After the delaying battle of Thermopyle, in which the 300 Spartans (and 8700 other Greeks) fought and delayed the massive army of Xerxes, and after the Persian navy was destroyed at Salimis, Xerxes departed for Persia and left a sizable Persian army in Greece to finish the conquest of Greece. In the Spring of the next year, 479 BC, the Persian army of 300,000 met the assembled Greeks at Platea. The Greeks, numbering roughly 50,000, arranged their battle line first, and the Persians then placed their strongest forces opposite what they thought were the strongest Greek forces. Thus the Persians were opposite the Spartans, and were eager to prove their valor. Opposite the Athenians, Plataians and Megarians, were placed the Boeottians, Locrians, Thessalians, and Phokians. And so the Persians arranged each of their many allied forces against the many independent Greek states.
Once the battle lines were set, both sides sought the advice of their diviners as to whether they should attack first or defend. Diviners of both sides said they would win if they defended, but not if they attacked, so both sides waited for the other side to attack. They waited for eleven days, staring across the battle field. Each day the Greek forces grew more numerous, as small contingents arrived to participate.
On the twelfth day, the Greeks decided to rearrange their forces, and move the Athenians to a place opposite the Persians. The Persians saw this and moved their Persian forces to be opposite the Spartans again. After night fell the Greeks decided to move back a small distance to take up a new battle like, for the purpose of being closer to a water source. In the morning light the Persian general saw that the Greeks were gone, and assumed they had dispersed. He led the entire Persian forces at a run after them, and came up against their reformed battle lines. The Persians attacked in an unorganized mass, and often in small groups, and being lightly armored, were slaughtered by the phalanx of the Greeks. The Spartans held against the Persians, and they and the Athenians pressed forward. The Persian general was killed, which caused panic among the Persian allies.
When the Persians were put to flight, all of the Persian allies also fled. The Greeks pursued the surviving Persians and their allies, and captured their camp with many treasures. About 3000 Persians of the army of 300,000 survived to return to Persia.
The first pendulum clock was invented in 1656 by Christian Huygens in the Netherlands. This clock was based on an escapement, a device which allows the first gear of the clock to advance only one gear with each swing of a pendulum. The pendulum clock greatly improved clock accuracy, and led to the addition of minute and second hands to the earlier hour hand.
I got the bug to build a wooden gear clock from a kit, and ordered a kit made by Abong. This clock was designed by Raymond Groothuizen in 2013. He put a lot of research and trial and error into making the clock. They make other cool kits, which can be viewed here.
It came in a box about half as big as a shoe box, and had all kinds of cool gear wheels. These are cut by laser from plywood of several different thicknesses, so every edge is burned. The first task is to lightly sand each gear, and apply graphite as a lubricant between gears. I made a sanding table by putting double sided tape to a marble tile piece, and putting 120 grit sandpaper on the marble slab.
The next task is to connect the large gears to their inner gears. This is done using wooden dowels which are glued in place, then cut flush with the surface of the gears.
I got ahead of myself and glued all the gears together in one day.
After assembling the gears, the wooden axles are placed on a backing plate, and the gears are placed on the axles. Graphite from a pencil is rubbed onto the axles for lubrication. I also smoothed the axles with fine sandpaper to reduce friction. If all goes well, the gears will all turn freely. Without the escapement holding the gears in check, the weight attached to the drive gear would spin all the gears in a furious tornado of spinning gears, until the weight hit the floor in about 5 seconds.
When the gears are on the backing plate, the plate is mounted vertically, the weight is hung and wound up, and if you are lucky, the weight drives the gears and each cycle of the pendulum gets a bit of a push from the shape of the escapement and the gears it touches.
If the clock is assembled correctly with minimal friction between the gears, a period of adjustment begins. The movement of the gears on each axle has be centered, more graphite will probably be needed, and seemingly endless adjustments might be required. My clock has been running for many days now, which is a big relief. Its very pleasant to hear that tick tick tick of the gears and the escapement.
I was missing some parts that were lost in the built, and Abong was nice enough to send me replacements for free! How nice. Thanks, Raymond and Joanne! The quality of the cuts is excellent and the instructions are very complete. Minimal equipment is needed, mostly sandpaper and glue. I would recommend this kit to any person with some building skills.
How do you use the energy of flowing water, such as in a stream or river, to pump water to a height far higher than the source of the water? How do you do that without electricity, without solar power, just using the moving water? A device that does just that was invented in 1746 by Wirtz of Switzerland. It was largely forgotten when steam power and later electrical power came along, but it has seen a resurgence of interest among people trying to use simple technology in the U.S. and also in developing countries.
Its called a Wirtz pump, and is also known as a spiral pump, a river pump, or coil pump, this amazing piece of technology was a little difficult to fabricate in the 18th and 19th century, but with readily available tubing it is easily and cheaply made today.
In the version in Figure A (from the Food and Agricultural Organization of the United Nations) above, tubing is arranged in a vertical spiral, with the outside end of the tubing situated to fill with water at each revolution. As the spiral turns (supported and driven by a waterwheel), water and air are moved along the tubing toward the center outlet pipe. Water and air are pumped out of the outlet pipe and can be lifted quite a ways above and away from the water source. No energy other than slowly moving water of a stream, river, or ditch are needed. A version of this with a 6' diameter coil of 1.25" tubing, puts out 3900 gal. per day of water, at a 40' head. Pumping water to a 70' head, 700 ' from the water source are known.
The version of the device in Figure B has the tubing arranged in a coil around a barrel or cone. In this configuration the pump can work in stationary water. The coil of tubing can be turned manually which causes water to be pumped out.
The version below is similar to the version shown in Figure B, but it has a bullet shaped housing, and an attached propeller that causes the bullet to rotate in moving water current. As the barrel rotates in the water current, water is pumped out the tubing, through a connection that has hose attached. These are sold commercially as the Rife River pump. Diagram courtesy of Rife River Pump. These pumps can pump to a 82' head, and some installations run 1/2 inch poly pipe out to 400' from the water source.
A great video of this pump in action is found here:
https://www.youtube.com/watch?v=JfdlG5hVUhs
Scott Swanson, our Paralegal Amy Hennig, and our Office Manager Dicsie Gullick and I recently started a new law firm, to continue our work in patent and trademark law, as well as litigation involving patents and trademarks. We got my daughter Ciera Shaver to work on the website, and she came up with this cool graphic. This is a great graphic for a patent law firm, because Scott and I both ride bikes, and arguably, the bicycle is the perfect invention. If not the ultimate invention, its a pretty darn revolutionary invention. Our website is located at shaverswanson.com
The largest stone ever moved by man, as far as I know, is the stone moved to St. Petersberg to serve as the base for the equistrian statue of Peter the Great. It was called the Thunder Stone, and was moved four miles by land from a swamp in Finland, to a waiting barge. It weighed 1250 tons, by far the heaviest stone known to have been moved by man. It traveled by barge to its resting place in St. Petersburg, and was carved to it's final shape as it was being moved. It started out as 1500 tons, and was something like 1250 tons when in its finished form.
It was moved by placing metal tracks under the stone. The tracks had grooves running their length, and were supported by 6" brass balls on a supporting track. There were basically ball bearings, in a time before ball bearings had been invented. Two large capstans were turned by teams of 36 men, to move the stone 150 meters per day. They did the move in winter, so the soft ground would support the weight by being frozen. They only had 100 meters of track, so the track has to be dissembled behind the stone and reassembled in front of the stone. A comparison with other large stoves moved (heavier ones were cut, but not moved) in antiquity shows:
1000 tons, Ramsseum statue: 1000 tons, moved 170 miles
800 t each, three foundation stones atBaalbek, Lebanon,
700 t, Collissi if Memnon, transported 420 miles by land
600 t, Alexander Column, St. Petersburg
575 t, Western Stone of Temple, Jerusaleum
100 t, Puma Punku stones, at 12,000' elevation in Bolivia
26 t, Stonehenge sarsen stones, England
In 1835 Sir Henry Rawlinson investigated some writings and figures carved in a stone wall on the road between the ancient capital of Babylonia and Media, located in modern Iraq . The writings were on a panel carved into the rock, the panel being 15 meters high and 25 meters long. The panel is 100 meters above the foot of the cliff.
Using copies of the text that he made, Rawlinson determined that the text of the inscription was a declaration, geneology, and history lesson written by King Darius of Persia, written before his death in 486 BC. The inscription was important because the same message is written three major languages of the day: Old Persian,Elamite, and Babylonian. Like the Rosetta stone, the fact that when one of these message could be deciphered, that meant the other two messages could be deciphered.
About one third of the Old Persian alphabet were known, and Rawlinson figured out the rest, aided by the fact that the ancient language had similarities to the modern Persian of the region. Once the words in Old Persian were known, translating the same words in the other two languages came fairly fast. Thus was learned how to read these old languages.
When the text was finished, Darius had the access trails to the rock panel cut away, which helped preserve the inscription to modern times.
Theories on how the Great Pyramid at Giza take various forms. Most of them have involved some form of ramp, up which the large stone blocks were hauled. The problem was that construction of some of the ramps would have taken more effort and material than the pyramid itself.
Recently a French architect has proposed a theory that seems pretty logical, and solved a lot of the problems with the previous ramp theories. Fleshing out a theory suggested by his architect father, Jean-Pierre Houdin spent most of a decade planning how he would build a pyramid, and developing 3D computer models to show how it could be done. His plan involves the use of a ramp, but one which is internal to the pyramid, which is made of straight sections which turn at the corners and create a straight sided spiral to the top of the pyramid.
When the ramp reached a corner, there would be a platform and a crane, for turning the block of stone 90 degrees, so it could proceed up the next section of ramp.
Of course, the ramp theory will not be proven until a pyramid is taken apart to verify that an internal ramp exists, which is not likely to happen anytime soon. Mr. Houdin was resigned to that uncertainty, and had been making presentations of his theory. After one of his presentation, he was approached by a member of a German team which in 1986 had undertaken a project of scanning the pyramid looking for internal passages and chambers, using a sensitive gravity sensing technology. The member of the German team said that beside their published report, they had some images which they could not explain, so they were not included in the report. The images are below, and show regions inside the pyramid which showed as low density zones. Maybe they are internal tunnels, ramps, or tunnels filled with rubble from the building process. They match almost exactly Houdin's calculated positions of the internal tunnels and ramps.
Another bit of supporting evidence is seen on the pyramid itself, where a notch on one of the corners appears to be an exposed turning platform theorized by Mr. Houdin.
When the notch was explored by Bob Brier, he found a small room behind the platform, inside the pyramid, on the notch. This room appeared to be from the time of the construction of the pyramid, because the entrance to the room was smaller than the stones that would have been removed to form the room later. The roof of the room also had stones which were shaped to a dome shape, to support the weight of the stone above the room. A project has been proposed to penetrate the wall of the hidden room to see if behind it is an internal ramp.
This theory was presented by Mr. Houdin and Bob Brier in Secret of the Great Pyramid. See these links for more information.
http://www.archaeology.org/0907/etc/khufu_pyramid.html
http://www.archaeology.org/0705/etc/pyramid.html
Its not often that one runs across a history book that you can't put down until you have finished. This new book about Alexander the Great is such a book. It is very readable, unlike many other books on ancient history, and explains the ancient battles and tactics in a much more understandable style than other books.
Alexander might have been better called Alexander the Bold, or Alexander the Lucky, or Alexander the Inheritor of Philip's Army. It was Philip who developed a style of soldering that could allow an army of herdsmen to challenge the Greek phalanx staffed by soldiers wearing expensive bronze armor. Philip also developed the battlefield tactic of advancing his army to strike a point to one side of the enemies line of infantry. By striking with a wedge instead of a direct frontal attack, the enemy's line would inevitably be pulled out of formation, allowing the rest of Philips line to attack them when the unity of the Greek phalanx had been weakened. Philip also drilled his army of herdsmen until they fought as a unit, could turn and defend from mulitple threats, and were hardened to forced marches and extremes of weather and terrain.
Philip developed the innovative sarissa spear and the tactics of using it, and the training in its use in battle. The sarissa was longer than the spear of the Greek phalanx, and made Macedonian lines a veritable porcupine of spears, and was specifically designed to defeat the Greek phalanx.
Photo by permission of Simon and Schuster
Alexander was smart enough to use all that Philip had developed, and had the political genius to gather allies, eliminate threats, cojol reluctant troops, and added his own genius to the tremendous assets he had been given by his father. Each of his three major battles with the Persian army, which always included a fair number of Greek mercanaries, involved an asymmetical battle line, which showed Alexander's confidence in the Macedonian battle tactic, and his father's wedge attacking style. In each of the three battles against an overwhelmingly superior Persian army, the impenetrability of the sarissa armed Macedonians and the ability of the Macedonian cavalry to exploit weaknesses in the enemy's battle lines carried the day.
These topics and all of Alexander's battles, politcal intrigues, and his far thinking plans for his empire are presented in a very enjoyable style. I'd highly recommend this book.
The Greek historian Herodotus tells of a Persian siege of a Greek colony called Barcus, in North Africa, in 512 BC. During the siege the Persians would tunnel under the city walls, hoping to fill the tunnel with firewood, and when ready the fire in the tunnel would burn the wooden support bracing holding up the tunnel, and the tunnel would collapse, and hopefully the wall above it would also collapse.
This graphic shows typical bronze shields used by the Greeks.
A bronze worker in the city devised a method of detecting the location of hostile tunneling, using a bronze shield "covered over with bronze." Maybe that means they stretched a thin layer of bronze over the back of the shield, to amplify any vibrations as sound. If so, this would be an ancient world speaker, or amplifier.
The defenders of the city would carry the speaker around the wall, and "applied it to the ground". When the shield was near active tunneling activity, the shield made a sound. The defenders of Barca then dug a tunnel from their side, and entered the tunnel and slayed the Persian tunnelers.
In the 2006 movie "The Illusionist", starring Edward Norton as a turn of the century magician in Vienna, Austria, Norton makes a special locket and gives it to his love. The locket opens to display a picture, and may also be turned to form a heart shaped locket. When the heart shaped locket opens, a different picture is displayed. The functioning of the locket appeared for just a few seconds in the movie, and the scene was created by the use of two lockets and special effects. The locket in the movie only opens when in the heart configuration. That brief glimpse of a magical locket inspired lots of people to try to buy one, and inspired a number of craftsman to try to make a locket in the real world that worked in the same way.
Link to the locket as seen in the movie:
A short video of the locket in action:
Duplicating the action of the locket from the movie in the real world was actually a very difficult task, and the lockets made were all crude, and only partially functional. An ebay search will turn up quite a few which "kind of" work, but not really. That changed when Jim Anderson designed a locket that actually works similar to the magician's locket,or even better. Pictures show its operation below. All these pictures are of the same locket.
It uses tiny magnets that both repel and attract other tiny magnets, which cause the locket sections to float over certain positions, and snap into place in other positions. It also uses an intricate ball socket that allows the locket to achieve the seemingly impossible, and required some intricate machining.
Jim sells these lockets at Illusion Lockets. They are available in many types of wood and other materials. They come with a small punch to punch out round portraits from prints.
The Patent Pending Blog has always had a lot of bicycling and outdoors posts, as well as posts on firearms, ancient technology, historical patents, motorcycle technology, and diverse other technologies. I have recently started a separate blog just for bicycle technology, and one just for outdoor technology. The other diverse fields of technology will continue to have postings on the Patent Pending blog, but bicycle technology will be featured at "Bicycle Technology and Patents":
http://bicyclepatents.com/
and outdoor technology will be features at "Backpacking Patents"
http://backpackingtechnology.com/
These two sites are up and running right now, but will be receiving additional tuneups as I have time. Gradually all the bicycle and outdoor posts of Patent Pending Blog will be transferred to these two blogs, and additional posts on other technology will be posted to Patent Pending Blog.
I have been looking for a way to light up the flagpole on my recumbent trike, and found a product that looked like it would work, the Arizona Whip. Jerry at arizonzawhips.com was very nice to work with, and I got it hooked up this past weekend. The whip is 5" tall, and is of clear lexan. Inside the clear tube are 24 LED lights, 12 facing forward and 12 facing backward. Each side has a red group, and a yellow group, and on one side the red and yellow groups of LEDs flash on alternately. Jerry has other color configurations, including a red, white and blue one. The whip screws into a clamp that grips the 1.25 inch tube of the rear wheel fork. The clamp is for 1.5 in. tubes, but with some rubber and duct tape shimming, it grips the 1.25 inch tubing nicely with one Allen bolt for tightening. It extends up through the frame and clears the panniers, rack, seat, and headrest nicely. These pictures show the whip in daylight, and the clamp attached to the frame.
I ran a switch forward to the left hand grip, so I can turn it on and off from the seat. It runs off a 9 v battery. I have not ridden it to work yet, so I don't know how long the 9 v battery will last.
The picture below is how it looks at night, from the rear. The bike is facing not quite straight, and the bag on the rack is blocking one of the LED lights. The headlight is shining across the street at an angle, and provides lots of illumination.
This sucker is not cheap at $150, but if I can get noticed by a car either ahead of or behind me, it will be worth it.
I've been experimenting with a lighting setup that is as
bright as a Dinotte, but way cheaper. It is based on a replacement LED
bulb that an
inventor I work with has just come out with. With this insert, a 60
lumen Surefire flashlight becomes a 240 lumen monster. The batteries
also last longer, due
to a heat sink that improves efficiency.
This light is brighter than a
car light, because I've driven at night in a car, shined the flashlight
ahead onto
the road, and you can see the spot in the pavement illuminated by the
car headlights. It is unbelievably bright. I was camping next to a huge
rock outcropping
and I lit up the whole rock with this little tiny flashlight. When I
drive down the street on my bike in the morning, all the reflective
signs bounce light
back at me. I took it into an REI store and compared it side by side to
a Dinotte, and they were about equal.
Here is the setup on my bike, the Catrike recumbent shown in posts below:
The parts are shown in the picture below, with where to get them
listed below the picture. The picture below shows two Surefire
flashlight setups. One has a
converter, available on ebay for about $8, which allows it to take
longer batteries which last longer. The regular batteries last about
1.5 hours, the larger
ones about 2-2.5 hours.
The parts of this system are as follows:
Flashlight Setup 1 : Surefire 6P flashlight (about $60) (or SureFire 6Z, C2, M2 and G2 or Cabela's 6 v flashlight ($32); from Surefire, Amazon, ebay or Cabela's.
Malkoff M60 insert: about $50: (replaces the fragile bulb that comes with the flashlight), from Tactical Design Labs (http://www.tdlabs.com/
if link doesn't work, under the "New" menu tab.) They
are selling the Malkoff device as an upgrade for police, who use Surefire flashlights
extensively. They say "It will easily illuminate objects at 350+ feet
and will
blind opponents within a 100 foot radius." I believe a Malkoff flashlight will easily to that.
2 CR123 Batteries, AW Brand protected rechargables from Lighthound.com, $7 each
Flashlight Setup 2: same flashlight and Malkoff insert as above, with
Surefire converter, ebay for $8, allows use of the longer 17500 batteries.
2 Batteries, AW Brand-17500-Protected-Rechargeable-Lithium-Battery from Lighthound.com, $11 each.
Fenix 360 Bike Mount, light holder, $15, this is high quality in fit and finish, but rattles. A small rubber band between the top half and bottom half stops the rattle. A no-name brand is also pretty decent, on ebay for $4 shipping, titled: New Bike/Bicycle LED Flash Light Mount Clamp Holder. These are a little loose on the Surefire, so I put a section of inner tube around the flashlight body, for a tighter fit.
Charger: Ultrafire WF-139
Charger for 3.7 volt Lithium Battery Charger, from Lighthound.com, $18.00 (charges several sizes of batteries)
I hope someone tries this setup and tells me how it works for you.
Thanks to Terry Harper, who informs that "one of the earliest such vehicles was patented by Ira Peavey of Maine
in 1907.
At least two were built and tested succesfully. One was stream
poweredm the other used a gasoline engine.
Peavey's machine was designed to haul trains of sleds loaded with logs.
However, he had to compete with Alvin Lombards steam Log hauler which
had appeared earlier in 1902. While Peavey's machine worked great on
hard packed snow it was near useless in soft powder. In addition its
relatively rigid construction meant that it tended to rear and plunge
over the hills and humocks associated with a rough winter haul road and
was quite hard on the drawbars of the sleds. In this respect the
Lombard proved to be a much better machine and dominated the market
here in the north east."