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·State of the art Innovative concept Top system Higher efficient percent.*Power by bar, for Air-Planes, Sea-Boats, Land-Transport & Dynamic Power-Plant Generation. -Have similar system of the Aeolipile Heron Steam device from Alexandria 10-70 AD. -New Form-Function Motor-Engine Device. Next Step, Epic Design Change, Broken-Seal Revelation. -Desirable Power-Plant Innovation. Next trend wave toward global technological coming change.
-YouTube; * Atypical New • GEARTURBINE / Retrodynamic = DextroRPM VS LevoInFlow + Ying Yang Thrust Way Type - Non Waste Looses
The present invention relates to a compression and pushing motor characterized in that it is composed of a housing, said housing accommodates a rotor rotating in its internal space supported by a pair of gears whose passage coincides with the inner surface of the rotor; A rotor (or core) that internally has flow ducts presented one in reverse of another, balanced these, begin at the point where they end; Has several cavity points for reaction turbines, as well as two combustion chambers isolated by means of a system of nozzles and presented in the manner of poles, that is on opposite sides of one another, but their flow with the same circular direction of the rotor when It rotates; The rotor also has several fluid conduits radially presented; A hollow power transmission rod arranged and traversing in the center of the rotor, which in its interior flows the lubricant and fuel with movement of the ends towards the center, at this point by means of the centrifugal force of the rotor reaches the required parts; In the bar is arranged an air intake fan which by rotating the rotor suction air and introduces it to the internal ducts of the rotor with an initial compression, next to this fan is a current collector that generates the necessary electricity and Together with a coil, activates the current necessary for combustion; A center of the nucleus in which the formation of the internal ducts of the rotor begins and ends (in and out); Said center of the core has arranged a pair of semi-cylindrical cavities housing two pairs of turbochargers said core of the core is diagonally traversed by fluid conduits exiting from the bar to the combustion bed and lubrication points and by the centrifugal force of the rotation Of the rotor sends the fluids to the required points due to their radial direction; Exhaust blades are the point of exit of the exhaust gases that leave the internal ducts of the rotor and contrareaccionan with the fixed blade in the last point of use of propulsion of the motor; Two combustion chambers contained in the rotor's strong ducts when the parts forming it are joined, said chambers have their flame in front of the thrust blade, which is connected by a common shaft to a gear located on the outside of the rotor and Coincides with the internal gear of the housing; A starter motor which by means of a gear engages the starter gear attached to the bar.
-This innovative concept consists of hull and core where are held all 8 Steps of the work-flow which make the concept functional. The core has several gears and turbines which are responsible for these 8 steps (5 of them are dedicated to the turbo stages). The first step is fuel compression, followed by 2 cold turbo levels. The fourth step is where the fuel starts burning – combustion stage, which creates thrust for the next, 5th step – thrust step, which provides power to the planetary gears and turbines and moves the system. This step is followed by two hot turbo steps and the circle is enclosed by the final 8th step – bigger turbine. All this motion in a retrodynamic circumstance effect, wich is plus higher RPM speed by self motion. The Reaction at front of the action.
5)2-Thrust - single turbo & planetary gears / ying yang
6)2-Turbo 2 hot
7)2-Turbo 1 hot
8)1-Turbine / bigger
-With Retrodynamic Dextrogiro vs Levogiro Phenomenon Effect. / Rotor-RPM VS InFlow / front to front; "Collision-Interaction Type" - inflow vs blades-gear-move. Technical unique dynamic innovative motion mode. [Retrodynamic Reaction = When the inflow have more velocity the rotor have more RPM Acceleration, with high (XY Position) Momentum] Which the internal flow (and rotor) duplicate its speed, when activated being in a rotor (and inflow) with [inverse] opposite Turns. The Reaction at front of the action. A very strong Novel torque power concept.
-Shape-Mass + Rotary-Motion = Inertia-Dynamic / Form-Function Wide [Flat] Cylindrical shape + positive dynamic rotary mass = continue Inertia positive tendency motion. Kinetic Rotating Mass. Tendency of matter to continue to move. Like a Free-Wheel.
-Combustion 2Two continue circular [Rockets] flames. [ying yang] opposite one to the other. – With 2TWO very long distance INFLOW [inside propulsion] CONDUITS. -4 TURBOS Rotary Total Thrust-Power Regeneration Power System. -Mechanical direct 2two [Small] Planetary Gears at polar position. -Like the Ying Yang Symbol/Concept.
-The Mechanical Gear Power Thrust Point Wide out the Rotor circumference were have much more lever [HIGH Torque] POWER THRUST. -No blade erosion by sand & very low heat target signature profile. -3 points of power thrust; 1-flow way, 2-gear, 3-turbine. *Patent; Dic. 1991 IMPI Mexico #197187 All Rights Reserved. Carlos Barrera.
·2-IMPLOTURBOCOMPRESSOR; Implo-Ducted, One Moving Part System Excellence Design - The InFlow Interaction comes from Macro-Flow and goes to Micro-Flow by Implossion - Only One Compression Step; Inflow, Compression and outflow at one simple circular dynamic motion Concept.
*·“Excellence in Design" because is only one moving part. Only one unique compression step. Inflow and out flow at the same one system, This invention by its nature a logic and simple conception in the dynamics flow mechanics area. The invention is a wing made of one piece in a rotating motion, contained in a pair cavity system connected by implocavity, and interacting dynamically with a flow, that passes internally "Imploded" through its simple mechanism. This flow can be gas (air) or liquid (water). And have two different applications, in two different form-function; this one can be received (using the dynamic flow passage, as a receiver). Or it can be generated (with a power plant, generating a propulsion).
An example cut be, as a Bike needs a chain to work from motor to wheel. And for the Imploturbocompressor application, cut be as; in a circumstance at the engine, as an A-activate flow, and with a a tube flow conduit going to the wheel as a B-receiving-flow the work use.
To see a Imploturbocompressor animation, is posible on a simple way, just to check the Hurricane Satellite view, and is the same implo inflow way nature.
And when the flow that is received and that is intended to be used at best, must no necessarily by a exhausting or rejection gas, but must be a dynamic passing gas or liquid flow with the only intention to count it or to measure it. This could be possible at the passing and interacting period when it passes inside its simple mechanism. This can be in any point of the work flow trajectory.
In case the flow that is received is a water falling by gravity, the Imploturbocompressor can profit an be obtained by generating? electricity such as obtained by the pelton well, like I say before. The "Imploturbocompressor", is a good option to pump water, or a gas flow, and all kinds of pipes lines dynamic moves.
Or only receive the air-liquid flow, in order to measure its passage with a counter placed on the bar, because when this flow passes through the simple mechanism of a rotating wing made of only one piece it interacts within the implocavities system. And this flow can be air wind, with the difference of can have an horizontal work position, and that particle technical circumstances make an easy way for urban building work new use application, and have wind flow from all the sides 180 grades view. The aforementioned information about this invention refers to technical applications, such as a dynamic flow receiver. (whether being gas or liquid).
With the appropriate power plant and the appropriate dimensioning and number of RPM this invention is also feasible to generate an atmospheric air propulsion and the auto-propulsion of an aircraft. Being an effective and very simple system that implodes and compresses the atmospheric air permits the creation of a new concept of propulsion for aircrafts, due to its simple mechanism and innovative nature. At the place of the aircraft were the system appears and the manner how the propulsion direction can be oriented with a vectorial flow (no lobster tail) with I call "yo-yo system" (middle cut (at the shell) to move, one side loose), guided and balanced is feasible to create a new concept of TOVL-vertical take-off landing, Because the exhaust propulsion can going out radial in all the 360 vectorial positions, going out direct all the time in all the vectors direction. With his rotor cover for an better furtive fly, like going down of a bridge for example. Likewise, with the due form and dimensioning, and considering the liquid density and the due revolutions for this element there could be generated a propulsion (water) in order to move an aquatic ship, whether on surface or under water. Also can be a good option to pump liquid combustion for a rocket propulsion.
Making a metaphoric comparison with the intention to expose it more clearly for a better comprehension of this innovative technical detail, it would be similar to the trajectory and motion of a dynamic flow compared with a rope (extended) that passes through the system would have now a knot (without obstructing the flow), so the complete way of the flow at the imploturbocompresor system have three direct ways and between make two different turns; direct way (entrance) - turn - direct way (implocavity) - turn - direct way (exit), all this in a 1 simple circular move system concept.
Its prudent to mention that the curves and the inclinations of the blades of a rotating wing made of this invention, is conferred by its shape and function a structural rigidity allowing it to conduct and alter appropriately the dynamic flow passing through its system.?
Retrodynamic Dextrogiro vs Levogiro Phenomenon Effect. / Rotor-RPM VS InFlow / front to front; "Collision-Interaction Type" - inflow vs blades-gear-move. Technical unique dynamic innovative motion mode. [Retrodynamic Reaction = When the inflow have more velocity the rotor have more RPM Acceleration, with high (XY Position) Momentum] Which the internal flow (and rotor) duplicate its speed, when activated being in a rotor (and inflow) with [inverse] opposite Turns. The Reaction at front of the action. A very strong Novel torque power concept.
"Changing rotation inside a mass makes it possible to change its inertial properties. It is the equation for a jet motion without rejection of any mass.” Albert Einstein.
The logic of creation of an inertial propulsion system is thus: Any motion is rotation ---- Rotation of a matter generates a space-time Torsion ---Torsion of space - time is described by Ricci torsion --- Ricci torsion is an inertial field-----the rest mass of any object is determined by its inertial field---- operating by fields and forces of inertia inside of mass we can create inertial propulsion system which moves according to the equation [m (t) dv/dt =-vdm/dt].
Newton's Third Law of Motion: III. For every action there is an equal and opposite reaction. *Wordpress Blog State of the Art Novel InFlow Gearturbine Imploturbocompressor:
Featured Project Development: State of the Art Novel InFlowTech 1-Gearturbine RotaryTurbo, 2-Imploturbocompressor One CompressionStep: |/ *1; Gearturbine Project, Rotary Turbo, Have the similar basic system of the Aeolipilie Heron Steam Turbine device from Alexandria 10-70 AD · With Retrodynamic = DextroRPM VS LevoInFlow + Ying Yang Way Power Type - Non Waste Looses · 8X/Y Thermodynamic CYCLE Way Steps. 4 Turbos, Higher efficient percent. No blade erosion by sand & very low heat target signature Pat:197187IMPI MX Dic1991 Atypical Motor Engine Type. |/ *2; Imploturbocompressor; One Moving Part System Excellence Design - The InFlow Interaction comes from Macro-Flow and goes to Micro-Flow by Imploducted Implossion - Only One Compression Step; Inflow, Compression and outflow at one simple circular dynamic motion / New Concept. To see a Imploturbocompressor animation, is possible on a simple way, just to check an Hurricane Satellite view, and is the same implo inflow way nature.
Sir Richard Branson is teaming up with Dubai port operator DP world to enter the hyperloop business and move cargo at a top speed of 760mph. The cargo system, which is being designed alongside a possible passenger service by Virgin Hyperloop One, will be called the DP World Cargospeed. Sultan Ahmed bin Sulayem, the port operator´s CEO and chairman revealed the at a glitzy announcement alongside billionaire Mr Branson today on the floating hotel Queen Elizabeth 2 in Dubai. A hyperloop involves levitating pods, powered by electricity and magnetism, hurtling through low-friction pipes at a top speed of 1,220 kph
By Jim Shelton May 2, 2018 Yale physicists looked for a signature of a discrete time crystal in a crystal of monoammonium phosphate.Yale physicists have uncovered hints of a time crystal — a form of matter that “ticks” when exposed to an electromagnetic pulse — in the last place they expected: a crystal you might find in a child’s toy.
The discovery means there are now new puzzles to solve, in terms of how time crystals form in the first place.
Ordinary crystals such as salt or quartz are examples of three-dimensional, ordered spatial crystals. Their atoms are arranged in a repeating system, something scientists have known for a century.
Time crystals, first identified in 2016, are different. Their atoms spin periodically, first in one direction and then in another, as a pulsating force is used to flip them. That’s the “ticking.” In addition, the ticking in a time crystal is locked at a particular frequency, even when the pulse flips are imperfect.
Scientists say that understanding time crystals may lead to improvements in atomic clocks, gyroscopes, and magnetometers, as well as aid in building potential quantum technologies. The U.S. Department of Defense recently announced a program to fund more research into time crystal systems.
Yale researchers Jared Rovny, left, Robert Blum, center, and Sean Barrett, right, made the discovery.MAP crystals are considered so easy to grow that they are sometimes included in crystal growing kits aimed at youngsters. It would be unusual to find a time crystal signature inside a MAP crystal, Barrett explained, because time crystals were thought to form in crystals with more internal “disorder.”
The researchers used nuclear magnetic resonance (NMR) to look for a DTC signature — and quickly found it. “Our crystal measurements looked quite striking right off the bat,” Barrett said. “Our work suggests that the signature of a DTC could be found, in principle, by looking in a children’s crystal growing kit.”
Another unexpected thing happened, as well. “We realized that just finding the DTC signature didn’t necessarily prove that the system had a quantum memory of how it came to be,” said Yale graduate student Robert Blum, a co-author on the studies. “This spurred us to try a time crystal ‘echo,’ which revealed the hidden coherence, or quantum order, within the system,” added Rovny, also a Yale graduate student and lead author of the studies.
Barrett noted that his team’s results, combined with previous experiments, “present a puzzle” for theorists trying to understand how time crystals form.
“It’s too early to tell what the resolution will be for the current theory of discrete time crystals, but people will be working on this question for at least the next few years,” Barrett said.
The National Science Foundation supported the research.
A tracker-equipped cow on the Utah State University dairy farm. -------------
Somewhere o a dairy farm in Wellsville, Utah, are three cyborg cows, indistinguishable from the rest of the herd.
Just like the other cows, they eat, drink, and chew their cud. Occasionally, they walk over to a big, spinning red-and-black brush, suspended at bovine back height, for a scratch. But while the rest of the cows just get their scratch and move on, these cows deliver data. Trackers implanted in their bodies use low-energy Bluetooth to ping a nearby base station and transfer information about the cows’ chewing frequency, temperature, and general rambling around the farm.
These cows are the first to try a device called EmbediVet, created by a startup named Livestock Labs. For now, they’re just going about their normal lives, unintentionally providing data that helps train an artificial neural network. The hope is that in the near future, this AI will help farmers figure out quickly and easily how well cows and other livestock are eating, whether they’re getting sick or about to give birth—things that are typically done today just by watching and waiting but are difficult to spot when you’ve got hundreds or thousands of animals to keep an eye on.
Embedded RFID sensors and other trackers have long been used in livestock, though generally just for identifying each animal. There are already some behavior-tracking wearables out there, such as collars, that use sensors to pinpoint events like cud-chewing and illness. But Livestock Labs claims that once EmbediVet is implanted—currently in a surgical procedure done under local anesthetic—it’s less annoying to the cow than a wearable and, potentially, a more powerful way to collect useful data and spot bovine behavior patterns over time.
This subcutaneous tracker actually had a human tryout before it even got anywhere near a cow. And its creator hopes to eventually bring the cow-tested technology back under your skin.
Livestock Labs' EmbediVet tracker. The rounded part is a bit larger than a quarter. Livestock Labs ----------------------------------------------
Tried in humans, retooled for cattle
Livestock Labs CEO Tim Cannon never set out to make what is, in essence, an embedded Fitbit for cows. What he really wanted was to use the same technology to reengineer himself, and anyone else who wanted to do likewise.
Cannon, a software developer and biohacker, took his first plunge into surgically upgrading himself in 2010 after seeing a video of a Scottish biohacker named Lepht Anonym talking about the sensations produced by a magnet she implanted in her finger. Shortly thereafter, he got his own finger magnet and cofounded Grindhouse Wetware, a biohacking startup in Pittsburgh that focuses on designing and building implantable electronics.
For years at Grindhouse, Cannon and his team made several sensors, including a device called Circadia, which included a thermometer and LED lights that glowed from beneath the skin.
Cannon hoped Circadia could collect data and work with AI software he built to start predicting illnesses. And in 2013, after about a year of work and $2,000 in development costs, he had a Circadia sensor surgically implanted into his arm.
“When we did this, we were actually trying to throw down a glove to the medical industry, to technological fields, to say, ‘Look, if a bunch of idiots in a basement can do this while smoking joints and listening to Wu Tang, what the fuck is the problem?’” Cannon says.
The problem, it seems, is that beyond a small community of hackers, grinders, and curiousobservers, most people just aren’t interested in having things implanted in their bodies, especially if these things aren’t medically necessary.
Grindhouse tried selling the implants it created, but it wasn’t making money. It couldn’t pull in any investors, so Cannon and others were funding the work themselves with their day jobs. They grew aware of the enormous regulation challenges they faced if they wanted to make non-essential implants for humans, he says, and realized that the job would undoubtedly include years of work and millions of dollars.
Then, last spring, an Australian biohacker named Meow-Ludo Disco Gama Meow-Meow (yes, really) contacted Cannon with an idea. A tech incubator in Sydney, Cicada Innovations, was about to launch a program that focused on helping build agricultural food technology companies (the country has a large livestock industry, with about 25.5 million cattle). How about putting sensors in cows instead of people?
It was like a “Duh, it’s obvious” moment, Cannon says. His new venture, dubbed Livestock Labs, was accepted to Cicada’s GrowLab program. In September, Cannon moved to Sydney from his home in Pittsburgh, and soon started working with a small team to remake the Circadia sensor from scratch into one that could be implanted in farm animals.
Within months, Livestock Labs readied a new device—now called EmbediVet—for testing in cattle. Covered in a clear resin, it includes an ARM processor and Bluetooth and long-range radios, as well as a thermometer, accelerometer, and heart-rate monitor and pulse oximeter for measuring heart rate, blood oxygen levels, temperature, and basic activity. It runs on a coin-cell battery the company expects will last for about three years.
On the farm
On April 3, Kerry Rood, an associate professor at Utah State University’s School of Veterinary Medicine, implanted a series of EmbediVet sensors in three cows on the school’s dairy farm: two in the left side of the lower jaw, and one between two ribs. (Since there’s not much existing data about the best places for implanted activity trackers in cattle, and Livestock Labs wants to log chewing and rumination, these seemed like good starting points.)
To perform this minor surgery, Rood gave the cows local anesthesia, sliced their hide in the proper spots, slipped in an EmbediVet prototype, and stitched them up. Over a month later, he says, they’re tolerating the implants well.
A cow on Utah State University's dairy farm that has been embedded with Livestock Labs' EmbediVet tracker. Livestock Labs -----------------------------------------------------
Why do it? Rood thinks that this kind of device can be more accurate than a wearable one such as a collar or an anklet, especially when it comes to tracking a metric like body temperature, which correlates with disease, in thick-skinned animals.
To check out the early data, Cannon says, he’s built some charting software that can pull in what’s gathered from the cows’ EmbediVet devices and plot it out. Eventually, Livestock Labs intends for farmers to use a smartphone app to check out their animals’ status and see alerts about issues.
“As a veterinarian, if there’s some way I can detect animal diseases, animal discomfort, earlier, then I’m ahead of the ballgame when it comes to providing care and welfare to these animals,” Rood says.
With just homemade needles and some cells from an ear biopsy, Jose Cibelli of Cyagra demonstrates how to build a blue-ribbon steer.
Beyond the work Livestock Labs is doing with Rood, Cannon says, other research trials are in the works with Charles Sturt University and the University of New England, both in Australia, as well as trials with some commercial farmers he won’t name. He hopes EmbediVet will be available in a public beta test next March.
“We stumbled onto something that was a lot bigger and more in demand than we thought, in this particular sector of the world,” Cannon says.
Ryan Reuter, an associate professor of animal science at Oklahoma State University who studies beef cattle, thinks the tracker could be quite useful. He cautions, however, that there are a lot of factors to consider with its design. For instance, cows are big and strong and like to rub on things (such as that aforementioned back scratcher), so anything implanted in them needs to be rugged enough to hold up to abuse. It also needs to stay in place, he says, especially with animals being raised to be eaten.
“That would be important in food animals, so you make sure that you put the implant somewhere that it has no chance of ending up in a food product for humans,” he says.
There’s also the issue of pricing, since margins in dairy and beef cattle production are slim. The components of EmbediVet cost $20 right now, Cannon says, but it’s not clear what the eventual price will be; Reuter says that somewhere in the range of $10 or $20 a cow would get beef or dairy farmers interested.
Back to you, humans?
These days, Cannon splits his time between Pittsburgh and Sydney. Livestock Labs has $2 million in early funding from Australia’s livestock industry group, Meat & Livestock Australia (which is also a GrowLab partner), and additional funds from individual investors in the US.
For now, he’s concentrating on making sure that the implants aren’t causing any unintended consequences with the cyborg bovines.
“They are developing a slight urge to destroy humanity,” he jokes, “but we’re monitoring it.”
Joking aside, Cannon is serious about one goal that’s far beyond anything his startup may do to help farmers and their livestock. He says he also hopes the company gets people more comfortable with the idea of bodily implants in general. He is adamant that one day he will return to offering sensors to people—though he’s not sure if it will be a totally new company or a “human line” from Livestock Labs.
The second option, he admits, might be “just a little bit too much for people.”
Ingestible sensor developed at MIT that can detect biomarkers of internal bleeding in the stomach. Credit: Lillie Paquette, MIT. --------------------------------------------------
Doctors are now one step closer to deploying sensors that can travel to parts of a patient's body to diagnose hard-to-detect conditions.
The details: In a new study published Thursday in MIT's Science journal, researchers report on a tiny sensor they developed that can be swallowed, which contains genetically modified bacteria capable of detecting heme, a component of blood, in the stomach. The bacterial response can be converted into a wireless signal, which is then read by nearby computers or a specially-designed app on an Android phone.
Hunting down internal bleeding: The researchers created sensors aimed at detecting internal bleeding in the stomach, which can be caused by a variety of disorders, such as ulcers, and is often hard to identify. They also designed sensors that can locate a marker of inflammation.
What they found: In the experiments, the genetically engineered E. Coli bacteria produced light when they came in contact with blood or inflammation components in the gut of pigs. The researchers combined this capability, which synthetic biologists have previously demonstrated, with a low energy electronic chip that converted the light into a signal that could be transmitted to a nearby phone or computer. This combination of bacterial sensing with low power circuits and transmitting capabilities is what makes the findings so novel.
“Our vision is we want to try to illuminate and provide access to areas that are not easily accessible.”— Timothy Lu, MIT associate professor of electrical engineering.
Methodology: The researchers took a genetically modified, probiotic strain of E. Coli and placed it inside their sensor, along with a membrane that allowed small molecules from the surrounding environment to pass through. They also installed transistors to measure the light produced by the E. Coli cells when they came into contact with heme, which is the substance inside red blood cells that binds to oxygen in the lungs. The transistors then would send that information to a tiny chip, and relay a signal to a nearby phone or computer.
-- GThe sensor is not quite small enough yet to be put into wide use, nor does it have Food and Drug Administration approval for human applications. It's about 1.5 inches long, and needs about 13 microwatts of power, which for now comes from a 2.7-volt battery. The researchers said they could "probably" reduce the sensor's volume by about one-third, thereby making it far more suitable for human use.
Tests in pigs were successful: The tests in pigs showed promising results, with the sensor picking up whether any blood was in the animals' stomach. It's possible that the device, or others like it, could be used to monitor the stomach consistently for days or weeks, constantly sending signals that would be monitored by patients and their doctors.
Why it matters: This would have significant advantages over current diagnostic tools, such as endoscopy, which requires patients to be sedated and only gives a one-time snapshot of the stomach's contents.
-- Study co-author Mark Mimee said the techniques used for this study could be used to detect the presence of other biomarkers in addition to heme.
What they're saying: “We could evolve these systems to apply to virtually any other biomarker,” he said during a press conference call on Tuesday. “This is platform technology that could be used by many synthetic biology groups.”
Lu said building biomarkers to detect various health conditions is becoming "a whole field" unto itself, and that for some diseases, such as colon cancer, you may soon be able to swallow an early warning pill. “What if you could actually swallow a pill every week or every month that gives you early detection?” he said.
The bottom line: This ingestible biosensor is an example of the future of diagnostic tools.