Top Electric Two Wheeler Leader In India

Sales of Electric Two Wheelers surged by a whopping 17% this festive season compared to last month in India

The top three companies that did well in October are OLA Electric, TVS Motor, and Bajaj Auto. OLA Electric sold 23,644 vehicles last month, up from 18,615 in September, which is a 27% increase in MOM growth. TVS Motor sold 16,340 vehicles last month, compared to 15,576 in September, showing a 5% MOM growth.

As for Bajaj Auto, they sold 8,289 vehicles last month, compared to 7,087 in September, with a MOM growth of 26%. These companies are doing a great job in the electric market. If we crunch the numbers and calculate the monthly growth of the top five companies, they have 82% of the market share of the total sales.

Source:Electric Vehicle Info

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Today's KNOWLEDGE Share Electric vehicle battery

Today's KNOWLEDGE Share

Electric vehicle battery prices are falling faster than expected

It wasn’t long ago rising demand and component shortages sparked concern that “greenflation” would drive up prices for the batteries used in electric vehicles. That’s subsiding as prices cool for battery metals, which could help make EVs more competitive with traditional cars more quickly. 

Goldman Sachs Research now expects battery prices to fall to $99 per kilowatt hour (kWh) of storage capacity by 2025 — a 40% decrease from 2022 (the previous forecast was for a 33% decline). Our analysts estimate that almost half of the decline will come from declining prices of EV raw materials such as lithium, nickel, and cobalt. Battery pack prices are now expected to fall by an average of 11% per year from 2023 to 2030.

As battery prices fall, Goldman Sachs Research estimates the EV market could achieve cost parity, without subsidies, with internal combustion engine (ICE) vehicles around the middle of this decade on a total-cost-of-ownership basis. 

“The reduction in battery costs could lead to more competitive EV pricing, more extensive consumer adoption, and further growth in the total addressable markets for EVs and batteries.

The EV market was initially driven by regulatory support around the world, but global EV penetration is starting to retreat from recent highs, a potential driver of which could be governments in Europe and China cutting back on subsidies.

So far China is leading the way — its EVs are more competitively priced against ICEs in its local market relative to Europe and the US. While EV sales there have been subsidized by Chinese EV producers, which are selling EVs at a loss, the Goldman Sachs Research expects this to eventually change in around the middle of the decade, when battery price declines and a scale-up in EV sales volumes lead to a significant reduction in EV costs. And whereas Chinese consumers are seeing more options of competitively priced EVs, carmakers in the US and Europe have so far focused on larger and more luxurious EV models.  

Source:goldmansachs

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#evmarket #evbatteries #automotiveindustry #pricereduction #china #goldmansachs #carmakers

Today's KNOWLEDGE Share: Wilhelm Ostwald-Nobel prize 1909

Today's KNOWLEDGE Share:

Wilhelm Ostwald-Nobel prize 1909

Electrochemistry and Chemical Dynamics:

It is assumed that Wilhelm Ostwald started his experimental work in 1875 with investigations of the law of mass action of water in relation to the problems of chemical affinity, with emphasis on electrochemistry and chemical dynamics. From 1894 Wilhelm Ostwald studied catalytic processes. He worked on inorganic, organic and biochemical questions and defined the majority of life processes as catalytic processes. The scientist published an initial determination of the term catalysis in the same year.

The Ostwald Process

In 1902, Wilhelm Ostwald filed the patent for the Ostwald process, used in the manufacture of nitric acid. Often, the year 1908 is given for the invention of the Ostwald process, which may have been the interval between filing the patent and the time it was granted. With the help of the Ostwald process, a more economical and large-scale production of fertilizers and explosives was possible. Also, Ostwald did significant work on dilution theory leading to his discovery of the law of dilution which is named after him. Ostwald’s rule states that in general it is not the most stable but the least stable polymorph that crystallises first. The scientist suggested that the solid first formed on crystallisation of a solution or a melt would be the least stable polymorph. This can be explained on the basis of irreversible thermodynamics, structural relationships, or a combined consideration of statistical thermodynamics and structural variation with temperature.

Source:scihi.org

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Today's KNOWLEDGE Share: Striking the Perfect Balance

Today's KNOWLEDGE Share

Striking the Perfect Balance: Lightweight vs. Comfort in Airplane Cabins 

When flying, we all cherish the unique experience of traveling by air. Today, let's delve into a fascinating topic that often sparks debate: the delicate balance between "Lightweight" and "Comfort" in airplane cabins. 

Lightweight Innovations:

With advancements in materials, technology, and engineering, airlines have been relentlessly striving to make their aircraft lighter. Why? Lighter planes lead to significant fuel savings, reduced emissions, and ultimately, a more sustainable future for air travel. These innovations are remarkable feats of engineering that we can't help but support with our Additive Fusion Technology (AFT)™ design & manufacturing standard! 

The Pursuit of Passenger Comfort:

At the heart of every aviation endeavor lies the utmost priority – passenger comfort. Airlines continuously invest in enhancing the in-flight experience, providing more legroom, adjustable headrests, improved entertainment options, and overall ergonomic seating. After all, a comfortable journey makes a world of difference, especially during long-haul flights. 

Striking the Right Balance:

As airlines evolve, they face the challenge of harmonizing the push for lightweight designs with the quest for ultimate passenger comfort. While reducing weight benefits fuel efficiency, it's essential not to compromise on providing a relaxing and enjoyable flight experience for our valued travelers. 

Collaboration for Future Progress:

The aerospace industry has always embraced collaboration and innovation. As we move forward, it's crucial for airlines, manufacturers, and experts to work hand in hand, finding creative solutions that marry lightweight technology with top-notch comfort. Together, we can shape the future of air travel, one that's both eco-friendly and delightful for all passengers on board. 

Source:Yannick Willemin

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#composites #aviationindustry #lightweight #sustainable

#aft #9tlabs

Heat engine: Bengaluru scientists overcome 200 year old problem on Carnot’s heat-engine

Resolving a 200-year-old challenge, Bengaluru physicists have developed a “heat engine” that generates high-power with high-efficiency, overcoming a “trade-off” associated with all types of engines, from cars and aeroplanes to nuclear reactors.

The path-breaking discovery from researchers at the Indian Institute of Sciences and Jawaharlal Nehru Centre for Advanced Scientific Research opens up the door to design fundamentally new engines using the novel concept, and can be translated into developing tiny microscopic engines for targeted drug delivery inside cells. “This is a conceptual breakthrough that opens up many new doors. It is the beginning of a fresh journey. What was thought impossible, has been achieved, Ajay Sood, Principal Scientific Advisor to the Union government and a co-author of the study, told DH.

In 1824, French engineer Nicolas Leonard Sadi Carnot – known as the father of thermodynamics – proposed what is known as the Carnot engine, the most efficient engine which is theoretically possible. It was a part of his theory on heat engines.

Heat engines are ubiquitous as they lie at the core of cars, aircraft, refrigerators, power plants and miniature motors. But they are currently limited by Carnot's maximum efficiency rule, according to which any attempt to enhance a heat engine's efficiency lowers its power, making the engine useless.

For the last two centuries, all the engines manufactured in the world follow the principles laid down by Carnot. But because of such a trade-off between power and efficiency, a Carnot heat engine was never made.

Take the example of a racing motor-bike, which requires you to pick up speed in a very short time. Their engines produce high power but are not fuel-efficient. In comparison, the regular family motorbikes are more fuel efficient, but they can’t generate such high power.

“Since a zero-power engine is useless, everyone accepts the power-efficiency trade-off like a law. More efficiency will mean lower power and vice versa. It has never been overcome and everyone thought it can’t be done till now,”

Sood, his student Sudeesh Krishnamurthy, who is now at the University of California, Berkley and Ganapathy carried out a series of ultra-precise experiments in the laboratory using a tiny heat engine made out of a single colloidal particle having a dimension of one-hundredth of a human hair.

The microscopic engine was exposed to a rapidly-fluctuating electrical field, because of which the engine’s efficiency reached close to the Carnot’s limit.

“The micro heat engine built by Krishnamurty operates at the Carnot efficiency at small durations of the engine cycle, and this is the regime of practical interest for extracting useful power output from any heat engine,” said Ganapathy.

Source:Deccanherald

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Today's KNOWLEDGE Share:ULTRA HIGH STRENGTH CARBON FIBER

 Today's KNOWLEDGE Share

Toray just unveiled TORAYCA™ T1200, the world's ultra high-strength carbon fiber. This carbon fiber helps move us forward to reducing environmental footprints by making carbon fiber-reinforced plastic materials lighter. This also opens a new performance frontier for strength-driven applications, from aerostructures and defense to alternative energy and consumer products.

Leveraging this fundamental technology led Toray to develop TORAYCA™ T1200 in its new facility within the Ehime Plant (in Masaki-cho, Ehime Prefecture). T1200 has a tensile strength of up to 1,160 Ksi, more than 10% higher than TORAYCA™ T1100, which currently has the highest tensile strength available. T1100 applications include defense weapon systems, space, aircraft, and sports and leisure equipment.

Toray began the commercial production of TORAYCA™ carbon fiber in 1971 at the Ehime Plant and diversified the application into compressed natural gas and high-pressure hydrogen tanks, automobiles, aircraft, and sporting equipment. In 1986, Toray developed TORAYCA™ T1000 and further expanded carbon fiber’s potential by commercializing TORAYCA™ T1100. Toray remains a global leader, with both carbon fibers exhibiting the highest strength available worldwide.

Source:TORAY

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#composites #CarbonFiber #Innovation #tensilestrength #automotive #h2tanks #cngtanks #aerospace

New Bio-based Polyesters with Excellent Tensile Properties Beyond PE and PP

The research group of professor Kotohiro Nomura, Tokyo Metropolitan University, in cooperation with the research group of director Hiroshi Hirano, Osaka Research Institute of Industrial Science and Technology, has developed biobased polyesters from inedible plant resources, which can be easily chemical recyclable and exhibit promising mechanical properties in film than commodity plastics.

Promising Alternative Materials to Commodity Polymers:

The development of high-performance sustainable, recyclable plastics is an important subject to realize circular economy. Biobased polyesters made from plant resources are expected to become promising alternative materials to commodity polymers such as #polyethylene and #polypropylene produced from petroleum. However, there have been few examples of the development of high-performance materials that exceed required mechanical properties such as tensile strength and elongation at break.

Synthesis methods for high molecular weight (long chain) polymers had been a pending issue in conventional polycondensation methods. To solve this issue, the research group has developed an olefin metathesis polymerization method using a high-performance #molybdenumcatalyst, focusing on polyesters derived from inedible plant resources, glucose and so forth.

In general, there is an antinomic relationship between tensile strength and elongation at break in polymer film, as well as increase in molecular weight and elongation at break. However, the present polymer film demonstrates that the tensile properties (strength and elongation at break) of the polymer film increased with the molecular weight, exhibiting superior properties beyond conventional plastics.

The present result is the first success in developing the #biobasedpolyester materials that can be decomposed/recycled and has excellent tensile strength and elongation at break than commodity plastics. The film properties can be further improved by combination with naturally derived fibers such as #cellulosenanofibers. Therefore, the material is expected to be a large breakthrough in the research and development of #plasticmaterials aiming at the #circulareconomy.

About Olefin Metathesis Polymerization Method

"Olefin" is a general term for hydrocarbons with one carbon-carbon double bond. The word “metathesis” means “substitution”. Therefore, the recombination reaction of substituents on the double bond of an olefin is called the olefin metathesis reaction.

For example, there is a reaction where a carbon-carbon double bond in an olefin is replaced with a catalytic metal-carbon double bond (catalytically active species) through the reaction using a catalytic metal such as ruthenium or molybdenum. The #polymersynthesis method using such reaction is called the olefin metathesis #polymerization method.

Source: Japan Science and Technology Agency/specialchem

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