Energy Transformation Why EVs will Impact the Utility Grid

Energy Transformation: Why EVs will Impact the Utility Grid – MarketScale

With the bipartisan National Electric Vehicle Infrastructure (NEVI) funding fast approaching, what are the implications on energy demand and the utility grid and why is EV charging compounding the complexities of grid transmission and distribution?

Currently EVs account for about 1% of the global vehicle market and according to EV Adoption, there are approximately 2 million EV on the road in the US. According to the Department of Transportation’s Federal Highway Administration, the average vehicle travels approximately 13,500 miles annually and EV efficiency is roughly 3.5 miles per kWh suggesting annual energy consumption of 3,870 kWh. According to the DOE Energy Information Administration, the average US home consumes roughly 10,900 kWh a year. Therefore, an EV would potentially account for the 35% of the average US home’s electric usage.  Most homes can be equipped with a Level 2 EV chargers (240 volts / 50 amps) mitigating any grid impact

EV Charging Grid Impact

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Are Electric Vehicles Worth the Investment?

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https://marketscale.com/industries/transportation/are-electric-vehicles-worth-the-investment/

EV Economics

So, what does this EV energy transformation mean to consumers?  Let’s look at a few key factors in evaluating EVs:  economics, driving range, charging time and charging network. For one, it is the understanding of EV economics such as the difference between MPG to miles per kilowatt hour (kWh). Essentially, how far can you drive with a gallon of gas to kWh of energy. According the EPA, the average vehicle fuel efficiency in 2020 was 25.7 MPG. The U.S. Department of Transportation’s Federal Highway Administration states the average person drives around 13,500 milesevery year suggesting an annual fuel cost of over $2,300 at $4.50 per gallon.

The average EV range is approximately 3.5 miles per kWh. One way to assess the economics between MPG and kWh efficiency is to compare the driving costs of traveling 100 miles. With the average fuel cost of $4.50 in the US and 25.7 MPG equates to $17.50.  With an EV achieving 3.5 miles per kWh, the 100-mile traveling cost will depend on whether the EV was charged at home or on a charging network station. According to the Energy Information Administration, the average at home cost is roughly $0.14 per kWh. So, the 100-mile EV travel cost equates to $3.91.

However, if the EV requires charging on a public charging network, the cost is significantly higher. The average kWh cost on public charging networks is approximately $0.42 per kWh ranging from $0.25 from Tesla to $0.33-to-$0.60 on other charging networks. At $0.42 per kWh, the 100-miles travel would cost $12.00 in an EV which is still a 30% savings over conventional vehicles.

Figure 1: 100-Mile Driving Costs

Source: EPA, EIA, Green Econometrics

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Why EVs, Digital Transformation and Crypto will Impact Utility Grid

The US utility grid, comprised of electric generation, transmission (high voltage long distance transport) and distribution (last mile connection to end user) consumes approximately 3.8 trillion kilowatt hours (kWh) with 1.28 trillion kWh in commercial use or roughly 34% of the grid.

In 2021, Electric Vehicles (EV) represented approximately 3% of the registered vehicles in the US. The U.S. Department of Transportation’s Federal Highway Administration states the average person drives around 13,500 miles every year. The average electric car consumes 34.5 kWh per 100 miles. This works out as 0.346 kWh per mile. https://ecocostsavings.com/electric-car-cost-per-mile/ That amounts to 36 billion kWh or 1% of the electric grid.

Vehicle manufacturers are projecting substantial migration to EVs which will increase the impact on the grid. When EVs account for 25% of total vehicles, an additional 7% of grid capacity will be required. 

The required grid buildout will be complicated further by the adding huge numbers of physical EV charging locations. The Federal Government has just allotted $5 billion to assist states that have aggressive charging station construction plans. Bottom line: the EV transformation will have a trillion-dollar impact on the economy — driven by the 30%-to-60%  energy efficiency gain of EVs over internal combustion engines.

Currently, there are over 160,000 fueling locations around the country such as gas stations and convenience stores. EV charging units, not individual locations, just a power connector, are estimated to be at around 36,000. What is important to note is that the majority of these legacy EV charging systems are Level 1 and Level 2 type requiring charge times of an hour to go 100 miles. These legacy EV charging systems are not conducive for vehicle commuting behavior. Who can wait an hour to charge their vehicle?

The trend is for next generation fast charge (FC) and extreme fast charge (EFC) EV charging systems that are capable of extending range and providing faster charge times more indicative of the average gas refueling time.  The limitation is that the number of FC and EFC charging locations is minute. Tesla operates over 20,000 Supercharger connections globally but only 908 physical US locations

The bottom line is that the buildout to support fast charging EVs will require extensive capital investment and generation capacity that is further complicated by managing distributed energy resources such as DC power conversion, energy storage and renewable energy.

While EVs are changing the utility landscape, digital transformation – where greater reliance is required by expanding data centers that consume substantially more energy than manufacturing facilities – is consuming energy at an even faster rate.  The economics of cloud computing, machine learning, AI chips, and analytics-driven business models are only accelerating this digital transformation and dependence on data centers. When one adds crypto currency mining to the mix, the utility grid will predictably undergo substantial change.  At current growth projections, Green Econometrics forecasts that EVs, data centers and crypto mining will require an additional 11% energy generation and grid capacity by 2027.

Why More Energy Storage Investments are in Everyone’s Best Interest

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Why More Energy Storage Investments are in Everyone’s Best Interest – MarketScale

https://marketscale.com/industries/energy/why-more-energy-storage-investments-are-in-everyones-best-interest/

Cloud Analytics Disruptive Innovation

Why Cloud Computing and Data Analytics Enable Digital Transformation

From the inception of the Industrial Revolution several core ingredients enabled the transformation and growth of industry.  Among these core building blocks of the Industrial Revolution namely: access to risk capital, visionary entrepreneurs, available labor, technology, resources and energy.  Technology and energy play a crucial role in not only growing industry but enable scale.   Technology can open new markets and provide advantage through product differentiation and economies of scale.  Energy is literally the fuel that scales operations.

Today technology, built from knowledge and data, is how companies compete. Energy now emerges as even more integral in scaling operations. Just as James Watt developed the first steam powered engine in 1606 commencing the Industrial Revolution, it was the access to available coal with the use of the steam powered pump, invented by Thomas Savery in 1698, that allowed greater access to coal that gave scale to industry.

Most recently, the pending transaction of Salesforce’s (CRM) acquisition of Slack (WORK) after acquiring Tableau last year serves as a reference in valuing the importance of technology is to sustaining market value.  The market value of seven companies accounts for 27% of the approximately $31.6 trillion for the S&P 500.  Evaluating the industry and market impact of innovative technologies can be viewed through the lens of stock valuations, particularly as it applies to mergers and acquisitions.  This article reviews the companies and the technologies from the perspective of market sales opportunity and the economic impact of the technologies based on the price/performance disruption to the industry.

So why are we focusing on energy and data today?  Energy, predominantly hydrocarbon fuels such as oil, natural gas and even coal is how people heat their homes and buildings, facilitate transportation, and generate electricity to run lights, computers, machines and equipment. In addition, there is substantial investment focus on the digital economy, Environmental and Social Governance (ESG), and innovative technologies. A common thread among these themes is energy and data.

Data and Energy are the pillars of the digital economy. Energy efficiency can reduce carbon emissions, thereby improve ESG sustainability initiatives. Innovative technologies around energy and data are opening new markets and processes from formulating new business models to structuring and operating businesses.

The climate imperative and investing in energy infrastructure and environmental ESGs are predicted on energy efficiency and relevant performance metrics to evaluate investment allocation decisions. Therefore, our initial emphasis begins with a background on energy consumption with focus on electric consumption trends, carbon footprint, Green House Gas (GHG) emissions, sustainability, electric grid resilience, and technologies that impact energy including Electric Vehicles (EV), energy storage, and Autonomous Driving (AD).  Data technologies encompass cloud architecture, Software as a Service (SaaS), Machine Learning (ML) analytics, and the importance of data as the digital transformation gives rise to the digital economy. 

Digital Economy Performance Metrics

Before we dive into the financial and competitive analysis, let’s review business models that are disruptive to the status quo. That is are innovative technologies capable of rapid scale and efficiency gains that change the economics of the market and business profitability.  In addition, disruptive events, driven primarily by technology, often appear as waves as the adoption of innovative technologies expands through the market.

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Disruptive Innovation – Why Energy Storage is Crucial Infrastructure

From the inception of the Industrial Revolution several core ingredients enabled the transformation and growth of industry.  Among these core building blocks of the Industrial Revolution namely: access to risk capital, visionary entrepreneurs, available labor, technology, resources and energy.  Technology and energy play a crucial role in not only growing industry but enable scale.   Technology can open new markets and provide advantage through product differentiation and economies of scale.  Energy is literally the fuel that scales operations.

Today technology, built from knowledge and data, is how companies compete. Energy now emerges as even more integral in scaling operations. Just as James Watt developed the first steam powered engine in 1606 commencing the Industrial Revolution, it was the access to available coal with the use of the steam powered pump, invented by Thomas Savery in 1698, that allowed greater access to coal that gave scale to industry.

Most recently, the pending transaction of Salesforce’s (CRM) acquisition of Slack (WORK) after acquiring Tableau last year serves as a reference in valuing the importance of technology is to sustaining market value.  The market value of seven companies accounts for 27% of the approximately $31.6 trillion for the S&P 500.  Evaluating the industry and market impact of innovative technologies can be viewed through the lens of stock valuations, particularly as it applies to mergers and acquisitions.  This article reviews the companies and the technologies from the perspective of market sales opportunity and the economic impact of the technologies based on the price/performance disruption to the industry.

So why are we focusing on energy and data today?  Energy, predominantly hydrocarbon fuels such as oil, natural gas and even coal is how people heat their homes and buildings, facilitate transportation, and generate electricity to run lights, computers, machines and equipment. In addition, there is substantial investment focus on the digital economy, Environmental and Social Governance (ESG), and innovative technologies. A common thread among these themes is energy and data.

Data and Energy are the pillars of the digital economy. Energy efficiency can reduce carbon emissions, thereby improve ESG sustainability initiatives. Innovative technologies around energy and data are opening new markets and processes from formulating new business models to structuring and operating businesses.

The climate imperative and investing in energy infrastructure and environmental ESGs are predicted on energy efficiency and relevant performance metrics to evaluate investment allocation decisions. Therefore, our initial emphasis begins with a background on energy consumption with focus on electric consumption trends, carbon footprint, Green House Gas (GHG) emissions, sustainability, electric grid resilience, and technologies that impact energy including Electric Vehicles (EV), energy storage, and Autonomous Driving (AD).  Data technologies encompass cloud architecture, Software as a Service (SaaS), Machine Learning (ML) analytics, and the importance of data as the digital transformation gives rise to the digital economy. 

Digital Economy Performance Metrics

Before we dive into the financial and competitive analysis, let’s review business models that are disruptive to the status quo. That is are innovative technologies capable of rapid scale and efficiency gains that change the economics of the market and business profitability.  In addition, disruptive events, driven primarily by technology, often appear as waves as the adoption of innovative technologies expands through the market.

Prominent technological waves such as the personal computer (PC), followed by the internet and smartphones and most recently social media and cloud computer all manifested themselves in engendering new business models and creating new market opportunities that dramatically changed the status quo among leading companies at the time. We will use the internet and mobile technology waves to explain how the introduction of innovative technologies offering vastly improved means of commerce enabled the development of new services that changed the business landscape.

Most recent advances in technology appear as waves and give rise to new business models and markets. The internet is one example. The internet enables the connection and process of communication over a new channel.  The internet allowed one-to-one and one to many communications and the ability to engage, transact and scale using a digital platform that tremendously lowered the cost of engagement. Scale is among the most important attributes of the internet because the cost of digital replication is close to zero.

Mobile and smartphones began a new era in the digital world.  The smartphone allowed a large portion of the world to interact with the internet for the first time on a mobile device. The mobile wave provided platform that enabled the introduction of a host of new business models.  The introduction of the Apple iPhone gave way to several new services and industries all from your cell phone.

Let’s review the business model impact of innovative technologies as it applies to cost structure.

Cost Structure and Disruptive Innovation

As explained by ARK Investment Management’s Catherine Wood, the rate of cost decline can be used as a proxy for evaluating the disruptive impact of innovative technology. Cost structure improves as unit production expands. As first postulated by Theodore Wright, an aerospace engineer, who postulated that “for every accumulated doubling of aircraft production, costs fell by about 20 percent”. Wright’s Law as it is now known is also called the Learning Curve or Experience Curve and it is found across industries that experience different rates of declining costs.

What is important from the perspective of investment firms such as Ark is that the magnitude of disruptive impact can be gleaned from these declining cost curves. Revenue growth can then be correlated from these declining cost curves. Essentially, demand elasticity and future sales can be derived from the rate of product cost declines. 

This is why price/performance and scientific metrics play an important role in evaluating products, services and company competitive positions. For example, the average cellular price per gigabyte (GB) of data is approximately $12.37 in 2020 according to Small business trends. Another example in science, is the physical performance of an LED light assessed by lumens the light output to the amount of energy consumed in watts such as lumens/watt (Lm/W). These metrics are points in time. For more context, the changes over time and magnitude of change provide insight into inflection points, trends, patterns and relationships.

As devices become complex, encompassing separate processors for communications, computing, power, video and various sensors, it is the integration and orchestration of the overall device performance that becomes of greater value to the user. So, price/performance, scientific understanding and economics become more attuned to relationships among these varied and interdependent components.

TAM Expansion Attribute

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Mega Trends Thematic Research and Analysis

As digital transformation grows, underlying technology platforms become a core differentiator for key players. Our research reveals that current market leaders need to identify and embrace important new technologies now and adapt to the continuous emergence of new innovative platforms — often through M&A activities. In our full report, we take a look at significant technology disrupters and identify key players to watch.

Two overarching themes, data and energy, inform our approach; and our core premise that drives our innovative technology analysis is that as more commerce commences over digital platforms, more energy is consumed and more data is generated. This lens enables us to identify important emerging trends as well as obstacles to progress; while sorting out the technologies and firms most likely to emerge as winners going forward.

Importantly, our ongoing research reveals that there is also a confluence of interactivity between classes of technology that results in cross dependencies, correlation, cross pollination and scale that creates nuances within each segment. It is our implementation of data collection and analysis between segments, comprehensively addressed in our full report, which adds the insight required for confident decision making. Order your copy now.

In our full report, we identify some of the sectoral trends fueling the new digital economy and the innovative technology companies creating value in our research. Let’s break it down by sector:

 Energy Storage – is the key differentiator for electric vehicles (EVs) and the end-to-end mobility solutions of the future. It also plays a vital role in energy efficiency and resiliency. Energy storage is a core technology to address energy efficiency; critical to controlling carbon emissions, grid resiliency, and providing EV charging solutions. Energy storage systems have substantial benefits for energy consumers, including: industrial, commercial, public, and households. From cost reduction to business continuity and equipment protection, proper energy management delivers significant business efficiencies. There are, however, associated high switching costs for energy storage to be considered. Our focus in our full, in-depth report includes thorough analyses of Plug Power (PLUG), Ballard (BLDP), FuelCell (FCEL), Bloom Energy (BE) and QuantumScape (QS)

Cloud Architecture – another key sector we examine, provides a very cost-effective means of providing separate layers of data storage, computing and transactional services to enterprises and agencies where reliability, scalability and availability are critical to performance and the maintenance of a competitive edge. Virtualization services enable separation of hardware and software as well as method for separating data from control planes. Innovative tools including Databricks and recent IPO Snowflake provide scale and data integration to manage cloud services and data analytics. Our focus in this niche includes Alteryx (AYX), Datadog (DDOG) Palantir (PLTR) Splunk (SPLK) C3.ai (AI) and Snowflake (SNOW).

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Why Visual Data Analytics: Discovery, Innovation and Opportunities

A data analytics framework is applicable to insight discovery; provides a roadmap towards innovation; and enables capabilities that can optimize approaches to new business models and opportunities. The following paper provides examples revealing how and why to apply visual analytics for discovery, innovation and evaluating new opportunities. 

Discover how waveforms and patterns are applied to science and finance, and how customer usage patterns can reveal new approaches to market micro-segmentation and persona classifications.  Lastly we’ll reveal how the deployment of IoT devices across the enterprise fuels data flow in the physical world regarding the performance and conditions of business assets.

Introduction

Our theme is applying visual data analytics as a tool for discovery, innovation and evaluating market opportunities. We show how two metrics, price and volume, are able to convey insight and establish price targets for technical analysis. Why energy consumption patterns and waveforms lend themselves to understanding science and classifying human behavior.  How proxy metrics can serve as measures for physical events. Why linking granular visibility into processes and the monitoring of conditions and operating performance help build an advantage in the digital economy.  

Green Econometrics relies on visual analytics as a core fabric in our data analytics frameworks because visual analytics are integral to discovery, innovation and new opportunity development. Visual insights are easy to understand – allowing business objective and performance metrics to seamlessly transfer across business units. So how do we do it?

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Why Composable and Agile Business Models Need Strategic Business Analytics

There are two overarching megatrends in today’s market: heightened uncertainty and the explosion of data as we migrate to the digital economy. In these circumstances, employing two crucial tactics in business strategy serves to create business value: 1) composability, the framework and interrelationships among component parts that can be reassembled to transform the business model; and, 2) business process agility, the ability to reconfigure resources and business processes for innovation and scale. Both of these tactics require highly granular visibility into business processes along with analytics to measure performance metrics aligned with business objectives. Given elevated levels of uncertainty around employee health and safety in the age of COVID, and the consequent economic and business uncertainty; a well thought out business strategy analytics framework provides a means of navigating uncertainty with greater confidence and lower risk exposure. To be successful in the face of volatility, the analytics framework employed must be structured to optimize outcomes that drive business value.

Disruption and Uncertainty

The pace of technological change and innovation is accelerating. Exogenous events unfold from numerous factors altering the competitive landscape that radically introduce new business models that in turn, redefine the means of competition. To gain a competitive advantage or even just maintain your advantage, new tools are required. These new tools such as cloud architecture, data engineering, secure data access, scale, analytics and machine learning, are integral in creating the capabilities required to remain competitive.

The rapid transition to the digital economy is only exacerbating uncertainty and the disruption to legacy business models. How can companies prepare and take advantage of new technologies to transform their business? For one, developing a business strategy analytics framework to navigate uncertainty and enhance your business model is a must. Essentially, a business strategy analytics framework is designed to measure performance metrics that are relevant to business objectives while optimizing the outcomes for success. One thing is clear, disruptive innovation and competitive landscape is changing fast, composability, agility and analytics are important.

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3 Metrics to Guide Air Quality Health & Safety

What it Means to Your Business

Key Air Quality Metrics

This post explores how the use of three key air quality metrics can improve the health and safety of your business. Occupant health and safety are paramount in the current environment and sensors that detect harmful compounds can serve as front line of defense.  Given these uncertain times, efforts to reduce risks and improve environmental conditions, will help to better support employees and build customer trust.

Begin the process by establishing a goal such as sustainability or worker productivity.  From your goal or objective identify metrics that are aligned with the goal, and then measure your progress toward the goal. Deploying this process improvement framework will improve your business in measureable ways.  In this manner we are transforming metrics and data analytics into performance improvement aligned to desired outcomes including sustainability and energy efficiency. 

Our approach is to identify metrics aligned to your goals and objectives and provide an analytics framework to assess performance. This involves data curation, our proprietary data architecture and machine learning algorithm to provide context, perspective and visual insight.  Key is performance benchmarking for health, safety, sustainability and energy efficiency. These are core environmental metrics and process capabilities that will transform your business model.

To zero-in on important indoor air health metrics, cost effective sensors are required. Based on health and energy efficiency objectives, we found these core indoor environmental metrics, namely carbon compounds including: CO2 and methane, Volatile Organic Compounds (VOCs), and particles. In our previous post, Green Econometrics discussed Air Changes per Hour (ACH) as a measure of air filtration performance – how many times does the air in a room change in an hour?  In this manner, monitoring CO2 levels can serve as a proxy for determining acceptable ACHs.  It is more cost effective to monitor the number of room air changes per hour using air filtration than to deploy expensive sensors to detect pathogens and viruses.

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Indoor Air Quality is Crucial for Safety and Productivity

The risks of viruses are now starkly apparent, and it’s only going to get worse with climate change according to researchers. This begs the question: How do we better protect building and office occupants from the risks of contagion? This post will explore how we can better prepare for future pandemics, reduce the risks of contagion, and navigate the uncertainty of these challenging times. 

The most important element in any interior air and environmental assay is accessing data regarding environmental conditions and operations within a defined space. Applying data analytics and machine learning algorithms can help create a comprehensive roadmap to improve operating efficiencies and understand conditions pertaining to emergent risks and exposure.

A process improvement framework is constructed by transforming data and analytics into metrics that are aligned to desired outcomes such as sustainability and energy efficiency. Green Econometrics has developed a framework to monitor, measure and curate data pertaining to process and sustainability performance.  This is extremely important.

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Analytics Framework for Sustainability

Why the analytics framework for process improvement can translate into substantial benefits around sustainability improvements and energy efficiency. The Coronavirus pandemic has upended social interaction – a new normal, with social distancing and protocols, and so why does sustainability play a crucial role in facilitating a smoother transition into the is new normal.  The reason is sustainability engenders confidence.  Knowing facilities are safe and that indoor air quality monitoring is vital for occupant health and safety builds confidence. Health and safety are also essential in generating the confidence that changes consumer behavior.  Therefore, the process by which you implement a sustainability plan plays an expanding role in orchestrating the activities that adhere to values and performance.

A sustainability framework provides the roadmap to monitor, measure and curate data thus enabling performance benchmarking of conditions and processes.  The analytics framework serves as a roadmap to utilize insight gained from data analysis.  Currently available tools such as data visual analysis, machine learning algorithms and cloud computing architecture enable cost effective approaches to achieve business and sustainability objectives.

A sustainability framework provides the foundation to drive business value across several dimensions and performance metrics.  The use of the sustainability process can drive business value, improve our environment, enhance customer loyalty, and better engage healthier and happier employees while rewarding shareholders and stakeholders with higher business valuations.

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IoT Connected Devices Change Everything

IoT connected devices represent the most important technological wave since the Internet, smartphones, and social media. The value proposition for the Internet of Things (IoT) is compelling because of the economic and financial value created for the built environment. The reason IoT is so important is because it builds and leverages upon the confluence and scale of an array of advanced technologies that continue to push the price-performance horizon including cloud computing, Internet connected mobile phones, semiconductors, distributed computing, machine learning and analytics. Inherent in IoT is that secure context aware connected devices drive improvements in efficiency, productivity, yield, and profitability by reducing costs.

IoT and business intelligence (BI) systems can provide a substantial enhancement to monitoring traditional key performance indicators (KPIs) such as marketing, sales, financial, operational metrics by adding new dimensions of analysis including assets, equipment, environmental conditions, health, safety, and energy. The balanced-scorecard approach to BI provides a more comprehensive understanding of business performance. IoT enables a facet of new metrics and automates the metric recording and analytics process right to your cell phone.

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