edison protected his Intellectual Property Rights with over 1,000 Patents

Thomas Edison was a great inventor.  A great entrepreneur.  But he wasn’t a great scientist or engineer.  He was home-schooled by his mom.  And didn’t go to college.  But he read a lot.  And loved to tinker.  He grew up in Port Huron, Michigan.  At one end of the train line that ran between Port Huron and Detroit.  Where he sold newspapers and other things to commuters during the Civil War.  Then he saved the life of some kid.  Pulled him out of the way of a runaway boxcar.  The kid’s dad ran the train station.  Out of gratitude for saving his son’s life he taught the young Edison Morse Code.  And trained him to be a telegraph operator.  He mastered it so well that Edison invented a better telegraph machine.  The Quadruplex telegraph.  Because he liked to tinker.

What made him a great entrepreneur and not a great scientist or engineer is that his inventions had a commercial purpose.  He didn’t invent to solve life’s great mysteries.  He invented to make money.  By creating things so great that people would want them.  And pay money for them.  He also had an eye on production costs.  So he could build these things the people wanted at affordable prices.  For if they were too expensive the people couldn’t buy them.  And make him rich.  So his inventions used technology to keep production costs down while keeping consumer interest high.  Because of the profit incentive.  But the POSSIBILITY of profits wasn’t enough to push Edison to set up his invention lab.  Where he employed a team of inventors to work full time inventing things.  And figuring out how to mass-produce inventions that made everyone’s life better.  He needed something else.  Something that GUARANTEED Edison could profit from his inventions.  The patent.  That gave the patent holder exclusive rights to profit from their invention.

Inventors and entrepreneurs spend a lot of money inventing things.  They do this because they know that they can file a patent when they invent something that people will buy.  Protecting their intellectual property rights.  So they alone can profit from the fruit of all their labors.  And Edison was one of these inventors.  One of the most prolific inventors of all time.  Filing over 1,000 patents.  Including one on the incandescent light bulb.  Which was going to replace gas lamps and candles.  And provided a need for another new invention.  Electric power distribution.  Something else he spent a lot of time tinkering with.  Producing electrical generators.  And an electric power distribution system.  Which was going to make him an even richer man.  As he held the patents for a lot of the technology involved.  However, he was not to become as rich as he had hoped on his electric power distribution system.  Not for any patent infringements.  But because of a mistreated former employee who had a better idea.

Thomas Edison and George Westinghouse battled each other in the War of Currents

Nikola Tesla was a brilliant electrical engineer.  But not a great entrepreneur.  So he worked for someone who was.  Thomas Edison.  Until Edison broke a promise.  He offered a substantial bonus to Tesla if he could improve Edison’s electric power generating plants.  He did.  And when he asked for his bonus Edison reneged on his promise.  Telling the immigrant Tesla that he didn’t understand American humor.  Angry, Tesla resigned and eventually began working for George Westinghouse.  An Edison competitor.  Who appreciated the genius of Tesla.  And his work.  Especially his work on polyphase electrical systems.  Using an alternating current (AC).  Unlike Edison’s direct current (DC).  Bringing Edison and Tesla back together again.  In war.

Direct current had some limitations.  The chief being that DC didn’t work with transformers.  While AC did.  With transformers you could change the voltage of AC systems.  You could step the voltage up.  And step it back down.  This gave AC a huge advantage over DC.  Because power equals current multiplied by voltage (P=I*E).  To distribute large amounts of power you needed to generate a high current.  Or a high voltage.  Something both DC and AC power can do.  However, there is an advantage to using high voltages instead of high currents.  Because high currents need thicker wires.  And we make wires out of copper or aluminum.  Which are expensive.  And the DC wires have to get thicker the farther away they get from the generator plant.  Meaning that a DC generating plant could only serve a small area.  Requiring numerous DC power plants to meet the power requirements of a single city.  Whereas AC power could travel across states.  Making AC the current of choice for anyone paying the bill to install an electric distribution system.

So the ability to change voltages is very beneficial.  And that’s something DC power just couldn’t do.  What the generator generated is what you got.  Not the case with AC power.  You can step it up to a higher voltage for distribution.  Then you can step it down for use inside your house.  Which meant a big problem for Edison.  For anyone basing their decision on price alone would choose AC.  So he declared war on AC power.  Saying that it was too dangerous to bring inside anyone’s house.  And he proved it by electrocuting animals.  Including an elephant.  And to show just how lethal it was Edison pushed for its use to replace the hangman’s noose.  Saying that anything as deadly as what states used to put prisoners to death was just too deadly to bring into anyone’s house.  But not even the electric chair could save Edison’s DC power.  And he lost the War of Currents.  For Tesla’s AC power was just too superior to Edison’s DC power not to use. 

Nikola Tesla was a Brilliant Engineer who Preferred Unraveling the Mysteries of the Universe over Business

George Westinghouse would get rich on electrical distribution.  Thanks to Nikola Tesla.  And the patents for the inventions he could have created for Thomas Edison.  If he only recognized his genius.  Which he lamented near death as his greatest mistake.  Not appreciating Tesla.  Or his work.  But Edison did well.  As did Westinghouse.  They both died rich.  Unlike Tesla.

Westinghouse could have made Tesla a very rich man.  But his work in high voltage, high frequency, wireless power led him away from Westinghouse.  For he wanted to provide the world with free electric power.  By creating power transmitters.  That could transmit power wirelessly.  Where an electric device would have an antenna to receive this wireless power.  He demonstrated it to some potential investors.  He impressed them.  But lost their funding when they asked one question.  Where does the electric meter go?  Free electric power was a noble idea.  But nothing is truly free.  Even free power.  Because someone had to generate that power.  And if you didn’t charge those using that power how were you going to pay those generating that power?

Edison and Westinghouse were great entrepreneurs.  Whereas Tesla was a brilliant engineer.  He preferred unraveling the mysteries of the universe over business.  Tesla probably suffered from obsessive-compulsive disorder.  Think of the character Sheldon Cooper on The Big Bang Theory television sitcom.  He was a lot like that character.  Brilliant.  Odd.  And interested in little else but his work.  He lived alone.  And died alone.  A bachelor.  Living in a two-room hotel room in the last decade of his life.  Despite his inventions that changed the world.  And the fortunes he made for others.  Sadly, Tesla did not die a rich man.  Like Edison and Westinghouse.  But he did live a long life.  And few men or women changed the world like he did.  A brilliant mind that comes around but once in a millennium.

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Music, Radio Transmitters, Radio Receivers, CD Players, Compression, MP3 Players, Internet, YouTube, Live Streaming and Music on Demand

Posted by PITHOCRATES - February 29th, 2012

Technology 101

The Roaring Twenties brought Electrical Power and Broadcast Radio into our Homes

We take music for granted today.  We can listen to pretty much anything we want to.  At any time.  In any place.  In the home.  In the car.  At the gym.  It’s nice.  You can listen to some of the most beautiful music at your convenience and leisure.  It wasn’t always like this, though.  During the time Edvard Grieg composed his masterpieces few could listen to them.  Unless you attended a live performance.  Which weren’t that readily available.  Unless you lived in a big city.  Where a symphony orchestra could include some of his music in a performance.  But you had to listen to what they played.  And what they played was the only music you were familiar with.  Unless you had a friend with a piano.  Who could read sheet music.  And was a concert-level pianist.  Again, something not that common.

But today you can click on a computer link and listen to almost any obscure piece of music there is.  From Grieg’s beautiful Bådnlåt (At the Cradle), lyric piece for piano, Op. 68/5.  To something really esoteric like Sparks’ As I Sit Down To Play The Organ At The Notre Dame Cathedral.  You can listen to them.  You can buy them.  Download them to a portable MP3 player.  And take them anywhere.  Just imagine trying to do this in 1899.  Going to the lake.  And wanting to listen to Grieg’s new lyric piece for piano.  Opus 68.  Number 5.  At the Cradle.  Unless you took a piano and a concert-level pianist with you that just wasn’t going to happen.  But this all changed.  Beginning around the dawn of the 20th century.

Nikola Tesla had recently won his war with Thomas Edison.  His AC power replaced Edison’s DC power as the standard.  And in the 1920s we were electrifying the country.  We began to generate and transmit AC power across the land.  To businesses.  And to homes.  Where we could plug in the new electrical appliances coming to market.  We were working on another new technology during this time.  Something that could plug in at home to the new electrical power.  The radio.  This technology had something to do with electromagnetic fields and waves.  Transmitted between antennas.  One on a transmitter.  And one on a receiver.  As long as the transmitter and the receiver were tuned to the same frequency.  The first use of this new technology was in the form of a wireless telegraph.  Which few people had in their homes.  These were more useful to communicate with others who were not connected by telegraph lines.  Like ships at sea.  Where we sent Morse code (those dots and dashes that spelled words).  Which worked well.  As long as all the ships didn’t tried to communicate at the same time on the same frequency.  But transmitting speech or music was a different manner.  Because everyone talks more or less in the same band of frequencies.  And notes played on one violin tend to play at the same frequency on another violin.  So if some radio transmitters broadcasted different concerts at the same time you wouldn’t hear a nice concert on your radio.  You’d hear a cacophony of noise.  To get an idea what that would sound like open up three or four browser windows on your computer.  And play a different song on YouTube in each.  What you hear will not be music.  But noise.

In the Eighties we traded our Phonograph Needles for Laser Beams in our CD Players

Of course, this didn’t stop the development of commercial broadcast radio.  For we tune radio transmitters and radio receivers to the same resonant frequency.  The transmitter transmitting at one frequency all of the time. While the radio receiver could tune in to different frequencies to listen to different radio broadcasts.  When you turned the radio tuning dial you changed what resonant frequency your receiver ‘listened’ to.  Which was basically a filter to block all frequencies but the tuned frequency from entering your radio.  We call that frequency the carrier signal.  Typically just a plain old sinusoidal wave form at a one frequency that we imprint the information of the speech or music on.  The transmitter takes the music waveform and modulates it on the carrier signal.  Then broadcasts the signal on the broadcast antenna.  The receiver then captures this signal on its antenna.  And demodulates it.  Pulling the musical imprint from the carrier signal.  And restoring it to its original condition.  Which the radio than amplifies and sends to a speaker.  I left some steps out of the process.  But you get the gist.  The key to successful broadcast radio was the ability to transform the source signal (speech or music) into another signal.  One that we could transmit and receive.  And transform back into the source signal.

The Roaring Twenties was a Neil Armstrong moment on earth.  It was one giant leap for mankind.  For it was in this decade that the modern world began.  Thanks to Nikola Tesla and his AC power.  Which allowed us the ability to plug in radios in our homes.  And power the great radio transmitters to get the signal to our houses.  Tesla, incidentally, created radio technology, too.  Well, Tesla, and Guglielmo Marconi.  (Patent disputes flared between these two greats about who was first.)  Great technological advancement.  Created during a time of limited government and low taxes.  That unleashed an explosive amount of creativity and invention.  The Eighties was another such decade.

The Eighties launched the digital age.  The world of bits and bytes.  1s and 0s.  Digital watches.  Clocks.  Calculators.  PCs.  And, of course, our music.  For the Eighties gave us the compact disc.  The CD.  Music that didn’t wear out like our vinyl records.  And didn’t pop or hiss with age.  Because a CD player didn’t have a phonograph needle.  That rode the groves on our vinyl records.  It had something far more futuristic.  A laser beam.  That reads information encoded into the CD.  Information encoded onto a reflective layer through a series of pits.  During playback the laser either reflects or doesn’t reflect.  This information is than processed into a series of 1s and 0s.  Then converted into the analog waveform of the source material.  And becomes music again.

The Eighties gave us the Digital Age which led to the Internet and Music on Demand

This process is similar to the process of broadcast radio.  Not in any technological way.  But by changing a source signal into something else.  And then converting it back again.  In the case of the CD we sample an analog signal (i.e., an audio recording).  By taking ‘snapshots’ of it at regular intervals.  Then convert these snapshots into a digital format.  And then transfer this digital information to the reflective layer on a CD.  Those 1s and 0s.  When we play it back the laser reads these 1s and 0s.  Then converts these digital snapshots back into the original audio signal.  Sort of like modulating and demodulating a signal.  Only instead of modulating we’re converting from analog to digital.  Then vice versa.

The quality of the digital format depends on how much information each snapshot contains.  And the interval we sample them at.  Larger chunks of information taken in short intervals contain a lot more information.  And improve the quality of the sound.  But it will also take up a lot of space on those CDs.  Limiting the number of songs we can encode on them.  Which lead to compression.  And MP3s.  Which worked on the premise that there’s a lot of music in music.  But we don’t necessarily hear all of that music.  Some sounds mask out other sounds.  Certain frequencies we barely hear.  So while the CDs tried to reproduce the music as faithfully as possible, we learned that we could discard some of the information in the music without reducing the quality of the music much.  This saved a lot of space on CDs and portable MP3 players.  Allowed faster downloads on the Internet.  And live streaming.

The Roaring Twenties changed our world.  Modernized it.  And gave us many things.  Including broadcast radio.  And music in our homes we never had before.  And the Eighties also changed our world.  Further modernizing it.  Giving us the digital age.  That led to the Internet.  And music on demand like we never had before.  Where we can listen to anything.  No matter how obscure.  It’s now all available at our fingertips.  To listen online.  Or to buy and download to a portable device.  From Grieg to Sparks.  And everything in between.

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The Horse, Waterwheel, Steam Engine, Electricity, DC and AC Power, Power Transmission and Electric Motors

Posted by PITHOCRATES - December 21st, 2011

Technology 101

A Waterwheel, Shaft, Pulleys and Belts made Power Transmission Complex

The history of man is the story of man controlling and shaping our environment.  Prehistoric man did little to change his environment.  But he started the process.  By making tools for the first time.  Over time we made better tools.  Taking us into the Bronze Age.  Where we did greater things.  The Sumerians and the Egyptians led their civilization in mass farming.  Created some of the first food surpluses in history.  In time came the Iron Age.  Better tools.  And better plows.  Fewer people could do more.  Especially when we attached an iron plow to one horsepower.  Or better yet, when horses were teamed together to produce 2 horsepower.  3 horsepower.  Even 4 horsepower.  The more power man harnessed the more work he was able to do.

This was the key to controlling and shaping our environment.  Converting energy into power.  A horse’s physiology can produce energy.  By feeding, watering and resting a horse we can convert that energy into power.  And with that power we can do greater work than we can do with our own physiology.  Working with horse-power has been the standard for millennia.  Especially for motive power.  Moving things.  Like dragging a plow.  But man has harnessed other energy.  Such as moving water.  Using a waterwheel.  Go into an old working cider mill in the fall and you’ll see how man made power from water by turning a wheel and a series of belts and pulleys.  The waterwheel turned a main shaft that ran the length of the work area.  On the shaft were pulleys.  Around these pulleys were belts that could be engaged to transfer power to a work station.  Where it would turn another pulley attached to a shaft.  Depending on the nature of the work task the rotational motion of the main shaft could be increased or decreased with gears.  We could change it from rotational to reciprocating motion.  We could even change the axis of rotation with another type of gearing.

This was a great step forward in advancing civilization.  But the waterwheel, shaft, pulleys and belts made power transmission complex.  And somewhat limited by the energy available in the moving water.  A great step forward was the steam engine.  A large external combustion engine.  Where an external firebox heated water to steam.  And then that steam pushed a piston in a cylinder.  The energy in expanding steam was far greater than in moving water.  It produced far more power.  And could do far more work.  We could do so much work with the steam engine that it kicked off the Industrial Revolution.

Nikola Tesla created an Electrical Revolution using AC Power

The steam engine also gave us more freedom.  We could now build a factory anywhere we wanted to.  And did.  We could do something else with it, too.  We could put it on tracks.  And use it to pull heavy loads across the country.  The steam locomotive interconnected the factories to the raw materials they consumed.  And to the cities that bought their finished goods.  At a rate no amount of teamed horses could equal.  Yes, the iron horse ended man’s special relationship with the horse.  Even on the farm.  Where steam engines powered our first tractors.  Giving man the ability to do more work than ever.  And grow more food than ever.  Creating greater food surpluses than the Sumerians and Egyptians could ever grow.  No matter how much of their fertile river banks they cultivated.  Or how much land they irrigated.

Steam engines were incredibly powerful.  But they were big.  And very complex.  They were ideal for the farm and the factory.  The steam locomotive and the steamship.  But one thing they were not good at was transmitting power over distances.  A limitation the waterwheel shared.  To transmit power from a steam engine required a complicated series of belts and pulleys.  Or multiple steam engines.  A great advance in technology changed all that.  Something Benjamin Franklin experimented with.  Something Thomas Edison did, too.  Even gave us one of the greatest inventions of all time that used this new technology.  The light bulb.  Powered by, of course, electricity.

Electricity.  That thing we can’t see, touch or smell.  And it moves mysteriously through wires and does work.  Edison did much to advance this technology.  Created electrical generators.  And lit our cities with his electric light bulb.  Electrical power lines crisscrossed our early cities.  And there were a lot of them.  Far more than we see today.  Why?  Because Edison’s power was direct current.  DC.  Which had some serious drawbacks when it came to power transmission.  For one it didn’t travel very far before losing much of its power. So electrical loads couldn’t be far from a generator.  And you needed a generator for each voltage you used.  That adds up to a lot of generators.  Great if you’re in the business of selling electrical generators.  Which Edison was.  But it made DC power costly.  And complex.  Which explained that maze of power lines crisscrossing our cities.  A set of wires for each voltage.  Something you didn’t need with alternating current.  AC.  And a young engineer working for George Westinghouse was about to give Thomas Edison a run for his money.  By creating an electrical revolution using that AC power.  And that’s just what Nikola Tesla did.

Transformers Stepped-up Voltages for Power Transmission and Stepped-down Voltages for Electrical Motors

An alternating current went back and forth through a wire.  It did not have to return to the electrical generator after leaving it.  Unlike a direct current ultimately had to.  Think of a reciprocating engine.  Like on a steam locomotive.  This back and forth motion doesn’t do anything but go back and forth.  Not very useful on a train.  But when we convert it to rotational motion, why, that’s a whole other story.  Because rotational motion on a train is very useful.  Just as AC current in transmission lines turned out to be very useful.

There are two electrical formulas that explain a lot of these developments.  First, electrical power (P) is equal to the voltage (V) multiplied by the current (I).  Expressed mathematically, P = V x I.  Second, current (I) is equal to the voltage (V) divided by the electrical resistance (R).  Mathematically, I = V/R.  That’s the math.  Here it is in words.  The greater the voltage and current the greater the power.  And the more work you can do.  However, we transmit current on copper wires.  And copper is expensive.  So to increase current we need to lower the resistance of that expensive copper wire.  But there’s only one way to do that.  By using very thick and expensive wires.  See where we’re going here?  Increasing current is a costly way to increase power.  Because of all that copper.  It’s just not economical.  So what about increasing voltage instead?  Turns out that’s very economical.  Because you can transmit great power with small currents if you step up the voltage.  And Nikola Tesla’s AC power allowed just that.  By using transformers.  Which, unfortunately for Edison, don’t work with DC power.

This is why Nikola Tesla’s AC power put Thomas Edison’s DC power out of business.  By stepping up voltages a power plant could send power long distances.  And then that high voltage could be stepped down to a variety of voltages and connected to factories (and homes).  Electric power could do one more very important thing.  It could power new electric motors.  And convert this AC power into rotational motion.  These electric motors came in all different sizes and voltages to suit the task at hand.  So instead of a waterwheel or a steam engine driving a main shaft through a factory we simply connected factories to the electric grid.  Then they used step-down transformers within the factory where needed for the various work tasks.  Connecting to electric motors on a variety of machines.  Where a worker could turn them on or off with the flick of a switch.  Without endangering him or herself by engaging or disengaging belts from a main drive shaft.  Instead the worker could spend all of his or her time on the task at hand.  Increasing productivity like never before.

Free Market Capitalism gave us Electric Power, the Electric Motor and the Roaring Twenties

What electric power and the electric motor did was reduce the size and complexity of energy conversion to useable power.  Steam engines were massive, complex and dangerous.  Exploding boilers killed many a worker.  And innocent bystander.  Electric power was simpler and safer to use.  And it was more efficient.  Horses were stronger than man.  But increasing horsepower required a lot of big horses that we also had to feed and care for.  Electric motors are smaller and don’t need to be fed.  Or be cleaned up after, for that matter.

Today a 40 pound electric motor can do the work of one 1,500 pound draft horse.  Electric power and the electric motor allow us to do work no amount of teamed horses can do.  And it’s safer and simpler than using a steam engine.  Which is why the Roaring Twenties roared.  It was in the 1920s that this technology began to power American industry.  Giving us the power to control and shape our environment like never before.  Vaulting America to the number one economic power of the world.  Thanks to free market capitalism.  And a few great minds along the way.

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LESSONS LEARNED #72: “Moms are a lot like CEOs. Only with more responsibility, longer hours and less pay.” -Old Pithy

Posted by PITHOCRATES - June 30th, 2011

A Genius may have a Brilliant Idea, but it’s an Entrepreneur that brings it to Market

A CEO is a lot like an entrepreneur.  They’re both a cut above the rest.  And can do what few can do.  Bring two worlds together.  The theoretical world inhabited by great thinkers and inventors.  And the practical world inhabited by people who act.  Who take the things the great thinkers and inventors create and give them to us.   There is a difference between the people that inhabit these worlds.  And most can only live in one or the other.  But CEOs and entrepreneurs can live in both.  That’s what makes them special.  Thinkers and inventors possess a genius of theoretical creativity.  But they can do little with their idea.  The action people can build great things (cars, airplanes, buildings, power plants, cell phones, etc.) but only from a construction plan.  Someone else has to have an idea and think and create the construction plan before they can build.  These are the two worlds.  The genius.  And the builders.  And it is the CEO and entrepreneur that bring these two worlds together.

Nikola Tesla was a genius.  A brilliant theoretical thinker.  He created the world in which we live.  But do you know who he is?  What he created?  Probably not.  Unless you’re a Croat.  Because there are probably a lot of statues of him in Croatia. Because he was born there to Serbian parents.  He eventually moved to America.  Got a job with a guy name Thomas Edison.  Who didn’t appreciate his genius.  Or his one particular ‘crazy’ idea.  But George Westinghouse did. 

That ‘crazy’ idea is the AC power we use today.  Thomas Edison was building DC power plants and a DC electric grid.  Despite all the failings of DC distribution (DC power doesn’t travel far requiring lots of generating plants, different voltages have to have their own generating plant, large power loads require very thick and expensive copper wires, etc.).  There was already a DC electrical infrastructure.  And it was Edison’s.  Which he wanted to expand because it would pay him well.

But Tesla’s AC system was better.  Because it could use transformers.  One power generating plant could provide power at a variety of voltages.  You just needed a transformer to get the voltage you wanted.  Also, electrical power is the product of voltage and current.  High power, then, requires either a high voltage or a high current.  High currents require thick, expensive copper wires.  So high voltage was the way to go.  It allowed power to travel farther over thinner wires.  Therefore, it required fewer generating plants.  And a single electric grid (not one for each voltage).  AC power was much more economical than DC power.  And George Westinghouse saw that.  And took Tesla’s brilliant idea and built the AC power generation and distribution system we use today.

The Business of Beautiful, Estée Lauder

You see, Tesla was at home in the lab.  He was a scientist.  Not a salesman.  That’s why he wasn’t an entrepreneur.  Because, just like being a CEO, you need sales skills to be an entrepreneur.  Because you are the number one sales person in your business.  And Edison and Westinghouse were great salesmen.  That’s why they brought a lot of Tesla’s great inventions to market.  And why Tesla did not.  He was just not a sales person.

But Estée Lauder was.  She was always selling.  And creating.  She was the classical entrepreneur.  Her uncle was in the chemistry business making beauty products.  Which fascinated her from a young age.  He taught her the chemistry.  Taught her how to make the products.  How to use the products.  And she did.  Loved them.  And started selling them.  With a passion.

She started creating her own products.  Using her own kitchen as her laboratory.  When not tending to her two sons.  She demonstrated how to use her products.  Gave away free samples.  And sold.  She was always selling.  She started out small.  By herself.  From these humble beginnings she grew to dominate the industry.  She was relentless.  She worked herself to the premier counter space in department stores by redefining the way cosmetics were sold.  Starting with Saks Fifth Avenue in New York.  She visited each counter to ensure they were meeting her high standards.  She gave away free samples.  She demonstrated.  She touched.  Personally applying products on customers.  That’s why when you walk into a department store you’ll see the Estée Lauder counter first.  And you’ll see all the counters selling the same way.  Giving away free samples.  Demonstrating products.  Showing how to apply products.  The Estée Lauder way.

One Smart Cookie, that Mrs. Fields

Debbi Fields liked to bake cookies.  She married young at 19.  To a Stanford graduate.  And aspiring financial consultant.  And about a year later decided to go into the cookie business.  After an incident at a party with her husband and a lot of his snobby associates.  She apparently mispronounced a word.  Said ‘orientated’ instead of ‘oriented’.  A snob pointed out her faux pas.  Sending her home in tears.  Didn’t much like that experience.  And decided to be something more than a ‘just’ a housewife.  Not that there was anything wrong with that.  And she would love being a housewife.  She would raise 5 daughters.  And add another 5 stepchildren in a second marriage.  But the snobs in her husband’s circle did look down on that particular institution.  It was so old fashioned.  It wasn’t progressive.  It wasn’t what people in their circles did.  So they acted like real asses.

Yet they liked her cookies.  Loved them.  Her husband would take them to work.  Where they were a big hit.  Soft and chewy.  Gourmet.  They were different.  When she asked them if she should go into the cookie business, they said it was a bad idea.  The conventional wisdom said crispy cookies were the way to go.  People didn’t want to buy soft and chewy.  They said as they stuffed their mouths with soft and chewy cookies.  And there were others who told her not to do it.  Even her husband doubted her.  But he loved her.  And would support her. She had no business experience.  But she was a hard worker.  And believed in what she was doing.  She got a bank loan to open a cookie store.  Not so much because the banker believed in the business idea.  But because of the good character of her and her husband.  Whatever the outcome, the bank was willing to take a chance.  Because, success or fail, they knew they would repay the loan.

She opened her first store in a mall food court.  Did not sell a single cookie.  Until she used the Estée Lauder sales method.  She gave away free samples.  People tried.  And people liked.  Soft and chewy was a hit.  She grew the company.  Added more stores.  And made a lot of money.  She was very hands on to maintain the quality.  Again, like Estée Lauder.  She visited her stores.  To make sure they maintained her high standards.  Which is why she refused to franchise.  She was too worried about losing that quality.  Which is what made Mrs. Fields cookies better than the competition.  Her husband computerized her operation.  Adding a computer at each store.  All wired to the Internet and tied into her headquarters.  It was state of the art technology.  Allowing more growth.  While retaining full control.  The growth was fast.  Too fast.  The hands-on management didn’t work well with so many stores.  The debt started to pile up.  And then a recession hit.  Her expensive gourmet cookies became too expensive.  And people stopped buying them.  To save the company she had to sell 80% of it.  And the new owners changed the business model.  Franchised stores.  And bumped Debbie Fields from CEO.  But she remained chairman of the board.  And though only a minority shareholder, the business Debbie Fields created continues on.  Her only mistake was being so successful so fast.  And if you’re going to have a fault that’s not a bad one to have.  By the way, don’t forget that she did all of this while raising 5 daughters.  Which probably made the running of the multi-million dollar business the easy part of her life.

Entrepreneurs, CEOS and Moms

Entrepreneurs and CEOs.  They’re a different breed.  They can be both brilliant thinkers like Nikola Tesla.  And aggressive sales people like Thomas Edison and George Westinghouse.  Such as Estée Lauder.  And Debbie Fields.  These mothers dominated their industries.  And set the bar for everyone else.  Lauder built an empire that dominates still.  Fields use of technology to streamline operations is a model for business efficiency at Harvard Business School.  Two of America’s most successful entrepreneurs and CEOs.  And both were moms first.

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