Battery Storage Energy Management

Battery Energy Storage Systems (BESS)

C&I is divided into four subsegments, with the initial one being electric vehicle charging infrastructure (EVCI). According to the McKinsey Center for Future Mobility, electric vehicles (EVs) are projected to experience a significant increase in market share, rising from approximately 23 percent of global vehicle sales in 2025 to 45 percent by 2030. This rapid growth will necessitate the widespread expansion of standard charging stations and superchargers, thereby exerting strain on existing grid infrastructure and requiring expensive and time-consuming upgrades. In order to prevent this situation, charging station companies and owners might choose to install a Battery Energy Storage System (BESS) on their premises. Collaborations have already been established between BESS providers and electric vehicle manufacturers to construct additional Electric Vehicle Charging Infrastructure (EVCI), even in secluded areas.

The last section of the C&I subsegment encompasses challenging settings, including mining, construction, oil and gas exploration, as well as outdoor festivals. The driving force behind its expansion will be customers shifting from diesel or gas generators towards eco-friendly options like BESS and hybrid generators in order to mitigate emissions. One of the primary catalysts for the increasing adoption in this sector is the implementation of forthcoming regulations, such as the European Commission's sustainability-driven Big Buyers initiative and Oslo's objective to achieve net zero on construction sites by 2025. A significant number of companies transitioning to more environmentally friendly practices will initially opt for hybrid genset solutions as an intermediate step before fully transitioning to Battery Energy Storage Systems (BESS).

The market for BESS (Battery Energy Storage Systems) is currently experiencing a rapid phase of growth and development. Companies that fail to take action at this pivotal moment risk losing out on significant opportunities. Success in this market will be determined by four essential factors that companies must demonstrate. As the energy transition gains momentum, these victors will generate value in an emerging market.

As the next stage of objectives outlined in the Paris Agreement draws near, governmental bodies and various organizations are actively seeking to enhance the uptake of renewable energy sources. Certain regions, heavily reliant on energy consumption, offer additional incentives to encourage the exploration of alternatives to conventional energy methods. In Europe, the motivation arises from an energy crisis, while in the United States, it originates from the Inflation Reduction Act, a legislation passed in 2022 that designates $370 billion for clean-energy investments.

Battery Storage Energy Management

The project's operating system, known as the energy management system (EMS), assumes responsibility for controlling (charging and discharging), optimizing (revenue and health), and ensuring safety (electrical and fire). The EMS operates in conjunction with the inverters, battery management system (BMS), breakers, and fire system to coordinate their functions. However, what occurs in the event that it does not yield satisfactory results?

To obtain a summary of the functioning of BMS and EMS, please refer to our publication on BESS and grid assistance. In this section, we will delve into the integration of BESS with SCADA.

According to our analysis, the current situation has presented a notable prospect. Our findings indicate that over $5 billion was allocated to BESS investments in 2022, marking an almost threefold rise compared to the previous year. It is anticipated that the worldwide BESS market will achieve a valuation ranging from $120 billion to $150 billion by 2030, surpassing its current size by more than twofold. However, this market remains fragmented, posing challenges for numerous providers who are uncertain about their competitive positioning and strategies. It is crucial to seize this moment and determine the prime areas of growth in the swiftly advancing BESS market, while also making the necessary preparations for them.

Battery Storage Controls

The advancements in technology are driving the growth of the market for battery energy storage systems (BESS). Battery storage plays a crucial role in supporting the generation of renewable energy, facilitating alternative sources to consistently contribute to global energy requirements despite the inherently unpredictable nature of these sources. As battery prices decrease, the versatility offered by BESS (Battery Energy Storage System) will become crucial in various areas such as peak load management, optimizing self-consumption, and providing backup power during power disruptions. These applications are progressively gaining profitability.

In order to monitor battery readings, the SCADA system generally establishes direct communication with the BMS. Additionally, there may be a need or advantage for the SCADA system to communicate with DC-DC converters, inverters, and auxiliary meters in order to effectively manage the BMS.

In response to economic and operational challenges, there is a prevailing tendency within the industry to enhance or modify the EMS. Making the decision to retrofit the EMS carries significant weight, hence it is vital to meticulously plan the sequence of retrofitting actions. Approximately 20% of the deal flow that FlexGen handles consists of retrofits.

Energy Management System

Large-scale deployments of BESS are already underway, with the notable involvement of FlexGen company in a project aiming to establish a BESS capacity of six GWh in due course. A different United States-based company, involved in various industries including energy, has already exceeded that milestone by achieving 6.5 gigawatt-hours (GWh) in deployments of battery energy storage systems (BESS) in the year 2022. A significant portion of the current influx of funding towards BESS is being allocated to services aimed at enhancing the flexibility of energy providers, such as firm frequency response. Over time, the main source of BESS (Battery Energy Storage System) expansion will arise from the development of solar parks and wind farms, requiring batteries to manage their storage requirements for shorter durations.

In an emerging market such as this, it is crucial to grasp the potential profits and profit margins linked to various products and services. The BESS value chain initiates with manufacturers responsible for producing storage components like battery cells, packs, inverters, housing, and other necessary elements within the system balance. Based on our calculations, the providers involved in this particular sector of the chain are expected to receive approximately 50% of the profit pool generated by the BESS market.

If the project consists of multiple inverters, then only one inverter and its corresponding batteries are required for step 6. As a result, the remaining components of the project can continue functioning with a partial outage while the full outage, lasting two weeks, is solely necessary for the completion of step 7.

Software for Battery Storage

BESS EMS, when contrasted with solar SCADA, presents considerably greater complexity. Several owners have come to realize this through personal experiences that were challenging. The EMS assumes a significant level of accountability in relation to its cost, particularly for projects exceeding 100 MWh in size. In such cases, there are two cost metrics that are taken into consideration.

Critical readings that are transmitted from the batteries/stacks comprise state of charge (SOC), electrical current, voltage, temperature, as well as the quantity of interconnected stacks and alarm indicators. In the case of battery issues such as excessive heat or failure to charge adequately, the SCADA system has the capability to notify plant operators through an alarm displayed on the human-machine interface (HMI).

The BMS encompasses the HMI, which denotes the operational state of the BMS (such as charging, discharging, or idle), desired levels of real and reactive power, limits for state of charge (SOC), alarm information, and input from control parameters.

Battery Storage Integrators

Exploring the realm of software is of utmost importance, particularly within the context of storage systems. It is anticipated that the value of these systems will shift from mere hardware to encompass the software that governs and enhances the overall functionality, presenting an opportunity to attract a wider customer base and achieve greater profitability. It is important for BESS players to cultivate these abilities at an early stage.

The battery management system (BMS) is frequently mistaken for the EMS. The BMS is a straightforward system that serves two purposes: 1) enabling or disabling battery operation and 2) ensuring the safety of the batteries. When initiating a BESS, the EMS will instruct the BMS to activate the batteries (establish the DC bus). The BMS will execute this command only if it detects a safe condition. During operation, if the BMS detects parameters that are exceeding their acceptable range, it will prompt the EMS to decrease power output (in cases where parameters breach fault thresholds, the BMS will activate the opening of rack contactors).

Anticipated advancements in utility-scale Battery Energy Storage Systems (BESS), which presently represent the majority of new capacity each year, are projected to witness a rapid growth rate of approximately 29 percent annually until the end of this decade. This trajectory positions utility-scale BESS as the fastest-growing segment among the three. Projections indicate that by 2030, annual utility-scale BESS installations could range from 450 to 620 gigawatt-hours (GWh), potentially securing up to a 90 percent market share of the total industry during that period (Exhibit 2).

Frequently Asked Questions

What makes FlexGen's battery storage solutions unique?

FlexGen's battery storage solutions stand out due to their advanced HybridOS software, flexible hardware integration, and the ability to provide scalable, reliable, and efficient energy storage for a wide range of applications.

What is FlexGen's HybridOS?

FlexGen's HybridOS is an advanced energy management software designed to optimize the performance and efficiency of battery energy storage systems. It integrates seamlessly with renewable energy sources, providing intelligent control, real-time monitoring, and predictive analytics to enhance energy storage and distribution.

Can FlexGen's solutions integrate with renewable energy sources?

Yes, FlexGen specializes in integrating renewable energy sources like solar and wind with their energy storage solutions. Their HybridOS software is specifically designed to manage and optimize the storage of renewable energy, ensuring a stable and efficient power supply.