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Heat-Resistant Nickel Alloy to Witness Soaring Demand from Onshore Power Plants over 2021-2027

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Heat-Resistant Nickel Alloy to Witness Soaring Demand from Onshore Power Plants over 2021-2027

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Nickel alloy has always been an important material for various industries, including some high-revenue sectors such as automotive, aerospace & defense, owing to its high solubility with iron, chromium, and other vital metals. The high versatility of the material, along with its exceptional heat and corrosion resistance properties enables its application in aircraft gas turbines, steam turbines in power plants, and other high-performance applications.

In onshore wind power plants, nickel-based alloys are primarily used in the gearing and generator components. On the other hand, in hydroelectric installations, nickel alloys are used in turbines owing to their exceptional erosion and corrosion resistance features.


A growing world government emphasis on scaling up power plant infrastructures, coupled with the soaring number of onshore power projects sanctioned to cater to the rapidly rising electricity demand, would foster the demand for nickel alloy to a large extent.

According to Global Market Insights, Inc., report, the global nickel alloy market size is expected to witness remunerative growth by 2027.

Nickel-based alloys and metals have wide-ranging applications in the automotive sector. Apart from its utilization in many automotive parts, nickel is extensively used in the batteries of electric vehicles. Nickel-manganese-cobalt (NMC) lithium-ion battery is witnessing significant adoption in EVs due to its extended power backup.

The rise in electric vehicle production globally is likely to drive the demand for nickel alloy in the coming years. As per the International Environment Agency, approximately 2.1 million electric vehicles were sold in 2019. Moreover, nickel and chromium plating are also used on numerous automotive components to enhance vehicles aesthetics.

The heat-resistant nickel alloy segment is forecast to hold considerable market share by the end of 2027, particularly owing to increasing demand in high-temperature applications. These applications include oil & gas production, and power plants, among others. There have been rising government initiatives to develop a large number of onshore and offshore power plants and oil & gas refineries mostly in developed nations.

From a regional frame of reference, the European nickel alloy industry share is anticipated to expand exponentially owing to the rising number of passenger jet fleets. As per the CAPA Fleet Database, the passenger jet fleet in Europe rose by 1.8% month-on-month in February 2021, to 3,400. The applications of nickel in aircraft engine turbines bring toughness, high-temperature strength, and durability.

Meanwhile, stringent environmental norms encouraging the adoption of electric vehicles and the establishment of renewable-energy power plants would positively influence nickel alloy business in Europe.

Leading companies involved in global nickel alloy business include Ametek Inc., Sandvik AB, Rolled Alloys, Inc., Aperam S.A., Voestalpine AG, Allegheny Technologies Incorporated, Haynes International, Precision Castparts Corporation (Berkshire Hathaway), and ThyssenKrupp AG, among others. These industry players are focusing on strategic alliances and novel product development to strengthen their position in the global market.

Nickel alloy plays a vital role in the transportation sector, right from its utilization in EVs, aircraft, and traditional automotive. Nickel-based stainless steel is used in passenger trains and subways to offer strongness and durability to the outer body. Superior mechanical properties, along with the ability to dilute with other materials expected to foster applications of nickel and nickel-based materials in the forthcoming years.

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What Would a Post-Carbon Supply Chain Look Like?

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Businesses worldwide are pushing for more sustainable practices. As the threat of climate change has worsened, it’s become clear that industry as a whole must move away from carbon emission-generating practices. This movement has significant implications for supply chains.

Today’s supply chains are far from carbon-free. An organization’s supply chain often accounts for 90% of its greenhouse gas emissions when taking overall climate impacts into account. From diesel-powered trucks to natural gas-generated warehouse power, these networks rely heavily on fossil fuels.

It can be hard to imagine supply chains without these resources, but it’s not impossible. Here’s what a post-carbon supply chain would look like and how companies could achieve it.

Electric Vehicles

The most obvious difference between today’s supply chains and a post-carbon one is their vehicles. Transportation accounts for 21% of total global emissions, and freight constitutes a considerable portion of that figure. Almost all trucks that move freight today use fossil fuels, but post-carbon transport will be electric.

Electric trucks will likely be the first type of carbon-free vehicles to appear in supply chains. General Motors has already established goals to produce zero emissions, and electric road vehicles are increasingly common. Post-carbon supply chains will bring electrification to more than just trucks, though.

Ships and airplanes will also be electric. Their longer routes will require more efficiency, so they may rely on technologies like fuel cells or solar power instead of batteries. Regardless of the specifics, every vehicle in the post-carbon supply chain will be electric.

Green Power Sources

While vehicles may be the easiest culprit to pinpoint, they’re not the only source of emissions. Supply chains consume a considerable amount of energy, most of which comes from fossil fuels. In fact, if 125 multinational companies increased their supply chain renewable energy by 20%, they would save more than 1 billion metric tons of carbon emissions.

In a post-carbon supply chain, all energy would come from renewable sources. That would likely mean using various technologies, as sustainable power has varying effectiveness in different applications. Solar, wind and hydroelectric power would all play a part in the transition to zero-carbon operations.

A truly zero-carbon supply chain would also use renewables to generate power for its electric vehicles. Creating batteries or hydrogen for fuel cells requires energy, and this too must be green for supply chains to be truly sustainable.

Sustainable Sourcing

A more easily overlooked aspect of post-carbon supply chains is how sustainability plays into their corporate partnerships. A truly zero-emissions supply chain must ensure its suppliers are also carbon-free. Otherwise, it would still be investing in emissions-producing activity, albeit indirectly.

Industrial sectors like manufacturing are responsible for 29.6% of total emissions in the U.S. If a supply chain moved products from a company with such a significant carbon footprint, one could hardly consider it carbon-free. In a truly post-carbon supply chain, all connected sources are also zero emissions.

Ensuring these connections are sustainable requires a considerable amount of transparency. As such, post-carbon supply chains will require regular audits from involved parties to verify their sustainability. They’ll likely also employ technologies like Internet of Things (IoT) trackers and blockchains to keep operations transparent.

How Can the World Move Toward Post-Carbon Supply Chains?

These factors may seem like lofty goals right now. Today’s supply chains have a long way to go before they can say they’re truly carbon-free. Thankfully, however far-off these sustainability targets may seem, they are achievable. Companies can start acting now to move toward them.

Recognizing the business incentives for removing carbon from the supply chain can help encourage further action. According to one study, 84% of global consumers are more likely to make purchase decisions based on a company’s sustainability practices. Similarly, 61% are willing to wait for longer delivery times if they know it’s better for the environment.

Interest in sustainable supply chains will grow when more organizations realize these benefits. As this trend gains momentum, here are a few ways supply chains can start moving toward zero-carbon goals.

Improve Visibility

The first step in moving away from carbon is improving supply chain visibility. Companies can’t effectively become more sustainable if they don’t know the extent of their current unsustainable practices. Audits and studies can reveal where carbon emissions come from in a supply chain, guiding further action.

Organizations must also ensure their emissions monitoring is an ongoing process. Without continuous checking, they won’t be able to tell how different actions impact their overall goals. Periodic audits and implementing IoT sensors to track carbon emissions can ensure ongoing transparency.

In that spirit, supply chains should start improving visibility between partners. Asking for suppliers to offer proof of their sustainability initiatives will encourage broader action and help reduce emissions on all fronts.

Invest in Green Technologies

Some aspects of the post-carbon supply chain, like electric vehicles, aren’t applicable right now. While options may be limited today, more investment in these technologies will speed their development, making sustainability more viable quicker.

Many companies have already begun to invest in green technologies. Maserati has invested more than $867 million to refurbish its production hub to produce electric cars. As more money flows into these innovations, efficient, low-cost, carbon-free technologies will become available sooner, aiding a faster transition.

Green energy is a technology, not a resource. As such, it will only become cheaper and more efficient over time. Consequently, while some of these technologies may not be viable business choices now, they will be eventually, especially with more funding.

Collaborate

Since supply chains are so interconnected, it will take increased collaboration to push them away from carbon. Decarbonization is also a considerable undertaking. The transition will be far easier and faster if companies can work together toward a common goal.

Collaboration can mitigate the financial burden of decarbonization. Similarly, it can help some companies overcome any qualms they may have about the risks of going green. Climate action experts highlight that shared responsibility translates into reduced risk, at least in people’s perception of it.

In addition to collaborating with other related companies, supply chains can partner with environmental organizations. They can help show where improvements can be made, guiding more effective action.

Supply Chains Must Become More Sustainable

Supply chains are essential to virtually every industry, and they often produce some of the most emissions. As such, these operations must move away from fossil fuels as companies seek to become more sustainable.

The post-carbon supply chain seems like a lofty goal, but it’s attainable. When organizations realize these things are possible, they can start moving toward a better future.

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3 Prominent Trends Influencing the Demand for Power Electronics Market Between 2021-2027

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The power electronics market is estimated to witness stellar growth underscored by the rising requirement for electronics modules in smart home appliances and the purchase of advanced consumer electronics. These modules are used extensively in air conditioners, smart TVs, HVAC control systems, robotic vacuums, smart energy meters, and other smart appliances for increasing the power efficiency of devices and to abstain the possibility of electrocutions. Mounting inclination towards IoT and AI technologies in smart homes could create new business prospects for power electronic manufacturers.

According to a report published by Global Market Insights, the power electronics market is projected to surpass USD 30 billion by 2027. This could be possible given to some of the trends mentioned below.

Ramping up sales of electric vehicles

Electric vehicles are steadily replacing conventional gasoline vehicles and are gaining prominence across North America and Asia Pacific. Escalating prices of fuel in APAC has incited consumers to shift towards more affordable transportation solutions like EVs. Over the coming years, it is likely that electric vehicles could become with the preferred mode of transit in view of new technological advancements in longer-lasting and affordable batteries.

This shift could also evidently ramp up the production of power electronics systems, such as MOSFETs, power switches, power modules, IGBTs, and power management integrated circuits (PMICs), as there are heavily integrated into battery management units (BMU), automotive powertrain systems, and motor drives. Government initiatives to encourage sales of EVs as to concerns over emissions and the environment could boost the supply and demand of power electronics in the EV sector.

Installation of EV charging stations across Europe

With production and sales of electric vehicles spiking up across European countries like France, the UK, Italy, Spain and Germany, the requirement for effective charging infrastructure is heightened. According to the Department for Transport, in January 2021, there were 20,775 public electric vehicle charging devices in the UK, of which, 3,880 were fast chargers. These charging infrastructures are integrated with a myriad of power electronic systems. Incremental construction of new EV charging stations across remote locations in Europe may augment the power electronics business outlook across the region. As per a report, the Europe power electronics market was valued at over USD 4 billion in 2020 is anticipated to register 4.5% CAGR between 2021 to 2027.

Technological advancements in power electronics

Companies like NXP Semiconductor N.V., Texas Instruments Incorporated, Fuji Electric Co. Ltd., Mitsubishi Electric Corporation, STMicroelectronics N.V., ON Semiconductor Corporation, Infineon Technologies AG, TOSHIBA ELECTRONIC DEVICES & STORAGE CORPORATION, among others are holding a significant share in the power electronics sector. All these companies are focusing on taking strategic initiatives like investing in R&D activities for developing technologically advanced products, and mergers & acquisitions.

Highlighting such instances, in May 2019, Infineon Technologies AG announced the launch of HybridPack series of power modules, which has applications in electric vehicles. While in December 2020, Toshiba launched 1,200V silicon carbide (SiC) MOSFET, which has applications in DC-DC converters, photovoltaic inverters, and AC-DC converters.

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Electric Vehicles and the Supply Chain Industry: Top 3 Emerging Trends

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Technology keeps evolving and impacting lives. It is changing how things happen in various industries worldwide. One of the most impacted industries is the supply chain industry, mainly because electric vehicles are becoming more popular now than ever before.

Research shows that by 2025, 30% of all vehicle sales will be hybrid electric vehicles and EVs. Vehicle manufacturers are doing their best to keep up with the demand for electric cars. This has been a result of carriers in the supply chain industry opting for clean-running vehicles.

It is vital to know how electric vehicles are set to transform the supply chain industry. This includes companies that offer car transportation services. In this article, you will learn about emerging electric vehicle trends. It will also look into how the trends will impact the supply chain industry.


 

Read on to find out more.

New Challenges for Automotive Companies

As mentioned earlier, technology has had a massive impact on automotive companies. Supply chain companies are looking for modern cars and trucks. Automotive manufacturers now have new challenges. The materials and parts used in making these cars are different from regular automobiles.

For instance, the designs have substantially changed in modern cars. In addition, the manufacturing process has also changed. Manufacturers have introduced different electronic components. Besides, other pieces of technology like sensors and microchips have also gained popularity in the industry.

Besides these changes, regulations have also become a challenge for automobile manufacturers. Every tiny part used in making modern cars needs to meet regulatory requirements. This hasn’t been an easy thing for car manufacturers worldwide. It has made it a challenge to meet the soaring demand for cars.

The challenges automotive manufacturers experience affects the supply chain industry significantly. It may delay the planned shift to more efficient cars and trucks. But so far, a gradual change has been possible. The reality is that a complete transformation to an energy-efficient industry is still far.

Increasing Demand for Electric Vehicles

The demand for electric vehicles in the supply chain industry doesn’t seem to slow down. For instance, most car shippers have already started changing their fleets. It could happen quicker if automobile manufacturers could produce as many modern cars and trucks as traditional ones.

However, three vital trends are emerging in this industry of late. These trends will impact many things including the costs of shipping cars. This comes as vehicle transporters plan to have more clean-running trucks in their fleets. EVs will reduce the car shipping operating costs and promote a cleaner environment.

This section will take a more in-depth look at the trends impacting vehicle shipping and the supply chain industry.

Here’s the first trend that you should look out for today.

1. Limited Lithium

Lithium-ion batteries power modern electric cars. But then, there have been concerns of whether there’s enough lithium to support their manufacture. This is because of the ever-growing market of lithium-ion batteries. Well, there have been reports that lithium is running out worldwide.

This hasn’t been good news to an already booming electric vehicle industry. It is even worse for the supply chain industry, especially auto car transporters. The planned shift to more efficient trucks to boost their car shipping business may not be achieved as soon as expected.

Predictions already show that at today’s prices, lithium could run out by 2025. However, the good news is that electric vehicles may reach cost parity with regular cars by 2024. That will make it easy for car transporters to shift to electric cars. It will also lead to an overall reduction in car shipping costs.

2. Lower Consumption

Consumption has been a concern for vehicle transporters worldwide. It is the consumption of shipping trucks that pushes car shipping costs high. But then, shipping a car will cost less when motor carriers change their fleets to include more energy-efficient trucks and some electric vehicles.

For energy-efficient trucks, it will be about low gas consumption and less pollution. This will mean well for the environment and also mitigate pollution-related diseases. The good news is that electric cars will take efficiency to a whole new level. They will also mean little or no pollutants into the environment.

This is what companies offering car hauling services want to achieve. They want to contribute to a cleaner environment. Besides, it will also help them keep up with regulations. This will, however, be achieved once electric cars become mainstream and cheaper.

3. Interdependent Supply Chains

There’s a lot more waiting to change in the supply chain industry. This is because changing car shipping fleets alone won’t be enough to achieve a sustainable energy revolution. Chargers and electrical grids will also have to convert to clean energy to achieve this transformation.

Another trend that you’ll see is an increase in the production of more efficient gas-powered cars. Car shippers will have both energy-efficient gas-powered and electric vehicles in their fleets. Thus, the production of gas-powered engines won’t decline like many people could be thinking.

This means that car suppliers will focus both on gas and electric-powered cars. Even if the prices of electric-powered vehicles drop in the future, they may remain relatively expensive. To be precise, the industry will have to wait at least 20 more years before seeing a complete shift in fleets.

Conclusion

The supply chain industry is one of the biggest industries in the world. It is also one of those set to get transformed by the mainstreaming of electric vehicles. This industry has been anticipating a change in trucks for a while. The primary aim has been to reduce consumption and costs as well as be compliant.

This has seemed to happen in recent years as more electric vehicles are getting produced. But it hasn’t meant anything for car transportation companies as they can’t replace entire fleets yet. The supply of electric cars remains low while the demand keeps rising every day.

However, the future remains bright as car manufacturers push for more production. The availability of raw materials like lithium will determine how soon this happens. Meanwhile, stakeholders in the supply chain industry, especially vehicle transporters, will have to be patient.

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New Regulations to Boost Investments into Battery Recycling in the EU

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IndexBox has just published a new report: ‘EU – Electric Accumulators – Market Analysis, Forecast, Size, Trends and Insights’. Here is a summary of the report’s key findings.

The battery market in the EU is expanding on the heels of growth in the electric vehicle and renewable energy industries. In July 2021, the EU instituted new regulations that force battery producers to diminish greenhouse gas emissions throughout all stages of the product lifecycle. Increases in mandatory levels of recovered batteries and the share of recycled materials used in new ones will lead to a critical need for additional recycling capabilities and could drive an investment boom in the market.

Key Trends and Insights

The Global Battery Alliance projects that by 2030 worldwide demand for batteries will increase 14 fold due to the widespread implementation of electric transport methods and deployment in electricity grids. The EU may account for 17% of global demand. In 2030 demand for lithium batteries is forecast to surpass the current amount by a factor of 18, cobalt by 5 and in 2050 by a factor of 60 and 15 respectively.

In July 2021, the EU implemented new regulations to ensure safe use, recycling and disposal of batteries. These regulations could lead to serious changes in the accumulator market. From July 1, 2024, producers selling batteries in the European market will have to provide declarations indicating the carbon footprint created throughout production. Then from July 1, 2027, they must comply with maximum lifecycle carbon footprint thresholds for their products. This will push expenses for producers up as they implement technologies to reduce greenhouse gases. To help companies stay competitive, the new regulations outline developing a plan where governments are obligated to purchase products manufactured with green technologies.

In Europe, over 1.9 million tonnes of waste batteries are generated annually. The current level of recycled materials in the EU is significantly low: only 12% of aluminium, 22% of cobalt, 8% of manganese, and 16% of nickel used within the EU is recycled. Currently, almost no lithium is recovered in the EU because it is deemed to not be cost-effective.

In accordance with the new regulations, targets are set for recovering metals from waste batteries at 90% for cobalt, copper, lead, and nickel, and 35% for lithium by the end of 2025. By 2030 the recovery level should reach 95% for cobalt, copper, lead and nickel, and 70% for lithium. This will require a significant increase in capacity to recycle batteries and thus provide new opportunities for investors. The sector for lithium is one the fastest growing areas and is forecast to expand by 30% annually, experiencing the highest level of demand for recycling capacity.

Electric Accumulator Imports in the EU

In 2020, approx. 1.2B units of electric accumulators were imported in the EU; with a decrease of -8.1% against the previous year’s figure. In value terms, accumulator imports soared to $23.1B (IndexBox estimates) in 2020.

Germany represented the largest importing country with an import of about 386M units, which finished at 33% of total imports. It was distantly followed by Poland (199M units), Hungary (168M units), the Netherlands (96M units), France (65M units) and the Czech Republic (58M units), together achieving a 49% share of total imports. Italy (37M units) followed a long way behind the leaders.

In value terms, Germany ($7.5B) constitutes the largest market for imported electric accumulators in the EU, comprising 32% of total imports. The second position in the ranking was occupied by France ($2.4B), with a 11% share of total imports. It was followed by the Netherlands, with a 6.8% share.

In 2020, the average annual rate of growth in terms of value in Germany totaled +48.6%. The remaining importing countries recorded the following average annual rates of imports growth: France (+1.6% per year) and the Netherlands (+3.4% per year).

The accumulator import price in the EU stood at $20 per unit in 2020, growing by 43% against the previous year. In 2020, the most notable rate of growth in terms of prices was attained by the Czech Republic, while the other leaders experienced more modest paces of growth.

European Imports of Primary Cells and Primary Batteries

Germany represented the major importing country with an import of around 3.1B units, which amounted to 33% of total imports. It was distantly followed by Poland (1,470M units), Belgium (743M units), Romania (624M units), France (605M units), the Netherlands (495M units), Italy (474M units) and Spain (452M units), together constituting a 52% share of total imports.

In value terms, Germany ($534M) constitutes the largest market for imported primary cells and primary batteries in the European Union, comprising 23% of total imports. The second position in the ranking was occupied by France ($238M), with a 10% share of total imports. It was followed by Poland, with a 10% share.

In Germany, the value of battery imports declined by an average annual rate of -2.3% in 2020. The remaining importing countries recorded the following average annual rates of imports growth: France (+10.3% per year) and Poland (+22.0% per year).

Source: IndexBox Platform

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Challenges Facing the Adoption of Electric Truck Fleets

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Innovations in electric truck technology present a major opportunity for business fleets. However, these electric trucks have yet to make much headway in the commercial vehicle market.

Despite several notable milestones and significant corporate investment, consumers and businesses have been slow to adopt these new EVs. A handful of challenges will likely need to be addressed before electric trucks become widely adopted.

Maintenance and High Prices May Be Discouraging EV Adoption

One of the most significant barriers to EV adoption remains cost. The heavy-duty lithium-ion batteries needed to power a truck’s drivetrain can still be extremely expensive. This drives up the cost of new electric trucks compared to similar, gas-powered vehicles.

Reliability and maintenance may also pose a barrier to adoption for some fleet owners. While electric vehicles can sometimes be more reliable than gas cars due to their electric powertrain, they can also be just as or more expensive than conventional vehicles to maintain.

Lithium-ion batteries tend to have a long lifespan, but they don’t last forever. Replacing one can be a major expense. Battery replacement costs for early EVs, like the Nissan Leaf, can be up to $5,000, which is near the resale value of the car. This is due to the price of a new battery and the labor needed to replace the old one.

While most EV maintenance is similar to conventional vehicles, simple failures can cause more serious problems due to the complexity and uniqueness of electric powertrains. Entire components found in a standard, internal combustion engine-powered truck are missing or replaced by other parts, like DC-DC converters, reducers and battery control modules.

If a business wants to keep fleet maintenance in-house, servicing electric trucks will require either hiring new technicians who are knowledgeable about electric trucks or training existing employees in EV upkeep.

The experimental nature of many modern EVs and the use of proprietary firmware may also mean adopting electric trucks would require fleet owners to develop a much closer relationship with dealers and mechanics.

As new EVs age, they may face problems that are hard for businesses to anticipate right now. The reliability of these new electric vehicles may be proven over the next few years — but, for the moment, potential maintenance woes may convince fleet owners to wait on upgrading.

Limited Charging Stations and Range Anxiety May Discourage Adoption

Like most consumer EVs, commercial electric trucks also face the charging problem. Drivers can’t rely on the existing infrastructure of gas stations and truck stops to keep them fueled. There’s a constantly expanding network of EV charging stations being built around the country. Still, outside of a few major cities, available stations may not be common enough to provide a reliable source of power.

Range anxiety — or the fear that EVs don’t store enough power to get a driver from home base to destination to a charging station — is likely a major barrier to the widespread adoption of EVs. Even in areas where charging stations are widely available, the capacity they offer may not be enough to charge EVs in a timely fashion.

For example, the 2021 Tesla Model Y has a range of up to 326 miles and takes eight to 12 hours to get a full charge from a 220-volt power station. Higher-voltage power stations are available commercially, and it’s possible to fully charge a Model Y in just an hour and a half with a Level 3 or 440-volt charger.

However, most existing EV charging stations offer just 220 volts. This means fleet owners will likely have to invest in home charging stations and carefully schedule drivers so they can always make it back to fleet headquarters for a recharge. Businesses that adopt electric trucks would be significantly limited by the density and location of existing charging stations.

While several major infrastructure projects and new subsidies will help increase the number of high-power charging stations, it will be a while before chargers are as common as gas stations.

Investment in the EV Market May Make Electric Trucks More Appealing

Major automakers seem to have committed to the growing EV market. It’s a good sign that, while adoption may be slow, some of the challenges discouraging fleet owners from buying EVs may be solved soon.

Ford has made an $11 billion investment in the EV market and is set to begin delivering the electric counterparts to its flagship truck, the Ford F-150, in early 2022. Other Ford EVs include the brand’s all-electric Mustang Mach-E SUV and the 2021 electric Ford Escape. Notably, the price point for Ford’s new electric F-150 is close to the price of the ICE version of the truck. After tax credits, the base electric model may even be cheaper than the gas-powered F-150.

Ford has also argued that the cost of ownership for the electric truck will be cheaper due to lower maintenance expenses and the price of electricity versus fuel.

General Motors, owner of the Ford brand, has long been an EV pioneer. The company launched one of the first few plug-in electric hybrids on the market, the Chevrolet Volt, in 2011. Affordable, modern EVs like these may convince fleet managers interested in electric trucks but have been cautious about investing in an EV upgrade.

At the very least, the rise of new commercial and consumer electric trucks is a good sign that there will be a robust market for used EVs emerging within the next few years. If these vehicles prove to be reliable, preowned models could provide a stepping stone for fleet owners interested in an electric upgrade but cautious about committing to a fleet of all-new EVs.

What the Future of Vehicle Fleets May Look Like

As investment in the EV market increases, commercial adoption of electric trucks and similar vehicles will also grow.

Current barriers to adoption — the high price of EVs, limited charging infrastructure and concerns around maintenance — are serious but aren’t likely to last forever. Prices are falling, the charging infrastructure is improving and more EVs means more mechanics familiar with repairing these vehicles.

In the near future, fleet owners may begin moving away from conventional vehicles to electric ones, but only once these challenges become easier to manage.

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The American Cable Market Will Shoot Up Thanks to Infrastructure Development for Electric Vehicles

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IndexBox has just published a new report: ‘U.S. – Insulated Wire And Cable – Market Analysis, Forecast, Size, Trends and Insights’. Here is a summary of the report’s key findings.

Electric wires and cables may hit a record demand amid the infrastructure development for electric vehicles in the U.S., for which the Biden administration’s infrastructure bill will allocate $174B. The active deployment of 5G networks and the expansion in the construction sector due to the rush demand for dwellings will also continue driving the market in the medium term.

Key Trends and Insights

The insulated cable and wire market could begin a new era of growth due to the expected increase in demand for infrastructure for electric vehicles in the U.S. In March 2021, the Biden Administration unveiled a plan to stimulate the introduction of electric vehicles, providing for the installation of charging stations throughout the whole country. The plan outlines investing more than $174B in infrastructure creation and development.

The construction boom in the private low-rise building sector will further stimulate the wire market. In the context of an acute shortage of housing amid the rush demand, the intensive pace of new construction will ensure a stable need for cables for the next two years at least.

The intensive construction of a new 5G network for broadband access will be another important driver of the wire market. The development plan for this segment is described in the National Strategy for 5G Security in the U.S., adopted in 2020, which points to allocate $100B for its implementation.

Producer prices for copper wires and cables in the U.S. grew steadily over the last three quarters of last year and prices in April 2021 exceeded their April 2020 level by a rate of 1.3. In the short term, prices are expected to continue growing as demand outstrips the market supply. Production in 2020 fell by 2.7% y-o-y and has not yet fully recovered from market disruptions due to the Covid pandemic. The rise in prices for copper and PVC, raw materials for manufacturing wires and cables, also contributes to the rise in the cost for the final product.

Given the above-mentioned circumstances, the U.S. wire market is expected to post solid gains in the medium, term. Driven by strong demand in the electrocar industry, the construction and the growing telecommunications segment, the market could reach 1.8M tonnes by 2030 (IndexBox estimates).

Insulated Wire and Cable Production in the U.S.

In 2020, the amount of insulated wire and cable produced in the U.S. reduced to 731K tonnes, which is down by -2.7% compared with the year before. Overall, production recorded a perceptible downturn. The most prominent rate of growth was recorded in 2019 with an increase of 6.1% y-o-y. Wire and cable production peaked at 996K tonnes in 2012; however, from 2013 to 2020, production remained at a lower figure.

In value terms, wire and cable production dropped modestly to $9.6B in 2020. Over the period under review, production recorded a perceptible descent. The most prominent rate of growth was recorded in 2019 with an increase of 6.1% year-to-year. Wire and cable production peaked at $12.9B in 2014; however, from 2015 to 2020, production stood at a somewhat lower figure.

Insulated Wire and Cable Imports into the U.S.

In 2020, purchases abroad of insulated wire and cable decreased by -28.1% to 1M tonnes, falling for the second consecutive year after three years of growth. In value terms, wire and cable imports shrank to $18.4B in 2020. The total import value increased at an average annual rate of +2.7% over the period from 2012 to 2020.

In 2020, Mexico (417K tonnes) constituted the largest supplier of wire and cable to the U.S., accounting for a 41% share of total imports. Moreover, wire and cable imports from Mexico exceeded the figures recorded by the second-largest supplier, China (148K tonnes), threefold. Viet Nam (65K tonnes) ranked third in terms of total imports with a 6.3% share.

In value terms, Mexico ($9.4B) constituted the largest supplier of wire and cable to the U.S., comprising 51% of total imports. The second position in the ranking was occupied by China ($2.9B), with a 16% share of total imports. It was followed by Viet Nam, with a 6.1% share.

In 2020, the average wire and cable import price amounted to $17,883 per tonne, increasing by 23% against the previous year. Over the last eight years, it increased at an average annual rate of +3.0%.

Source: IndexBox Platform

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Is There a Shortage of Lithium-Ion Batteries?

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The wider availability of electric vehicles has played a major role in getting more people interested in them. However, analysts warn that a lack of lithium-ion batteries could stifle the surge in electric vehicle adoption.

Here’s a closer look at the matter and some details about the possible associated issues that could affect fleet owners.

Rising Electric Vehicle Usage Causes Elevated Materials Demand

The electric vehicle has experienced recent success that seems unlikely to wane. For example, a global electric vehicle report confirmed there were 2.1 million electric vehicles sold in 2019, which surpassed the previous year’s numbers by 6%.

However, the interest in those automobiles has been far more long-term. The report clarified that there were only 17,000 of them on the world’s roads in 2010. The total soared to 7.2 million by 2019.

Another section of the report goes into the materials required to make batteries for electric cars. The cars sold in 2019 required an estimated 65 kilotons of nickel, 22 kilotons of manganese, 19 kilotons of cobalt, and 17 kilotons of lithium.

However, the report estimates those amounts will rise substantially by 2030 due to ongoing interest in electric vehicles. More specifically, it could increase to at least 925 kilotons of class I nickel, 185 kilotons of lithium per year, 180 kilotons of cobalt, and 177 kilotons of manganese.

A Heavy Dependence on Imports

Most analysts agree that there is not an immediate shortage of lithium-ion batteries, but concerned parties should respond quickly to mitigate the possible effects. One reality is that many nations, including the United States, rely heavily on China to supply battery materials.

A February 2021 executive order from The White House involves looking at current supply chain risks in the United States, then exploring measures to tackle those issues. Batteries were not the only goods mentioned in the document, but the content specified examining concerns associated with critical metals.

Estimates suggest that China accounts for between 70% and 77% of the world’s rare earth elements. Moreover, that country owns most of the processing facilities, even if the source material comes from other places.

As recently as 2019, people became particularly concerned about those realities when tensions rose between the U.S. and China due to a trade war. Experts suggest that building more battery factories in the U.S. is an actionable strategy for lessening the nation’s need for Chinese exports.

That approach would also mean the batteries could travel shorter distances. Shipping the batteries from overseas requires the appropriate risk mitigation strategies, such as transporting them in explosion-proof refrigerated containers.

Domestic manufacturing makes sense, but it’s also not a quick strategy. Since the anticipated lithium-ion battery shortage hasn’t happened yet, there’s still time to figure out what to do when it does. Building factories will likely become part of a multipronged strategy.

Electric Vehicles Make Sense for Fleet Owners, Study Suggests

Outside of the threat of a battery shortage, other factors may cause commercial fleet owners to balk at the prospect of upgrading to all-electric models. However, a recent Berkeley Lab study illustrated some of the potential payoffs.

For example, researchers used current battery cost data and calculated that an electric long-haul truck gives a 13% per-mile decrease in ownership costs compared to the same kind of vehicle that uses diesel. The team also confirmed that electric fleet owners could achieve a net savings of $200,000 over a truck’s lifespan.

They confirmed that aspects like battery price drops and more aerodynamic designs for commercial trucks could slash the per-mile ownership costs by as much as 50% by 2030. The researchers believe that a significant shift from diesel to electric-powered fleets would cause a major reduction in greenhouse gas and particulate matter associated with the transportation sector.

A Battery Shortage Could Increase Buyer Costs

Electric commercial vehicles are still in the minority. It could take a while before that changes, but adoption rates should rise as more decision-makers see examples of successful electric commercial vehicle usage.

Analysts point out that electric vehicles could become about $1,500 more expensive if nickel prices eventually reach a historic high of $50,000 per tonne, though. That possibility could discourage fleet owners if they don’t take overall cost reductions into account.

Elsewhere, a 2019 study of American adults found that 60% cited high upfront costs as a negative aspect of electric vehicle purchase. Relatedly, 84% did not know whether their state offers incentives to offset those buying decisions. Promoting the availability of such programs could make electric vehicles more attractive.

Manufacturers Grapple With Assorted Supply Chain Challenges

Recent coverage also indicates that dealing with lithium-ion battery shortages could be more complicated than it first seems. Contrary to popular belief, there is not a lithium shortage, but rather a surplus. More specifically, Australia, which is among the top producers of lithium, has approximately double the number of mines now as in 2015.

However, certain places — such as the United States — have a lithium shortage compared to other nations. While the U.S. has small lithium deposits in California, they’re much smaller than those in South America and Australia.

A cobalt shortage is a more pressing concern, especially since most of it comes from the Democratic Republic of Congo. Cobalt is one of the most expensive components in an electric vehicle battery, and research suggests there’s not enough mining and processing capability to meet growing demands for it. This example shows that a cobalt shortage could relate more to the capacity required to reach the resource rather than the scarcity of the material itself.

A Dramatic Scaling of Resources

Celina Mikolajczak, vice president of battery technology at Panasonic Energy of North America, noted that lithium-ion battery technology features in numerous consumer devices. However, it’s not at the level required for electric vehicles.

She pointed out that whereas a laptop battery has a dozen cells, one for an electric vehicle has thousands. “How do you quickly scale an industry by 100 times?” she asked, before clarifying, “You need more raw materials, the skilled talent, and machines to extract the raw materials, the factories to process the raw materials into cell components, and then the factories to turn those components into cells.”

A related issue is that the parts required for a car with an internal combustion engine are not the same as those for an electric automobile. Electric vehicles have fewer parts, and the differences mean that a manufacturer could not swiftly pivot to making them after formerly producing autos with engines.

A strategy deployed by companies like BMW and Volkswagen is to invest in battery technology companies. Doing that could give them better access to emerging technologies compared to competitors that didn’t provide such support. That could prove crucial for business models concerning batteries made with more widely available resources. Tesla took another approach by entering long-term agreements with suppliers. Such arrangements allow better pricing.

A Complex Matter

A lithium-ion battery shortage could affect consumers and manufacturers alike, albeit in different ways. The main takeaway for the present is that it’s not a current crisis but a looming one. Plus, there’s no single, straightforward way to tackle it.

Thus, fleet owners who are interested in future electric vehicle investments should plan for the possibility of increasing their budgets to accommodate increased upfront costs. Relatedly, it’s wise for them to stay abreast of the manufacturers that have taken proactive steps to cope with a future battery shortage. Planning now should reduce the possible ramifications later.

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Emily Newton is an industrial journalist. As Editor-in-Chief of Revolutionized, she regularly covers how technology is changing the industry.

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The Permanent Magnet Market to Expect Significant Growth Thanks to the Electric Vehicle Industry

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IndexBox has just published a new report: ‘World – Permanent Magnets – Market Analysis, Forecast, Size, Trends, and Insights.’ Here is a summary of the report’s key findings.

With the development of the electric car and electronic technology industry, the demand for permanent magnets shows significant growth. Thanks to government subsidies, China continues to maintain low market prices for permanent magnets and dominate the export market.

Key Trends and Insights

The permanent magnet market predicts significant growth in the coming years due to the rapid development of consuming industries: electric vehicles, wind turbines, electronics, household appliances. The highest demand is for high-performance and lightweight neodymium iron boron (NdFeB) magnets.

The expansion of the permanent magnet industry will be driven mainly by China’s consuming industries’ growth. According to the China State Council’s New Energy Vehicles (NEV) Industry Development Plan, NEV will account for 20% of the country’s total vehicle sales by 2025, up from a market share of just 4.7% in 2019. This will lead to a significant increase in the need for permanent magnets. In one NEV, permanent magnets are used 2-3 times more by weight than in a car with an internal combustion engine.

The widespread adoption of telecommunication technologies drives electronics production, which also stimulates the market for permanent magnets. According to the National Bureau of Statistics of China, the production of tablet computers increased by 33% in January-September 2020.

Subsidies from the Chinese government to the industry help the country keep prices on permanent magnets down, making the imported products uncompetitive on the local market.

The US government has also begun to actively subsidize the rare earth and permanent magnet industries to reduce dependence on Chinese imports.

China Is Set to Dominate the Permanent Magnets Exports

In 2019, the global permanent magnet market increased by 2.6% to $7.6B, rising for the third consecutive year after two years of decline. The market value increased at an average annual rate of +1.2% from 2012 to 2019.

In value terms, the largest permanent magnet markets worldwide were China ($1.5B), the U.S. ($866M), and Germany ($513M), with a combined 37% share of the global market. Indonesia, Canada, the Philippines, Japan, Mexico, South Korea, Viet Nam, Thailand, India, and Italy lagged, together comprising a further 34% (IndexBox estimates).

The countries with the highest levels of permanent magnet per capita consumption in 2019 were Germany (346 units per 1000 persons), Canada (275 units per 1000 persons), and Thailand (251 units per 1000 persons).

From 2012 to 2019, the most notable growth rate in terms of permanent magnet per capita consumption amongst the key consuming countries was attained by the Philippines, while permanent magnet per capita consumption for the other global leaders experienced more modest growth.

In value terms, China ($2.5B) remains the largest permanent magnet supplier worldwide, comprising 51% of global exports. The second position in the ranking was occupied by Japan ($541M), with an 11% share of global exports. It was followed by Germany, with a 6.9% share (IndexBox estimates).

From 2012 to 2019, the average annual growth rate in terms of value in China was relatively modest. The remaining exporting countries recorded the following average annual export growth rates: Japan (-7.4% per year) and Germany (-1.8% per year).

There were significant differences in the average prices amongst the major importing countries. In 2019, the country with the highest price was the U.S. ($20 per unit), while Indonesia ($3.3 per unit) was amongst the lowest.

Driven by increasing demand for permanent magnets worldwide, the market is expected to continue an upward consumption trend over the next decade. Market performance is forecast to retain its current trend pattern, expanding with an anticipated CAGR of +2.2% for the period from 2019 to 2030, projected to bring the market volume to 783M units by the end of 2030.

Source: IndexBox AI Platform

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The Rising Electric Vehicle Industry to Drive the Global Natural Graphite Market

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IndexBox has just published a new report: ‘World – Graphite (Natural) – Market Analysis, Forecast, Size, Trends, and Insights.’ Here is a summary of the report’s key findings.

In 2020, most countries suspended mines since the pandemic started. However, natural graphite production is projected to grow worldwide, driven by increasing demand from the electric vehicle industry.

Key Trends and Insights

Global natural graphite production in 2020 is estimated to be 15% lower than in 2019 (IndexBox estimates). In most countries, mining has been suspended during the pandemic.

The development of the electric vehicle industry is expected to become the main driver of growth in the natural graphite market, as graphite is the main component of lithium-ion batteries in electric vehicles. According to the Electric Vehicle World Sales Database, the fastest‑growing EV sales in 2020 were in Europe (+ 137% YoY), the US (+ 4%), and China (+ 12%), where the governments subsidize the industry. China’s share of the global electric car market is over 50%. China, the USA, and the EU are the world’s leading lithium-ion battery manufacturers and, therefore, the most promising markets for natural graphite.

Another steadily developing niche is the use of natural graphite as a filler in the plastic industry. China has a dominant market position concerning the global consumption of graphite fillers for plastics.

The market performance is forecast to increase, with an anticipated CAGR of +2.0% for the period from 2019 to 2030, projected to bring the market volume to 1.4M tonnes by the end of 2030.

China to Remain the Key Consumer and Exporter of Natural Graphite

China, with 465K tonnes, remains the largest graphite-consuming country worldwide, comprising approx. 42% of total volume. Moreover, graphite consumption in China exceeded the figures recorded by the second-largest consumer, Japan (129K tonnes), fourfold. The third position in this ranking was occupied by India (79K tonnes), with a 7.3% share.

In China, graphite consumption decreased by an average annual rate of -3.9% over the period from 2012-2019. In the other countries, the average annual rates were as follows: Japan (+5.4% per year) and India (+7.5% per year).

In value terms, China ($422M) led the market alone. The second position in the ranking was occupied by Japan ($114M). Brazil followed it.

The countries with the highest levels of graphite per capita consumption in 2019 were Japan (1,010 kg per 1000 persons), South Korea (804 kg per 1000 persons), and Canada (788 kg per 1000 persons).

From 2012 to 2019, the most notable growth rate in terms of graphite per capita consumption, amongst the main consuming countries, was attained by Canada, while graphite per capita consumption for the other global leaders experienced more modest paces of growth.

China dominates the graphite export structure, accounting for 344K tonnes, which was approx. 65% of total exports in 2019. It was distantly followed by Madagascar (46K tonnes), creating an 8.7% share of total exports. Germany (19K tonnes), Brazil (19K tonnes), Canada (13K tonnes), Mexico (11K tonnes), Norway (11K tonnes), and the Netherlands (9.1K tonnes) held a minor share of total exports.

Exports from China increased at an average annual rate of +4.2% from 2012 to 2019. At the same time, Madagascar (+48.6%), the Netherlands (+19.6%), and Germany (+6.1%) displayed positive paces of growth. Moreover, Madagascar emerged as the fastest-growing exporter exported globally, with a CAGR of +48.6% from 2012-2019. Norway experienced a relatively flat trend pattern. By contrast, Canada (-4.0%), Brazil (-6.9%), and Mexico (-8.6%) illustrated a downward trend over the same period. Madagascar (+8 p.p.) and China (+2.4 p.p.) significantly strengthened their positions in global exports, while Canada, Mexico, and Brazil saw their shares reduced by -1.8%, -3%, and -4% from 2012 to 2019, respectively. The shares of the other countries remained relatively stable throughout the analyzed period.

In value terms, China ($353M) remains the largest graphite supplier worldwide, comprising 59% of global exports. The second position in the ranking was occupied by Germany ($37M), with a 6.2% share of global exports. It was followed by Madagascar, with a 5.5% share.

Source: IndexBox AI Platform