市场调查报告书
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1466252
区域冷却市场:按冷却技术、组件、部署、应用划分 - 2024-2030 年全球预测District Cooling Market by Cooling Technique (Absorption Cooling, Electric Chillers, Free Cooling), Component (Central Chiller Plant, Consumer System, Distribution Network), Deployment, Application - Global Forecast 2024-2030 |
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预计2023年区域供冷市场规模为101亿美元,预计2024年将达109亿美元,复合年增长率为8.18%,2030年将达175.2亿美元。
区域冷却是一种高效、经济且环保的方式,可为区域或都市区的多栋建筑物提供空调。冷冻水透过保温管道集中生产并分配给各种住宅、商业和工业最终用户。区域供冷系统具有许多优点,包括节能、减少温室气体排放以及降低营运和维护成本。近年来,由于多种影响因素,全球区域供冷市场不断增长,其中包括由于对温室气体排放和气候变迁的日益担忧而对节能製冷解决方案的需求不断增加,以及支持采用绿色技术的政府政策。生长。政府和私人公司之间的一家合资企业正在促进对区域供冷系统基础设施的投资。然而,建设区域供冷基础设施需要大量资本投资,这对潜在投资者构成了阻碍。
主要市场统计 | |
---|---|
基准年[2023] | 101亿美元 |
预测年份 [2024] | 109亿美元 |
预测年份 [2030] | 175.2亿美元 |
复合年增长率(%) | 8.18% |
此外,一些国家复杂的法律规范可能会阻碍区域供冷计划的顺利实施。为了克服这些挑战并挖掘区域冷却市场的巨大成长潜力,组织正在投资先进的热交换器、冷却器、泵浦和其他组件,以提高系统效率并降低营运成本。製造商还利用巨量资料分析,透过预测性维护、负载平衡和需求预测来优化系统效能。
冷却技术:由于有丰富的废热源,采用吸收式冷却的趋势
吸收式冷却是一种利用废热生产冷冻水的环保且经济高效的技术。该系统采用热驱动过程,通常动力来源,以减少电力需求。吸收式冷却技术的主要优点是能够利用废热和再生能源来源,例如太阳能、地热和热电联产 (CHP) 工厂。电动式冷冻是最受欢迎的技术之一,因为它们相对高效且易于整合到现有的电力基础设施中。这些系统的工作原理是蒸气压缩冷冻循环,其中电动压缩机透过一系列膨胀阀和热交换器来冷却冷媒。自然冷却是一种利用环境温度进行冷却的节能区域冷却技术。这种环保方法可以透过空气自然冷却或水基自然冷却解决方案来实施。风冷系统使用较冷的外部空气直接或透过风冷式冷却器间接冷却建筑物。水冷系统使用来自天然水源(例如湖泊、河流或深井)的冷冻水作为冷冻水迴路中的散热器,而不是传统的机械冷水机。儘管其可行性取决于地理位置和气候条件,但自然冷却可显着降低能源消耗和营运成本。
组成部分:透过不断改进中央冷却器机组来提高效率
中央冷却器机组是区域冷却系统的关键组成部分,负责生产冷冻水,并发行到附近的建筑物以用于空间冷却。集中冷却过程可优化能源效率并降低运作噪音。消费者係统是指用于将冷冻水从配水网路分配到各建筑物的最终用户基础设施。这包括热交换器、泵浦和建筑级控制系统,它们根据设施的特定要求管理冷冻水的流量。配水网路由相互连接的管道组成,这些管道在中央冷却器机组和跨越区域供冷网路覆盖范围内的各个建筑物的消费者係统之间输送冷冻水。该网路的主要目的是维持高效率的配送路线,同时最大限度地减少运输过程中的热损失。对区域供冷系统三个组成部分的比较表明,每个部分的最新进展都有助于提高能源效率并优化整个系统的性能。中央冷却器机组正变得更加连网型,并与机器学习技术和物联网功能连接。消费性系统透过针对区域冷冻应用的各种客製化选项,提供更高的温度控制精度和节能效果。在我们的配电网路中,先进的隔热材料和洩漏检测系统可确保最大的可靠性,同时最大限度地减少运输过程中的热损失。
部署:区域供冷部署不仅限于改装,以优化营运成本
在区域供冷部署领域,新计画是指在新开发的区域和建筑物中安装区域冷却系统。人们对能源效率和永续的认识不断提高,大大增加了新计画对区域供冷解决方案的偏好。在新计画中实施区域供冷的主要好处是,它可以在施工阶段与各种建筑系统进行更精简且更具成本效益的整合。改装是指用更有效率的区域冷却解决方案升级或取代现有的传统冷却系统,从而节省能源、降低营运成本并提高环境永续性。改造的引入为市场相关人员提供了一个重要的机会,因为世界各地的许多建筑物仍然依赖过时或低效的 HVAC 系统,这些系统大大增加了温室气体的排放。基于维修需求的偏好主要源于优化与过时和低效系统相关的营运成本以及实现政府和组织设定的永续性目标的愿望。此外,维修还透过更好的温度控制和室内空气品质改善了整体用户体验。
应用:人们对气候变迁的认识不断增强,因此在住宅中得到了快速采用。
区域冷却系统对于购物中心、办公大楼、饭店和医疗机构等商业设施至关重要,这些设施需要高效、可靠的冷却解决方案。这些系统有助于降低营运成本、提高能源效率并促进环境永续实践。在製造工厂和资料中心等工业应用中,区域冷却对于将设备功能维持在最佳温度并确保製程稳定性至关重要。与传统空调设备相比,区域冷却可降低消费量,有助于减少碳排放并实现永续目标。区域供冷系统因其具有减少能源消费量、减少温室气体排放和提供舒适的生活环境等优点而越来越多地被住宅采用。区域供冷系统透过提高能源效率水准、同时降低营运成本并最大限度地减少对环境的影响,在商业、工业和住宅领域发挥重要作用。这些系统的越来越多的采用表明人们对气候变迁议题的认识不断增强以及政府对绿色措施的支持。
区域洞察
在美洲地区,北美是一个关键市场,在纽约、多伦多、波士顿、芝加哥和西雅图等城市建立了区域冷却基础设施。美国环保署 (EPA) 一直透过能源之星认证计画等政策奖励来提高能源效率。此外,研发投资带来了吸收式冷冻等创新,它利用天然气和工业製程的废热来提高运作效率。由于不断增长的城市人口寻求更好的能源管理解决方案,巴西和墨西哥等南美国家正在逐步探索区域冷却的潜力。在欧洲,瑞典、丹麦、德国和法国等国家正在建造利用太阳能和生物质等可再生能源的区域供冷网路。此外,相关人员之间的策略伙伴关係有助于加快计划实施,连接研究中心、公司和大学,并推动当地能源技术的创新。中国、印度、日本、新加坡和澳洲等国家对智慧城市计划的投资不断增加,为高效能能源管理解决方案铺平了道路,并支持跨市场部署区域冷却。
FPNV定位矩阵
FPNV定位矩阵对于评估区域冷却市场至关重要。我们检视与业务策略和产品满意度相关的关键指标,以对供应商进行全面评估。这种深入的分析使用户能够根据自己的要求做出明智的决策。根据评估,供应商被分为四个成功程度不同的像限:前沿(F)、探路者(P)、利基(N)和重要(V)。
市场占有率分析
市场占有率分析是一种综合工具,可以对区域供冷市场中供应商的现状进行深入而详细的研究。全面比较和分析供应商在整体收益、基本客群和其他关键指标方面的贡献,以便更好地了解公司的绩效及其在争夺市场占有率时面临的挑战。此外,该分析还提供了对该行业竞争特征的宝贵见解,包括在研究基准年观察到的累积、分散主导地位和合併特征等因素。详细程度的提高使供应商能够做出更明智的决策并制定有效的策略,从而在市场上获得竞争优势。
1. 市场渗透率:提供有关主要企业所服务的市场的全面资讯。
2. 市场开拓:我们深入研究利润丰厚的新兴市场,并分析其在成熟细分市场的渗透率。
3. 市场多元化:提供有关新产品发布、开拓地区、最新发展和投资的详细资讯。
4.竞争力评估与资讯:对主要企业的市场占有率、策略、产品、认证、监管状况、专利状况、製造能力等进行全面评估。
5. 产品开发与创新:提供对未来技术、研发活动和突破性产品开发的见解。
1.区域供冷市场的市场规模与预测为何?
2.区域供冷市场预测期间需要考虑投资的产品、细分市场、应用和领域有哪些?
3.区域供冷市场的技术趋势与法规结构是什么?
4.区域供冷市场主要厂商的市场占有率为何?
5.进入区域供冷市场的适当型态和策略手段是什么?
[188 Pages Report] The District Cooling Market size was estimated at USD 10.10 billion in 2023 and expected to reach USD 10.90 billion in 2024, at a CAGR 8.18% to reach USD 17.52 billion by 2030.
District cooling is an efficient, cost-effective, and environmentally friendly method of providing air conditioning to multiple buildings in a district or urban area. It involves the central production and distribution of chilled water through insulated pipes to various residential, commercial, and industrial end-users. District cooling systems offer numerous benefits, such as energy savings, reduced greenhouse gas emissions, and decreased operational and maintenance costs. The global district cooling market has been experiencing growth in recent years owing to several influencing factors, such as increasing requirement for energy-efficient cooling solutions owing to rising concerns about greenhouse gas emissions and climate change and supportive government policies for green technologies adoption. Collaborative ventures between governments and private players have driven investment in infrastructure development for district cooling systems. However, establishing a district cooling infrastructure requires significant capital outlay, deterring potential investors.
KEY MARKET STATISTICS | |
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Base Year [2023] | USD 10.10 billion |
Estimated Year [2024] | USD 10.90 billion |
Forecast Year [2030] | USD 17.52 billion |
CAGR (%) | 8.18% |
Additionally, complex regulatory frameworks in some countries may hamper the smooth implementation of district cooling projects. Organizations are focusing on innovation and research across developing advanced heat exchangers, chillers, pumps, and other components that improve system efficiency and reduce operational costs to overcome these challenges and capitalize on the immense growth potential of the district cooling market. Manufacturers also leverage big data analytics capabilities to optimize system performance through predictive maintenance, load balancing, and demand forecasting.
Cooling Technique: Inclination toward adoption of absorption cooling due to presence of abundant source of waste heat
Absorption cooling is an environmentally friendly and cost-effective district cooling technique that utilizes waste heat to produce chilled water. This system uses a heat-driven process, typically powered by natural gas or solar energy, reducing electricity demand. The primary advantage of absorption cooling technology is its ability to utilize waste heat or renewable energy sources such as solar thermal, geothermal, or combined heat and power (CHP) plants. Electric chillers are one of the most common district cooling technologies due to their relatively high efficiency and the ease of integrating them within existing electrical infrastructure. These systems work on the principle of vapor-compression refrigeration cycles, where an electric-powered compressor forces refrigerant through a series of expansion valves and heat exchangers to achieve cooling. Free cooling is an energy-efficient district cooling technique that capitalizes on ambient temperatures for cooling purposes. This environmentally friendly method can be implemented either through air-based free cooling or water-based free cooling solutions. Air-based systems use outdoor air with lower temperatures to cool buildings directly or indirectly by passing it through an air-cooled chiller. Water-based systems use cooler water from natural sources such as lakes, rivers, or deep wells as a heat sink for the return chilled water loop instead of conventional mechanical cooling equipment. Its feasibility depends on geographic location and climate conditions, and free cooling significantly reduces energy consumption and operational costs.
Component: Continuous improvements in central chiller plants to enhance efficiency
The central chiller plant is the main component of the district cooling system and is responsible for producing chilled water distributed to nearby buildings for space cooling purposes. Energy efficiency is optimized, and operational noise is reduced by consolidating the cooling process in a centralized location. The consumer system refers to the end-user infrastructure for distributing chilled water from the distribution network into individual buildings. This includes heat exchangers, pumps, and building-level control systems that manage the flow of chilled water based on the exact requirements of the facility. The distribution network consists of interconnected pipelines transporting chilled water between the central chiller plant and consumer systems across various buildings within the district cooling network's footprint. The primary purpose of this network is to maintain efficient delivery routes while minimizing heat loss during transportation. Comparing the three components of a district cooling system, it is evident that recent advancements in each segment have contributed to increased energy efficiency and optimized performance across the entire system. Central chiller plants have become more intelligent and connected through machine learning technologies and IoT capabilities. Consumer systems benefit from greater customization options tailored specifically for district cooling applications, resulting in improved temperature control accuracy and energy savings. Distribution networks offer advanced insulation materials and leak detection systems that minimize heat loss during transportation while ensuring maximum reliability.
Deployment: Increasing deployment of district cooling across retrofitting to optimize operational costs
In the deployment segment of district cooling, new projects refer to installing district cooling systems in newly developed areas or buildings. The preference for district cooling solutions in new projects has grown significantly due to increased awareness about energy efficiency and sustainable development. The primary advantage of implementing district cooling in new projects is that it allows for a more streamlined and cost-effective integration with various building systems during the construction phase. Retrofitting refers to upgrading or replacing existing conventional cooling systems with more efficient district cooling solutions to achieve energy savings, reduce operating costs, and improve environmental sustainability. Retrofitting deployments are creating significant opportunities for market players as numerous buildings worldwide continue to rely on outdated or inefficient HVAC systems, which contribute substantially to global greenhouse gas emissions. The need-based preference for retrofitting arises primarily from the desire to optimize operational costs associated with older and less efficient systems and achieve sustainability goals set by governments or organizations. Additionally, retrofitting improves overall user experience due to better temperature control and indoor air quality.
Application: Rapid residential adoption due to heightened awareness of climate change concerns
District cooling systems are crucial for commercial establishments such as shopping malls, office buildings, hotels, and healthcare facilities as they require efficient and reliable cooling solutions. These systems help reduce operational costs, enhance energy efficiency, and promote environmentally sustainable practices. In industrial applications, such as manufacturing plants or data centers, district cooling is essential in ensuring process stability by maintaining optimum temperatures for equipment functionality. It helps industries reduce their carbon footprint and achieve sustainability goals by lowering energy consumption levels compared to traditional air conditioning units. Residential buildings are increasingly adopting district cooling systems due to the benefits of reducing energy consumption, lowering greenhouse gas emissions, and providing a comfortable living environment. District cooling systems play a vital role across commercial, industrial, and residential sectors by enhancing energy efficiency levels while reducing operational costs and minimizing environmental impacts. The growing adoption of these systems demonstrates the increasing awareness of climate change concerns and governments' push toward green initiatives.
Regional Insights
In the Americas region, North America represents a significant market with a well-established district cooling infrastructure in cities such as New York, Toronto, Boston, Chicago, and Seattle. The U.S. Environmental Protection Agency (EPA) has consistently promoted energy efficiency through policy incentives such as Energy Star Certification Programs. Moreover, investments in research & development have led to innovative technologies such as absorption chillers that use natural gas or waste heat from industrial processes to operate more efficiently. South American countries such as Brazil and Mexico are gradually exploring district cooling potential due to growing urban populations demanding better energy management solutions. In Europe, countries such as Sweden, Denmark, Germany, and France have established district cooling networks leveraging renewable energy sources, including solar power or biomass. Additionally, strategic partnerships between stakeholders facilitate project implementation and help connect research centers, companies, and universities to drive innovation in district energy technologies. The APAC region is currently at a developing stage in adopting district cooling systems, with countries such as China, India, Japan, Singapore, and Australia increasingly investing in smart city projects that pave the way for efficient energy management solutions, which is supporting the deployment of district cooling across markets.
FPNV Positioning Matrix
The FPNV Positioning Matrix is pivotal in evaluating the District Cooling Market. It offers a comprehensive assessment of vendors, examining key metrics related to Business Strategy and Product Satisfaction. This in-depth analysis empowers users to make well-informed decisions aligned with their requirements. Based on the evaluation, the vendors are then categorized into four distinct quadrants representing varying levels of success: Forefront (F), Pathfinder (P), Niche (N), or Vital (V).
Market Share Analysis
The Market Share Analysis is a comprehensive tool that provides an insightful and in-depth examination of the current state of vendors in the District Cooling Market. By meticulously comparing and analyzing vendor contributions in terms of overall revenue, customer base, and other key metrics, we can offer companies a greater understanding of their performance and the challenges they face when competing for market share. Additionally, this analysis provides valuable insights into the competitive nature of the sector, including factors such as accumulation, fragmentation dominance, and amalgamation traits observed over the base year period studied. With this expanded level of detail, vendors can make more informed decisions and devise effective strategies to gain a competitive edge in the market.
Key Company Profiles
The report delves into recent significant developments in the District Cooling Market, highlighting leading vendors and their innovative profiles. These include ABB Ltd., ADC Energy Systems, Alfa Laval AB, ARANER, Artelia, Cetetherm, Danfoss A/S, DC Pro, DC PRO Engineering L.L.C., DESMI A/S, E.ON SE, Emirates Central Cooling Systems Corporation, Emirates District Cooling (Emicool) LLC, ENGIE Group, Equans SAS, Fortum Oyj, General Electric Company, Grundfos Holding A/S, Honeywell International Inc., ICAX Limited, isoplus Piping Systems Ltd., Johnson Controls International PLC, Keppel Corporation Limited, Kingspan Group PLC, National Central Cooling Company PJSC, Ramboll Group A/S, Shinryo Corporation, Siemens AG, Singapore Power Limited, SNC-Lavalin Group Inc., Stadtwerke Munchen GmbH, Stellar Energy, Trane Technologies PLC, Veolia Environnement SA, and Xylem Inc..
Market Segmentation & Coverage
1. Market Penetration: It presents comprehensive information on the market provided by key players.
2. Market Development: It delves deep into lucrative emerging markets and analyzes the penetration across mature market segments.
3. Market Diversification: It provides detailed information on new product launches, untapped geographic regions, recent developments, and investments.
4. Competitive Assessment & Intelligence: It conducts an exhaustive assessment of market shares, strategies, products, certifications, regulatory approvals, patent landscape, and manufacturing capabilities of the leading players.
5. Product Development & Innovation: It offers intelligent insights on future technologies, R&D activities, and breakthrough product developments.
1. What is the market size and forecast of the District Cooling Market?
2. Which products, segments, applications, and areas should one consider investing in over the forecast period in the District Cooling Market?
3. What are the technology trends and regulatory frameworks in the District Cooling Market?
4. What is the market share of the leading vendors in the District Cooling Market?
5. Which modes and strategic moves are suitable for entering the District Cooling Market?