LN Magneto.

Liquid nitrogen powered hybrid car well could be an answer for today's transport. First to creating power liquid nitrogen generator magneto driven motor. The Micro Flash Expansion Turbine uses liquid nitrogen as its only fuel. When coupled with an electrical generator this turbine can produce clean quiet and renewable energy. It is not a combustion process and so it is extremely eco-friendly.

In lab tests it has the same compreshion ratio as a petroleum combustion cycle. One in seventy making it as power full as a combustion cycle. How would it drive a car? Well it depends on the figures from combustion gas expansion system this maintains an equal ratio during gas combustion. For instance it doesn't freeze up. Flash Expansion turbine has to be very efficient under acoustic tests. Motors just run a Magneto, to drive the power train. Its like this its quite unique and it has to be heated. Turbine compression it drives a three phaze step up gearing system. This jet has to power the rotation from off the crankshaft. A rotary driven crankshaft or a compression jet cycle could achieve 70 bhp.

High pressure injection turbine with a heat exchanger to power the system. A radiator cools a combustion engine. This has the opposite effect, its driven because of expanding liquid from a housing in a thermos causing gas. Sounds like an easier option. Use silicate composite off the injectors. Its a heat expanction liquid into gas. As its a new science few distinctive styles zag at quiet.

Food Cupboard.

As retailers, the internet of food means finding out everything they need to know, and reducing waste and food safety issues. Everyone hope to see you soon artificial intelligence in particular, are some of the best things to ever happen to a grocery store. Our smartphones and our home-based assistants are ushering in a new way to buy our food. Sure, we can replenish our foods by asking a readymade order from Amazon, and just last week one of my favorite c-stores, Sheetz, announced that their made-to-order foods from all their 564 stores can be ordered online marketing becomes faster than ever.

By 2020, there will be 55 million smart devices in our homes💞Making for the  biggest supermarket chain on the planet. What this clearly shows is that the relationship between the “internet of things” and food has arrived. It's in our homes, in our smart refrigerators and cupboards that will take over the automatic replenishment of those branded products. Fresh ones we can’t live without. Its no paper towel, for ketchups those branded items we love will leave the supermarket with the exciting taste. foods such as the fresh foods, the artisan foods and the prepared foods to focus on and Food Cupboard may become that exceptional service 💕

Coanda less Trail

In 1910 at the Paris air show.

A young engineer named Henri Coanda first tested a plane he had built powered by the worlds first jet engine of which he was the inventor. The engine was not a Turbo jet which was later invented by Frank Whittle and Von Ohain, but had a gasoline engine driven centrifugal compressor, a combustion chamber and nozzle. The sled picture below had no plates thus it's combustion chamber was omitted. It makes it safer, still reached speeds of one hundred miles per hour. 

Coanda placed metal plates between the hot jet gases and the plywood fuselage. However instead of deflecting the jet away it deflected it onto the plates, ran along them and set his plane alight. Fascinated, he failed to notice he was approaching a wall at high speed until the last second, pulled back on the stick, became airborne enough to clear the wall, crashed and was thrown clear to watch his plane go up in flames. As flying was hazardous he built a sled without the combustion chamber. Now 107 years later,  we can assume Henri was ignored. What this one invention could have given our planet. Coanda aircraft can be seen as a cleaner more fuel efficient way to travel. Small engine aircraft less toxic make take another thirteen years heck who's flaunting.

New have rc designs that are different. As croanda jets are ejected from slots and then traverse a hard surface or wall. They are sometimes called a wall jet. This wall after the slot creates a non-symmetrical nozzle. The velocity of the jet immediately evacuates the molecules between it and the wall. This low pressure region cannot be relieved by ambient inflow as ambient air is on the other side of the jet and so the jet quickly deflects toward and runs tangent to the wall. The average pressure across a Coanda jet is lower than the average pressure across an unbounded round jet.


This means that the average velocity at any point in the Coanda jet is higher than in a conventional jet, at the same distance from the slot. It follows then that the pressure is lower at any comparable distance from the slot and the momentum and mass flow are higher at the same points. Todays technology these turbines could be electrical.

Helium Bath.

As with any form of transportation shipping lanes onto land are lightly to become reality for smaller cargo vessels.

Magnetic field locking mechanism for a water sealed bulkhead is new. These baths could be inflated with helium gas. Then these baths can be leveraged across a mountain range. As with any magnetic levitation, can move easily. This is nothing more than a prism based system and can have the stabilization for transportation. Saving time and effort in building such large engineering features and projects. It's a new idea and weights may not exceed the limit for transportation. This is unlike shipping. Hyper loop seems to be used as the new alternative way in the transportation of goods and fresh perishables like fruits. Also cargo flying with the movement in seating. Some of these bath barge's may be like large cargo vessels with the undercarriage of a modern aircraft without it's wing's. Built solutions for commercial container's. Shipping with the fastest possible delivery time in mind. Barge's as super sized containers for large-scale shipping.

Battery Capacitor.

Here's how to print your very own instant rechargeable battery. First coat a layer of graphite oxide, a compound containing carbon, hydrogen and oxygen, on a disc and allow it to dry. Then they place the disc in a DVD label-burning drive, then with the use of software from the company LightScribe and just press send. This software this etches labels onto CDs presentation, punch out this experment. One can remote control a conventional drone without the cost, same formula for solar panels. If the product is introduced into the market, people would be able to charge their phones fully in just ten minutes and would not have to change their laptop batteries every three years and that's a good day. From a graduate student in chemistry and biochemistry called Richard Kaner, professor in the Department of Chemistry and Biochemistry as well as the Department of Materials Science and Engineering in Egypt.

The two had been working to develop a large-scale method for the production of graphene-based supercapacitors, a battery-like charged storage device that El-Kady said could replace the batteries used today “The special thing about (supercapacitors) is that it resonates with the public; everyone can relate to it,” said Kaner, who is the principal investigator in the study. Unlike the average battery, which is made of lithium, a graphene-based supercapacitor can be charged and recharged one million times, Kaner said. It charges quickly, and is inexpensive and easy to manufacture, he added. Graphene is the thinnest, strongest material on Earth, with a high-rate of electron transfer – properties ideal for a . The graphene-based supercapacitor charges 100,000 times faster than regular batteries and is biodegradable. Photography of printed bird house obtain Zip print file.

As I saw these Battery's in a toy tonka and thought about agricultural sciences alas just didn't hit the spot back then, in 2010. It could have save the day for a few. As El-Kadyead is the author of the study. He began working with the compound graphene in 2010. Originally, the team was working to manufacture graphene on a large scale. But when El-Kady saw the potential for graphene’s use as a battery, he and Kaner shifted their focus. To produce graphene, the researchers coat a layer of graphite oxide, a compound containing carbon, hydrogen and oxygen, on a disc and allow it to dry. Then they place the disc in a DVD label-burning drive from the company LightScribe, software that etches labels onto CDs and DVDs directly. When the laser in the drive hits graphite oxide, the compound is converted to graphene, which can be cut to emulate the shape of a battery-like coin cell used in watches. Photography of a steam unit as this could be used to drive any system efficiently.

Like in 2010 El-Kady received the Herbert Newby McCoy Award in 2012 – the highest form of recognition from UCLA’s Department of Chemistry – for the breakthrough. El-Kady and Kaner recently began talking to a company to commercialize the product and bring it to the market. The researchers plan to introduce it to consumers within the next two years, Kaner said. Electric cars are often expensive, and may not always give a good return for consumers because the technology used to power the cars is costly and not as efficient in terms of mileage, said Sanjog Misra, professor of marketing at the UCLA Anderson School of Management. If the technology in electric cars improved, and people could enduce or plug in their cars and charge them up for miles in a few minutes – using the graphene-based supercapacitors – then there could be a significant impact on the electric-car market. Generator to bring up the the charges in the capacitors, tendency to fizzle, one million cycles sounds good on a instant rechargeable. With new techniques it could lead the electric field and bus transportation. No more sulphur dioxide over 💯 particles.

Static Motor's.

Twistron's like some drivites are becoming ever more available. Compelling is their feature an ability to operate in sea water. Could potentially harvest a large amounts of energy from the ocean. The yarn is made from tiny strands of carbon atoms 10,000 times smaller than a hair. The device exploits the ability of nanotubes to transfer motion into energy. This could mean electricity could be produced from a host of natural sources. Innovation could power internet-connected devices and smart clothing. It could also be used to create sea-power stations that can light entire cities. The days of having to carry a phone charger with you could soon be a thing of the past, thanks to a new type of yarn. Scientists have developed a stretchy yarn called twistron' made of carbon nanotubes that can generate its own power. The yarn could be used in a range of products, including smart clothing as all other devices.

Scientists have developed a stretchy yarn made of carbon nanotubes - tiny strands of carbon atoms up to 10,000 times smaller than a hair. Scientists have developed a stretchy yarn made of carbon nanotubes - tiny strands of carbon atoms up to 10,000 times smaller than a hair. The device, which exploits the ability of nanotubes to transfer spring-like motion into electrical energy, has numerous possible applications, according to the paper. In the lab, tests showed that a yarn weighing less than a housefly could light up a small LED light. When sewed into a t-shirt, it could power breathing sensors - like those used to monitor babies - using the stretch caused by the chest expanding at every inhalation Dr Haines said. This increases the voltage associated with the charge stored in the yarn, enabling the harvesting of electricity. Stretching the coiled twistron yarns 30 times a second generated 250 watts per kilogram of peak electrical power when normalized to the harvester’s weight, said Dr. Ray Baughman, director of the NanoTech Institute and a corresponding author of the study. 

But the twistron's most compelling feature was the ability to operate in sea water and potentially harvest vast amounts of energy from the ocean. 'The easiest way to think of twistron harvesters is, you have a piece of yarn, you stretch it, and out comes electricity,' said Carter Haines, a lead author of the study published in the journal Science. The device, which exploits the ability of nanotubes to transfer spring-like motion into electrical energy, has numerous possible applications, according to the paper. In the lab, tests showed that a yarn weighing less than a housefly could light up a small LED light.When sewed into a t-shirt, it could power breathing sensors - like those used to monitor babies - using the stretch caused by the chest expanding at every inhalation. The innovation could be used to power internet-connected devices and smart clothing, said the study's senior author Ray Baughman, a professor at The University of Texas at Dallas. 'Electronic textiles are of major commercial interest, but how are you going to power them,' Dr Baughman said in a statement. 'Harvesting electrical energy from human motion is one strategy for eliminating the need for batteries. Researchers describe “twistron” yarns and their possible applications, such as harvesting energy from the motion of ocean waves 

Compression Question.

Acetic acid is a versatile chemical that can be readily converted to a number of fuels, polymers, pharmaceuticals and chemicals. The team fed the bacteria cadmium and cysteine – an amino acid that contains a sulphur atom. This made the bacteria synthesis cadmium sulphide nanoparticles, which function as mini solar panels on their surfaces. Dr Sakimoto said: 'Once covered with these tiny solar panels, the bacteria can synthesize food, fuels and plastics, all Using solar energy.

'These bacteria outperform natural photosynthesis.' Cyborg bacteria covered in tiny 'solar panels' outcompete plants to produce clean fuel from sunlight. Scientists fed bacteria cadmium and cysteine - an amino acid containing sulphur. This made the bacteria synthesise cadmium sulphide nanoparticles. The nanoparticles function as mini solar panels on their surfaces. Once covered with solar panels, the bacteria could make food, fuels and plastics. They functioned at 80 per cent efficiency, with zero waste. The word 'cyborg' may bring to mind the terrifying robot from the Terminator film. But in a new study, scientists have created a less scary, and much more useful cyborg, by adapting bacteria.

The cyborg bacteria are covered in tiny crystals that act as highly efficient solar panels, producing a range of useful compounds, with zero waste. As cyborg bacteria are covered in tiny crystals that act as highly efficient solar panels, producing a range of useful compounds. The cyborg bacteria are covered in tiny crystals that act as highly efficient solar panels, producing a range of useful compounds. The team used a type of bacteria called Moorella thermoacetica, which naturally produces acetic acid from carbon dioxide.The bacteria operate at an efficiency of more than 80 per cent, and the process is self-replicating and self-regenerating, meaning there is zero waste.Researchers from Harvard University created the cyborg bacteria in the hope of finding an alternative to chlorophyll – the green pigment in plants that harvests sunlight.

Dr Kelsey Sakimoto, who led the study, said: 'Rather than rely on inefficient chlorophyll to harvest sunlight, I've taught bacteria how to grow and cover their bodies with tiny semiconductor nanocrystals. 'These nanocrystals are much more efficient than chlorophyll and can be grown at a fraction of the cost of manufactured solar panels.'Scientists are increasingly looking to find alternatives to fossil fuels as sources of energy and feedstocks for chemical production. While other studies have created artificial photosynthetic systems, these have not been efficient enough for commercial production. In this study, the researchers focused on harnessing inorganic materials that can capture sunlight to bacteria that can use the energy to make useful chemicals. To do this, the team used a type of bacteria called Moorella thermoacetica, which naturally produces acetic acid from carbon dioxide.

Acetic acid is a versatile chemical that can be readily converted to a number of fuels, polymers, pharmaceuticals and chemicals. The team fed the bacteria cadmium and cysteine – an amino acid that contains a sulphur atom. This made the bacteria synthesise cadmium sulphide nanoparticles, which function as mini solar panels on their surfaces. The researchers from Harvard University created the cyborg bacteria in the hopes of finding an alternative to chlorophyll – the green pigment in plants that harvests sunlight. The researchers from Harvard University created the cyborg bacteria in the hopes of finding an alternative to chlorophyll – the green pigment in plants that harvests sunlight. Dr Sakimoto said: 'Once covered with these tiny solar panels, the bacteria can synthesize food, fuels and plastics, all using solar energy. 'These bacteria outperform natural photosynthesis.'The bacteria operate at an efficiency of more than 80 per cent, and the process is self-replicating and self-regenerating, meaning there is zero waste.
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Dr Sakimoto said: 'Synthetic biology and the ability to expand the product scope of CO2 reduction will be crucial to poising this technology as a replacement, or one of many replacements, for the petrochemical industry. Once covered with these tiny solar panels, the bacteria can synthesize food, fuels and plastics, all using solar energy. These bacteria outperform natural photosynthesis. Once covered with these tiny solar panels, the bacteria can synthesize food, fuels and plastics, all using solar energy. These bacteria outperform natural photosynthesis (artist's impression pictured) 'Many current systems in artificial photosynthesis require solid electrodes, which is a huge cost. 'Our algal biofuels are much more attractive, as the whole CO2-to-chemical apparatus is self-contained and only requires a big vat out in the sun.' While the researchers are optimistic about the cyborg bacteria, they highlight that the system needs some tweaking before it can be commercially used.  Scientists tweak photosynthesis to boost crop yield.