세계의 압축 공기 에너지 저장(CAES) 시장 : 유형별, 지출 유형별, 저장 형식별, 용도별, 용량별, 지역별 - 예측(-2030년)
Compressed Air Energy Storage Market by Type (Adiabatic, Diabatic), Expenditure Type (CAPEX, OPEX), Storage Form (Underground, Above Ground), Application (Grid Management, Renewable Energy Integration), Capacity, and Region - Global Forecast to 2030
상품코드:1836425
리서치사:MarketsandMarkets
발행일:2025년 10월
페이지 정보:영문 236 Pages
라이선스 & 가격 (부가세 별도)
ㅁ Add-on 가능: 고객의 요청에 따라 일정한 범위 내에서 Customization이 가능합니다. 자세한 사항은 문의해 주시기 바랍니다.
한글목차
세계의 압축 공기 에너지 저장(CAES) 시장 규모는 2025년 4억 8,000만 달러, 2030년까지 18억 8,000만 달러에 이르고, 예측 기간 동안 CAGR 31.4%로 성장할 전망입니다.
조사 범위
조사 대상 연도
2020-2030년
기준 연도
2024년
예측 기간
2025-2030년
단위
100만 달러, MW, MWh
부문
유형, 지출 유형, 용량, 저장 형식, 용도, 지역
대상 지역
유럽, 아시아태평양, 북미 및 기타 지역
시장은 신재생에너지의 통합을 지원하고 송전망의 신뢰성을 높이기 위해 장기운전이 가능하고 배출가스를 배출하지 않는 에너지저장 솔루션에 대한 요구 증가에 의해 견인되고 있습니다. 압축 공기 에너지 저장(CAES) 시스템은 잉여재생가능전력의 대규모 저장을 가능하게 하고, 온실가스를 직접 배출하지 않고 발송가능한 전력을 공급하기 때문에 화석연료에 대한 의존성을 줄이고 기후 변화 목표를 달성하기 위한 실현가능한 옵션이 됩니다. 신재생에너지 채택 증가는 CAES 플랜트와 같은 저장 인프라에 대한 수요를 직접적으로 증가시킵니다. 시장의 확대는 깨끗하고 지속 가능한 에너지 저장 기술을 우월한 법률, 정책 및 투자 인센티브에 의해 더욱 강화됩니다.
"그리드 관리 부문이 2025년부터 2030년까지 가장 높은 CAGR을 기록합니다."
압축 공기 에너지 저장(CAES) 시스템은 장시간 유연성을 제공하고 수급 변동의 균형을 맞추어 운영 효율성을 높입니다. CAES는 신재생에너지 간헐성의 과제를 경감하고, 저 수요기에는 이용률이 낮은 발전에 대한 안정성을 확보하고, 피크 부하기에는 송전망의 과부하를 방지합니다. CAES의 그리드 관리를 지원하는 기술은 성숙해지고 있으며, 개발 위험을 줄이고 대규모 투자를 촉진하고 있습니다. 또한, CAES 시스템은 기존의 송배전 네트워크에 잘 통합될 수 있기 때문에 전력 기업은 재생에너지의 보급률이 중간에서 높은 지역을 타겟팅할 수 있습니다. CAES의 규모와 설치 장소는 다양하므로 전개 기회가 크고 전반적인 송전망의 탄력성과 접근성이 향상됩니다. 게다가, 예측되는 재생가능 에너지 용량의 확대는 그리드 관리에서 CAES의 경제성, 특히 시스템 수명, 낮은 운영 비용, 언시러리 서비스의 제공이라는 점에서 충분히 지지되고 있습니다.
“지하 저장이 예측 기간에 가장 급성장하는 부문이 됩니다.”
지하 저장 부문에서 압축 공기 에너지 저장(CAES) 시스템은 소금 돔, 대수층, 경암층과 같은 자연적으로 존재하거나 전용으로 만들어진 동굴을 활용하여 보다 높은 효율성과 신뢰성을 실현합니다. 이러한 지질 구조는 대규모의 안전하고 비용 효율적인 저장 용적을 제공하여 소규모 지상 탱크의 미사용 위험과 대체 저장 솔루션의 잠재적인 비용 상승을 방지합니다. 지하 CAES의 기술은 잘 확립되고 널리 입증되어 개발 위험을 줄이고 투자자의 신뢰를 높일 수 있습니다. 게다가, 지하 시설은 재생가능 에너지의 보급률이 중간에서 높은 지역에서의 전개에 전략적으로 적합하며, 그리드의 안정성과 탄력성을 강화하는 장기적인 용량을 제공합니다. 확장성과 적응성은 시장 수요 증가에 부합하기에 이상적이며, 건설, 유지보수, 긴 수명 등의 경제적 실행가능성은 CAES 채택을 세계적으로 추진하는 역할을 더욱 강화합니다.
"유럽이 가장 빠르게 성장하는 압축 공기 에너지 저장(CAES) 시장이 될 것입니다."
유럽은 여러 대규모 프로젝트에 지원되는 압축 공기 에너지 저장(CAES)의 급성장 시장입니다. 독일에서는 Corre Energy와 Eneco가 소금 동굴을 이용한 대규모 CAES 시설을 아하우스에서 개발하고 있으며, 2027년까지 300MW를 넘는 발전 용량을 공급할 전망입니다. 네덜란드에서는 Core Energy가 Floningen에서 Zuidwending 프로젝트를 진행하고 있으며 며칠 동안 저장 능력을 갖춘 수소 대응 CAES 플랜트로 설계되었습니다. 이와 함께 EU는 CAES를 태양열 시스템과 통합하여 효율성과 유연성을 향상시키는 ASTERIx-CAESar와 같은 혁신 프로젝트를 지원합니다. 이러한 노력은 유럽이 에너지 전환 전략의 일환으로 장기 저장에 강력하게 헌신하고 있음을 강력하게 보여줍니다.
본 보고서에서는 세계의 압축 공기 에너지 저장(CAES) 시장에 대해 조사 분석하여 주요 촉진요인과 억제요인, 경쟁 구도, 미래 동향 등의 정보를 제공합니다.
목차
제1장 서론
제2장 조사 방법
제3장 주요 요약
제4장 중요한 지견
압축 공기 에너지 저장(CAES) 시장의 기업에게 매력적인 기회
아시아태평양의 압축 공기 에너지 시장 : 지출 유형별, 국가별
압축 공기 에너지 저장(CAES) 시장 : 유형별
압축 공기 에너지 저장(CAES) 시장 : 지출 유형별
압축 공기 에너지 저장(CAES) 시장 : 저장 형식별
압축 공기 에너지 저장(CAES) 시장 : 용도별
압축 공기 에너지 저장(CAES) 시장 : 지역별
제5장 시장 개요
소개
시장 역학
성장 촉진요인
억제요인
기회
과제
고객사업에 영향을 주는 동향/혼란
공급망 분석
생태계 분석
기술 분석
주요 기술
보완 기술
인접 기술
사례 연구 분석
특허 분석
무역 분석
수입 시나리오(HS 코드 841490)
수출 시나리오(HS 코드 841490)
주요 컨퍼런스 및 이벤트(2025년-2026년)
규제 상황
규제기관, 정부기관, 기타 조직
규제
Porter's Five Forces 분석
주요 이해관계자와 구매 기준
투자 및 자금조달 시나리오
압축 공기 에너지 저장(CAES) 시장에 대한 AI/생성형 AI의 영향
시스템 모델링 및 최적화를 위한 AI
AI에 의한 예지보전
신재생에너지 통합 및 그리드 관리를 위한 AI
세계의 거시경제 전망
소개
정부 정책과 보조금
에너지 전환과 탈탄소화 목표
설비투자(CAPEX)의 동향
에너지 안보와 지정학
기술 혁신
제6장 압축 공기 에너지 저장(CAES) 시장 : 지출 유형별
소개
CAPEX
OPEX
제7장 압축 공기 에너지 저장(CAES) 시장 : 유형별
소개
비단열
단열
등온
제8장 압축 공기 에너지 저장(CAES) 시장 : 저장형식별
소개
지하
지상
수중
제9장 압축 공기 에너지 저장(CAES) 시장 : 용량별
소개
소규모
중규모
대규모
제10장 압축 공기 에너지 저장(CAES) 시장 : 용도별
소개
그리드 관리
신재생에너지 통합
기타 용도
제11장 압축 공기 에너지 저장(CAES) 시장 : 지역별
소개
북미
미국
캐나다
아시아태평양
중국
호주
기타 아시아태평양
유럽
독일
영국
네덜란드
스위스
기타 유럽
기타 지역
중동 및 아프리카
남미
제12장 경쟁 구도
개요
주요 참가 기업의 전략/강점(2020년-2025년)
주요 기업 시장 랭킹(2024년)
브랜드 비교
기업 평가 매트릭스 : 주요 기업(압축 공기 에너지 저장(CAES) 기술 공급자)(2024년)
경쟁 시나리오
제13장 기업 프로파일
기술 제공업체
HYDROSTOR
STORELECTRIC LTD
CORRE ENERGY
APEX CAES
AUGWIND
HIGHVIEW POWER
KEEP ENERGY SYSTEMS
BAROMAR
SHERWOOD POWER
기타 기술 제공업체
TERRASTOR ENERGY CORPORATION
ALACAES
ENAIRYS POWERTECH
POWERPHASE INTERNATIONAL
BRAYTON ENERGY, LLC
CAES 시스템 제공업체
SIEMENS ENERGY
EVERLLENCE
INGERSOLL RAND
KOBE STEEL, LTD.
DOOSAN SKODA POWER
GREEN-Y ENERGY AG
SHAANGU
기타 CAES 시스템 제공업체
HARBIN TURBINE COMPANY LIMITED
ATLAS COPCO GROUP
MITSUBISHI HEAVY INDUSTRIES, LTD.
제14장 부록
SHW
영문 목차
영문목차
The compressed air energy storage market is expected to grow from USD 0.48 billion in 2025 to USD 1.88 billion by 2030, at a CAGR of 31.4% during the forecast period.
Scope of the Report
Years Considered for the Study
2020-2030
Base Year
2024
Forecast Period
2025-2030
Units Considered
Value (USD Million) and Volume (MW, MWh)
Segments
By Type, Expenditure Type, Capacity, Storage Form, Application, and Region
Regions covered
Europe, Asia Pacific, North America, RoW
The market is driven by the growing need for long-duration, emission-free energy storage solutions to support renewable integration and enhance grid reliability. Compressed air energy storage (CAES) systems enable large-scale storage of surplus renewable electricity and provide dispatchable power without direct greenhouse gas emissions, making them a feasible option for reducing reliance on fossil fuels and achieving climate targets. Rising renewable energy adoption directly increases the demand for supporting storage infrastructure such as CAES plants. Market expansion is further reinforced by laws, policies, and investment incentives that favor clean, sustainable energy storage technologies.
"Grid management segment to register highest CAGR from 2025 to 2030"
Compressed air energy storage (CAES) systems enhance operational efficiency by providing long-duration flexibility and balancing supply-demand fluctuations. They mitigate the challenges of renewable intermittency, ensuring stability against underutilized generation during low-demand periods and preventing overburdening of grids during peak loads. The technology supporting grid management through CAES is maturing, reducing development risks and encouraging large-scale investment. Furthermore, CAES systems integrate well into existing transmission and distribution networks, allowing utilities to target regions of moderate to high renewable penetration. Their versatility in scale and siting offers significant deployment opportunities, improving overall grid resilience and accessibility. Additionally, the predicted expansion of renewable capacity is well supported by the economic feasibility of CAES in grid management, particularly in terms of system lifetime, low operating costs, and provision of ancillary services.
"Underground storage form to be the fastest-growing segment during forecast period"
In the underground storage segment, compressed air energy storage (CAES) systems achieve higher efficiency and reliability by utilizing naturally occurring or purpose-built caverns, such as salt domes, aquifers, or hard-rock formations. These geological structures provide large, secure, and cost-effective storage volumes, avoiding the underutilization risks of smaller above-ground tanks and the potential cost intensiveness of alternative storage solutions. The technology for underground CAES is well established and widely proven, which reduces development risks and attracts greater investor confidence. Additionally, underground facilities are strategically suited for deployment in regions with moderate to high renewable penetration, offering long-duration capacity that strengthens grid stability and resilience. Their scalability and adaptability make them ideal for meeting growing market demand, while their economic feasibility in terms of construction, maintenance, and long operational life further reinforces their role in advancing CAES adoption globally.
"Europe to be fastest-growing compressed air energy storage market"
Europe is the fastest-growing market for compressed air energy storage (CAES), supported by several large-scale projects. In Germany, Corre Energy and Eneco are developing a major CAES facility in Ahaus using salt caverns, which is expected to provide over 300 MW of generation capacity by 2027. In the Netherlands, Corre Energy is advancing the Zuidwending project in Groningen, designed as a hydrogen-enabled CAES plant with multi-day storage capability. Alongside these, the EU is supporting innovation projects such as ASTERIx-CAESar, which integrates CAES with solar thermal systems to improve efficiency and flexibility. These initiatives highlight Europe's strong commitment to long-duration storage as part of its energy transition strategy.
In Europe, ambitious climate targets and renewable energy directives are driving strong policy support for long-duration storage solutions such as CAES. The EU's Green Deal, along with funding mechanisms like Horizon Europe and Projects of Common Interest (PCI), provides financial and regulatory backing to accelerate development. National governments in countries like Germany and the Netherlands are further supporting CAES projects through grid modernization incentives and renewable integration programs.
In-depth interviews were conducted with various key industry participants, subject-matter experts, C-level executives of key market players, and industry consultants, among others, to obtain and verify critical qualitative and quantitative information and assess future market prospects. The distribution of primary interviews is as follows:
By Company Type: Tier 1 - 57%, Tier 2 - 29%, and Tier 3 - 14%
By Designation: C-Level Executives - 35%, Directors - 20%, and Others - 45%
By Region: North America - 20%, Europe - 15%, Asia Pacific - 30%, Middle East & Africa - 25%, and South America - 10%
Notes: The tiers of the companies are defined based on their total revenues as of 2024; Tier 1: > USD 1 billion, Tier 2: USD 500 million to USD 1 billion, and Tier 3: < USD 500 million. Others include sales managers, engineers, and regional managers.
Hydrostor (Canada), APEX CAES (US), Storelectric LTD. (UK), Keep Energy Systems (UK), Corre Energy (Netherlands), TerraStor Energy Corporation (US), ALCAES (Switzerland), Augwind (Israel), Enairys Powrtech (Switzerland), Highview Power (UK), Baromar (Israel), Powerphase International (US), Sherwood Power (UK), Brayton Energy, LLC (US), Siemens Energy (Germany), Evellence (Germany), Ingersoll Rand (US), KOBE STEEL, LTD. (Japan), Doosan Skoda Power (Czech Republic), Green-Y Energy AG (Switzerland), Shaangu (China), Atlas Copco Group (Sweden), Harbin turbine company limited (China), and MITSUBISHI HEAVY INDUSTRIES, LTD. (Japan) are some of the key players in the compressed air energy storage market. The study includes an in-depth competitive analysis of these key players in the compressed air energy storage market, with their company profiles, recent developments, and key market strategies.
Study Coverage:
The report defines, describes, and forecasts the compressed air energy storage market by type (Adiabatic, Diabatic, Isothermal), expenditure type (CAPEX, OPEX), storage form (Underground, Underwater, Above ground), capacity (Small (Below 50 MWh), Medium (50-500 MWh), Large (above 500 MWh)), Application (Grid Management, Renewable Energy Integration, Others), and region (North America, Europe, Asia Pacific, RoW). The report's scope covers detailed information regarding the major factors, such as drivers, restraints, challenges, and opportunities, influencing the growth of the compressed air energy storage market. A thorough analysis of the key industry players has provided insights into their business overview, solutions, and services; key strategies such as contracts, partnerships, agreements, expansion, Joint ventures, collaborations, and acquisitions; and recent developments associated with the compressed air energy storage market. This report covers the competitive analysis of upcoming startups in the compressed air energy storage market ecosystem.
Key Benefits of Buying the Report
The report includes the analysis of key drivers (Growing integration of renewable energy, Enables short-term and long-term storage across diverse applications, Long operational lifespan and reduced maintenance requirements), restraints (Competition from alternative storage technologies, Geological dependency and storage feasibility,) opportunities (Government incentives & regulatory support, Rising need to ensure grid resilience) and challenges (High upfront capital costs, Lower round-trip efficiency).
Product Development/Innovation: Compressed air energy storage (CAES) market participants are advancing innovations across the value chain-covering storage form, capacity, expenditure models, and applications. In plant design, modular and scalable configurations, optimized turbomachinery, and advanced thermal management systems are enhancing efficiency, flexibility, and reliability. In storage and compression, companies are developing improved cavern engineering techniques, isothermal and adiabatic processes, and hybrid systems with hydrogen or thermal storage to boost round-trip efficiency and reduce emissions. Digital tools, including AI-driven plant optimization, predictive maintenance, real-time monitoring, and smart grid integration, are increasingly being deployed to improve performance, extend asset life, and ensure seamless integration with renewable energy and grid management systems.
Market Development: In May 2024, BaroMar and RheEnergise signed an agreement to advance long-duration energy storage (LDES) projects in Cyprus and the UK. Under this partnership, BaroMar engaged Jacobs to design a 4 MWh underwater compressed air energy storage (CAES) pilot off Cyprus' coast, using rigid seabed-ballasted tanks to bypass land constraints. Meanwhile, RheEnergise launched a 500 kW high density pumped hydro energy storage (PHES) project at Sibelco's Cornwood mining site near Plymouth, UK, utilizing dense fluids for compact operation. This report provides a detailed analysis of compressed air energy storage solution provider strategies critical for project success, providing stakeholders with actionable insights into trends and opportunities for growth in the compressed air energy storage market.
Market Diversification: The report offers a comprehensive analysis of the strategies employed by compressed air energy storage solution providers to facilitate market diversification. It outlines innovative products and operating models, as well as new partnership frameworks across various regions, underpinned by technology-driven business lines. The findings emphasize opportunities for expansion beyond traditional operations, identifying geographical areas and customer segments that are currently served but remain underserved and are suitable for strategic entry.
Competitive Assessment: The report provides in-depth assessment of market shares, growth strategies, and service offerings of leading players such as Hydrostor (Canada), APEX CAES (US), Storelectric LTD. (UK), Keep Energy Systems (UK), Corre Energy (Netherlands), TerraStor Energy Corporation (US), ALCAES (Switzerland), Augwind (Israel), Enairys Powrtech (Switzerland), Highview Power (UK), Baromar (Israel), Powerphase International (US), Sherwood Power (UK), Brayton Energy, LLC (US), Siemens Energy (Germany), and Evellence (Germany), among others, in the compressed air energy storage market.
TABLE OF CONTENTS
1 INTRODUCTION
1.1 STUDY OBJECTIVES
1.2 MARKET DEFINITION
1.3 STUDY SCOPE
1.3.1 MARKETS COVERED
1.3.2 INCLUSIONS AND EXCLUSIONS
1.3.3 YEARS CONSIDERED
1.4 CURRENCY CONSIDERED
1.5 LIMITATIONS
1.6 STAKEHOLDERS
2 RESEARCH METHODOLOGY
2.1 RESEARCH DATA
2.1.1 SECONDARY DATA
2.1.1.1 List of key secondary sources
2.1.1.2 Key data from secondary sources
2.1.2 PRIMARY DATA
2.1.2.1 List of primary interview participants
2.1.2.2 Key data from primary sources
2.1.2.3 Key industry insights
2.1.2.4 Breakdown of primaries
2.2 DATA TRIANGULATION
2.3 MARKET SIZE ESTIMATION
2.3.1 BOTTOM-UP APPROACH
2.3.2 TOP-DOWN APPROACH
2.3.3 DEMAND-SIDE ANALYSIS
2.3.3.1 Demand-side assumptions
2.3.3.2 Demand-side calculations
2.3.4 SUPPLY-SIDE ANALYSIS
2.4 FORECAST
2.5 RISK ANALYSIS
3 EXECUTIVE SUMMARY
4 PREMIUM INSIGHTS
4.1 ATTRACTIVE OPPORTUNITIES FOR PLAYERS IN COMPRESSED AIR ENERGY STORAGE MARKET
4.2 COMPRESSED AIR ENERGY MARKET IN ASIA PACIFIC, BY EXPENDITURE TYPE AND COUNTRY
4.3 COMPRESSED AIR ENERGY STORAGE MARKET, BY TYPE
4.4 COMPRESSED AIR ENERGY STORAGE MARKET, BY EXPENDITURE TYPE
4.5 COMPRESSED AIR ENERGY STORAGE MARKET, BY STORAGE FORM
4.6 COMPRESSED AIR ENERGY STORAGE MARKET, BY APPLICATION
4.7 COMPRESSED AIR ENERGY STORAGE MARKET, BY REGION
5 MARKET OVERVIEW
5.1 INTRODUCTION
5.2 MARKET DYNAMICS
5.2.1 DRIVERS
5.2.1.1 Strong focus on renewable energy generation
5.2.1.2 Significant demand for technologies supporting hybrid energy ecosystems
5.2.1.3 Long operational lifespan and low maintenance requirements
5.2.2 RESTRAINTS
5.2.2.1 Competitive pressure due to presence of alternative storage technologies
5.2.2.2 Dependence on geological formations to store compressed air at high pressures
5.2.3 OPPORTUNITIES
5.2.3.1 Government incentives and regulatory support for CAES projects
5.2.3.2 Global clean energy transition
5.2.4 CHALLENGES
5.2.4.1 High upfront costs
5.2.4.2 Lower round-trip efficiency than substitutes
5.3 TRENDS/DISRUPTIONS IMPACTING CUSTOMER BUSINESS
5.4 SUPPLY CHAIN ANALYSIS
5.5 ECOSYSTEM ANALYSIS
5.6 TECHNOLOGY ANALYSIS
5.6.1 KEY TECHNOLOGIES
5.6.1.1 Adiabatic compressed air energy storage (A-CAES)
5.6.1.2 Liquid air energy storage (LAES)
5.6.2 COMPLEMENTARY TECHNOLOGIES
5.6.2.1 Carbon capture and storage (CCS)
5.6.2.2 Hydrogen CAES integration
5.6.3 ADJACENT TECHNOLOGIES
5.6.3.1 Battery energy storage
5.6.3.2 Pumped-storage hydropower
5.7 CASE STUDY ANALYSIS
5.7.1 UNDERWATER CAES SYSTEM PROVIDES SICILY WITH YEAR-ROUND RENEWABLE POWER BY CONVERTING SURPLUS WIND AND SOLAR ENERGY
5.7.2 WIND FARMS IN IRAN INTEGRATE CAES TO STABILIZE GENERATION AND MAXIMIZE CONSISTENT SUPPLY OF ENERGY
5.8 PATENT ANALYSIS
5.9 TRADE ANALYSIS
5.9.1 IMPORT SCENARIO (HS CODE 841490)
5.9.2 EXPORT SCENARIO (HS CODE 841490)
5.10 KEY CONFERENCES AND EVENTS, 2025-2026
5.11 REGULATORY LANDSCAPE
5.11.1 REGULATORY BODIES, GOVERNMENT AGENCIES, AND OTHER ORGANIZATIONS
5.11.2 REGULATIONS
5.12 PORTER'S FIVE FORCES ANALYSIS
5.12.1 THREAT OF SUBSTITUTES
5.12.2 BARGAINING POWER OF SUPPLIERS
5.12.3 BARGAINING POWER OF BUYERS
5.12.4 THREAT OF NEW ENTRANTS
5.12.5 INTENSITY OF COMPETITIVE RIVALRY
5.13 KEY STAKEHOLDERS AND BUYING CRITERIA
5.13.1 KEY STAKEHOLDERS IN BUYING PROCESS
5.13.2 BUYING CRITERIA
5.14 INVESTMENT AND FUNDING SCENARIO
5.15 IMPACT OF AI/GEN AI ON COMPRESSED AIR ENERGY STORAGE MARKET
5.15.1 AI FOR SYSTEM MODELING AND OPTIMIZATION
5.15.2 AI-DRIVEN PREDICTIVE MAINTENANCE
5.15.3 AI FOR RENEWABLE INTEGRATION AND GRID MANAGEMENT
5.16 GLOBAL MACROECONOMIC OUTLOOK
5.16.1 INTRODUCTION
5.16.2 GOVERNMENT POLICIES AND SUBSIDIES
5.16.3 ENERGY TRANSITION AND DECARBONIZATION GOALS
5.16.4 CAPITAL EXPENDITURE (CAPEX) TRENDS
5.16.5 ENERGY SECURITY AND GEOPOLITICS
5.16.6 TECHNOLOGY INNOVATION
6 COMPRESSED AIR ENERGY STORAGE MARKET, BY EXPENDITURE TYPE
6.1 INTRODUCTION
6.2 CAPEX
6.2.1 ONGOING LONG-DURATION ENERGY STORAGE PROJECTS TO CREATE GROWTH OPPORTUNITIES
6.3 OPEX
6.3.1 RISING ADOPTION OF SERVICE-BASED AND PERFORMANCE-LINKED CONTRACTS BY UTILITIES TO SUPPORT MARKET GROWTH
7 COMPRESSED AIR ENERGY STORAGE MARKET, BY TYPE
7.1 INTRODUCTION
7.2 DIABATIC
7.2.1 CAPACITY TO STORE ENERGY IN BULK TO ENCOURAGE DEPLOYMENT
7.3 ADIABATIC
7.3.1 CARBON-FREE OPERATIONS, SUSTAINABILITY, AND ABILITY TO REUSE STORED HEAT TO PROMOTE DEMAND
7.4 ISOTHERMAL
7.4.1 HIGH ROUND-TRIP EFFICIENCY AND REDUCED TECHNICAL COMPLEXITY TO ENCOURAGE DEPLOYMENT
8 COMPRESSED AIR ENERGY STORAGE MARKET, BY STORAGE FORM
8.1 INTRODUCTION
8.2 UNDERGROUND
8.2.1 SCALABILITY AND LONG-DURATION STORAGE CAPACITY NECESSARY FOR GRID-SCALE APPLICATIONS TO BOOST ADOPTION
8.3 ABOVE GROUND
8.3.1 SIMPLIFIED PERMITTING PROCESSES AND SUITABILITY FOR DISTRIBUTED AND MICROGRID APPLICATIONS TO SUPPORT SEGMENTAL GROWTH
8.4 UNDERWATER
8.4.1 NEED TO EXPAND STORAGE OPTIONS IN COASTAL AND LAKESIDE REGIONS TO DRIVE MARKET
9 COMPRESSED AIR ENERGY STORAGE MARKET, BY CAPACITY
9.1 INTRODUCTION
9.2 SMALL-SCALE
9.2.1 INCREASING EFFICIENCY AND FAVORABLE POLICIES FOR ABOVE GROUND STORAGE SOLUTIONS TO DRIVE MARKET
9.3 MEDIUM-SCALE
9.3.1 POTENTIAL TO OFFER SCALABILITY AND COST EFFICIENCY TO SPIKE DEMAND
9.4 LARGE-SCALE
9.4.1 ABILITY TO SUPPORT BULK RENEWABLE INTEGRATION DURING PEAK DEMAND FOR EXTENDED OUTAGE TO SPUR DEMAND
10 COMPRESSED AIR ENERGY STORAGE MARKET, BY APPLICATION
10.1 INTRODUCTION
10.2 GRID MANAGEMENT
10.2.1 GROWING NEED FOR FLEXIBLE AND RELIABLE POWER STORAGE SYSTEMS TO ACCELERATE SEGMENTAL GROWTH
10.3 RENEWABLE ENERGY INTEGRATION
10.3.1 INCREASING RENEWABLE DEPLOYMENT AMID ENERGY CRISIS TO FOSTER SEGMENTAL GROWTH
10.4 OTHER APPLICATIONS
11 COMPRESSED AIR ENERGY STORAGE MARKET, BY REGION
11.1 INTRODUCTION
11.2 NORTH AMERICA
11.2.1 US
11.2.1.1 Emerging CAES projects supported by private and institutional investors to fuel market growth
11.2.2 CANADA
11.2.2.1 Rising renewable penetration and decarbonization targets to boost demand
11.3 ASIA PACIFIC
11.3.1 CHINA
11.3.1.1 Abundance of salt-cavern resources to accelerate CAES deployment
11.3.2 AUSTRALIA
11.3.2.1 Supportive policies backing dispatchable energy technologies to drive market
11.3.3 REST OF ASIA PACIFIC
11.4 EUROPE
11.4.1 GERMANY
11.4.1.1 Rise of long-duration energy storage to drive market
11.4.2 UK
11.4.2.1 Government-backed decarbonization targets to boost demand
11.4.3 NETHERLANDS
11.4.3.1 Transition toward low-carbon, renewables-dominated energy system to contribute to market growth
11.4.4 SWITZERLAND
11.4.4.1 Adoption of innovative CAES research and pilot projects to create opportunities
11.4.5 REST OF EUROPE
11.5 ROW
11.5.1 MIDDLE EAST & AFRICA
11.5.1.1 Expanding renewable-linked storage infrastructure to drive demand
11.5.2 SOUTH AMERICA
11.5.2.1 Investments in renewable-integrated storage solutions to propel demand
12 COMPETITIVE LANDSCAPE
12.1 OVERVIEW
12.2 KEY PLAYER STRATEGIES/RIGHT TO WIN, 2020-2025
12.3 MARKET RANKING OF KEY PLAYERS, 2024
12.4 BRAND COMPARISON
12.5 COMPANY EVALUATION MATRIX: KEY PLAYERS (COMPRESSED AIR ENERGY STORAGE TECHNOLOGY PROVIDERS), 2024
