电力系统模拟器市场:现状分析与预测(2024年～2032年)

电力系统模拟器市场预计在预测期内（2024-2032年）将出现约7.1%的显着成长率。值得注意的是，随着新形成的电力系统变得更加复杂和动态，电力系统模拟器的使用正在迅速扩大。随着越来越多的电力公司转向风能和太阳能等可变的再生能源，需要模拟器来管理电网稳定性。随着高效新技术不断推动电网发展，复杂多样的通讯和控制功能正在推动有效模拟模型的发展。例如，2020年8月，电力系统模拟器F6150sv成功通过了基本到最复杂的测试。 F6150sv 可以处理从基本到复杂的所有测试，并且具有市场上所有测试装置中最高的输出电流。基于 IEC 61850 的系统应用于流程和站汇流排级别，具有采样值和 GOOSE 讯息。对网路攻击和基础设施陈旧地区电网现代化的担忧也促使工具支出增加。旨在增加再生能源使用和提高电网可靠性的政府政策和政策也在推动电力系统模拟器的使用，这对于规划未来的能源需求非常重要。

依模组，市场分为潮流、谐波、短路、设备调整选择、弧闪等。 2023 年的市场将由潮流部分主导。主要驱动因素之一是由于全球电力消耗的增加，对可靠和高效电力供应的需求不断增加。这种需求的激增需要先进的配电规划和管理工具，并正在推动潮流系统的采用。此外，再生能源併入电网带来了潮流管理的复杂性，进一步增加了对先进模拟工具的需求。提供更准确和即时分析的模拟软体技术进步也在市场成长中发挥重要作用。此外，对智慧电网技术和公用事业数位化的日益重视也推动了先进潮流系统的采用。

根据组件，市场分为硬体、软体和服务。软体领域正以最高的复合年增长率成长，并占据了相当大的市场占有率。一个关键驱动因素是现代电网日益复杂，这需要先进的软体工具来进行有效的管理和最佳化。随着再生能源日益一体化，对能够应对这些资源的可变性和不可预测性的软体的需求不断增长。此外，人工智慧和机器学习等技术进步正在被纳入模拟软体中，以增强其功能并使其对公用事业公司具有吸引力。旨在实现电网现代化和实施智慧电网技术的政府法规和措施进一步推动了对复杂软体解决方案的需求。

市场依最终用户细分为电力、工业等。 2023年，由于已开发地区和新兴市场对可靠不间断电源的需求不断增加，电力领域占据市场主导地位。因此，需要先进的模拟工具来进行有效的电力系统规划和运作。将风能和太阳能等再生能源併入电网会增加复杂性和可变性，需要先进的模拟器来确保稳定性和效率。此外，监管压力和政府减少碳排放和促进永续能源利用的措施正迫使公用事业公司采用更先进的模拟技术。模拟软体的技术进步（例如即时数据分析和预测功能）提高了电力系统模拟的准确性和可靠性，使其对公用事业至关重要。

为了加深对电力系统模拟器市场介绍的了解，它根据其在印度、澳洲、世界其他地区（亚太地区）和世界其他地区的全球分布对市场进行了分析。北美在电力系统模拟器市场中占据重要占有率，预计在预测期内将保持稳定的成长速度。在技??术、监管和市场驱动因素的推动下，北美电力系统模拟器市场正在经历显着成长。主要讯息是，风能和太阳能等再生能源越来越多地融入电网，需要先进的模拟工具来管理可变性并确保电网稳定性。旨在减少碳排放和促进永续能源实践的监管要求进一步推动了电力系统模拟器的采用。此外，该地区正在增加对模拟技术的投资，重点关注老化电力基础设施的现代化以及提高电网抵御极端天气事件和网路威胁的能力。即时数据分析、人工智慧和机器学习等技术进步正在增强电力系统模拟器的功能，使其成为高效电网管理的关键。 2020 年，美国能源部宣布对先进电网建模和模拟工具进行重大投资，作为其电网现代化计画的一部分。该投资旨在支持尖端技术的开发和部署，以提高国家电网的可靠性、弹性和安全性。诸如此类的举措凸显了电力系统模拟器在实现能源目标和应对电力产业新课题、推动北美市场成长的关键作用。

参与市场的主要公司包括ABB、施耐德电机、伊顿、西门子、通用电气公司、Operation Technology, Inc.、Aspen Technology Inc.、The MathWorks, Inc.、OPAL-RT TECHNOLOGIES，范例包括PowerWorld Corporation 。

目录

第1章 市场简介

• 市场定义
• 主要目的
• 相关利益者
• 限制事项

第2章 调查手法或前提条件

• 调查流程
• 调查手法
• 受访者简介

第3章 摘要整理

• 产业摘要
• 各市场区隔预测
  • 市场成长的强度
• 地区展望

第4章 市场动态

• 促进因素
• 机会
• 阻碍因素
• 趋势
• PESTEL分析
• 需求面分析
• 供给面分析
  • 合併和收购
  • 投资情势
  • 产业洞察：主要新创公司及其独特策略

第5章 价格分析

• 各地区价格分析
• 价格的影响因素

第6章 全球电力系统模拟器市场收益，2022-2032年

第7章 各模组的市场分析

• 负担流量
• 谐波
• 短路
• 设备调整的选择
• 电弧闪光
• 其他

第8章 各零件的市场分析

• 硬体设备
• 软体
• 服务

第9章 各终端用户的市场分析

• 电力
• 工业
• 其他

第10章 各地区的市场分析

• 北美
  • 美国
  • 加拿大
  • 其他北美地区
• 欧洲
  • 德国
  • 英国
  • 法国
  • 义大利
  • 西班牙
  • 其他欧洲地区
• 亚太地区
  • 中国
  • 日本
  • 印度
  • 澳洲
  • 其他亚太地区
• 全球其他地区

第11章 价值链分析

• 限制分析
• 市场参与企业一览

第12章 竞争情形

• 竞争仪表板
• 竞争市场定位分析
• 波特的五力分析

第13章 企业简介

• ABB
• Schneider Electric
• Eaton
• Siemens
• General Electric Company
• Operation Technology, Inc
• Aspen Technology Inc
• The MathWorks, Inc
• OPAL-RT TECHNOLOGIES
• PowerWorld Corporation

第14章 缩写与前提条件

第15章 附录

Power system simulation is a mature application for modeling, analyzing, and optimizing the performance of electrical power systems. Such simulators are critical to guaranteeing power grids' performance, reliability, and robustness as they continuously add more renewable energy resources and transform them to become much brighter. They allow utilities and grid operators to model different scenarios, predict potential problems that may arise in specific conditions, and help build efficient grid management and optimization methods. For instance: In 2023 the New York Independent System Operator (NYISO) used power system simulators to integrate significant growth in renewable energy capacity while maintaining grid stability and reliability. This instance further illustrates the importance of power system simulators and their role in enabling a smoother shift toward sustainable, stable energy infrastructure.

The power system simulator market is expected to grow at a significant rate of around 7.1% during the forecast period (2024-2032). As newly shaped power systems are becoming more complex and dynamic, it is noteworthy that the use of power system simulators is expanding rapidly. More utility systems are turning to variable renewable energy sources such as wind and solar power and hence need simulators to manage the grid's stability. As new and efficient technologies continue to develop the grid, complex and diverse communication and control functions propel the development of effective simulation models. For example, in August 2020, the F6150sv, which is a power system simulator, succeeded in performing the basic tests to the most complex ones. The one has the highest output current of any test set on the market- all integrated within one unit. It applies IEC 61850 - based systems at the process-bus and station-bus levels with sampled values and GOOSE messages. Fears of cyber-attacks and the modernization of the grid in regions with old infrastructure have also led to higher spending on the tools. This, coupled with other government policies and regulations that aim at increasing the use of renewable energy and the grid's reliability, also supplements the use of power system simulators, which are crucial in planning future energy needs.

Based on the module, the market is segmented into load flow, harmonics, short circuit, device coordination selectivity, arc flash, and others. The load flow segment dominated the market in 2023. One of the primary drivers is the increasing demand for reliable and efficient power supply due to rising electricity consumption globally. This surge in demand necessitates advanced tools for planning and managing power distribution, leading to a higher adoption of load flow systems. Additionally, integrating renewable energy sources into the power grid creates complexities in power flow management, further boosting the need for sophisticated simulation tools. Technological advancements in simulation software, providing more accurate and real-time analysis, also play a significant role in market growth. Furthermore, the growing emphasis on smart grid technologies and the digitalization of power utilities encourage the adoption of advanced load flow systems.

Based on the components, the market is segmented into hardware, software, and services. The software segment is growing with the highest CAGR and holds a considerable share of the market. A primary driver is the escalating complexity of modern power grids, which requires advanced software tools for efficient management and optimization. As the integration of renewable energy sources increases, there is a growing need for software that can handle the variability and unpredictability of these resources. Additionally, advancements in technology, such as AI and machine learning, are being incorporated into simulation software, enhancing their capabilities, and making them more attractive to power utilities. Government regulations and initiatives aimed at grid modernization and implementing smart grid technologies further propel the demand for sophisticated software solutions.

Based on the end-users, the market is segmented into power, industry, and others. The power segment dominated the market in 2023 owing to the rising demand for reliable and uninterrupted power supply in developed and developing regions. This necessitates advanced simulation tools for effective power system planning and operation. Integrating renewable energy sources, such as wind and solar, into the power grid adds complexity and variability, requiring sophisticated simulators to ensure stability and efficiency. Additionally, regulatory pressures and government initiatives to reduce carbon emissions and promote sustainable energy practices are compelling power utilities to adopt more advanced simulation technologies. Technological advancements in simulation software, including real-time data analysis and predictive capabilities, enhance the accuracy and reliability of power system simulations, making them indispensable for utilities.

For a better understanding of the market adoption of power system simulator, the market is analyzed based on its worldwide presence in countries such as North America (U.S., Canada, and the Rest of North America), Europe (Germany, France, U.K., Spain, Italy, Rest of Europe), Asia-Pacific (China, Japan, India, Australia, and, Rest of Asia-Pacific), Rest of World. North America holds a significant share of the power system simulator market and is anticipated to maintain a steady growth rate over the forecast period. The power system simulator market in North America is experiencing significant growth due to technological, regulatory, and market-driven factors. The increasing integration of renewable energy sources, such as wind and solar, into the power grid is a primary driver, necessitating advanced simulation tools to manage variability and ensure grid stability. Regulatory mandates aimed at reducing carbon emissions and promoting sustainable energy practices further propel the adoption of power system simulators. Additionally, the region's focus on modernizing aging power infrastructure and enhancing grid resilience against extreme weather events and cyber threats has increased investment in simulation technologies. Technological advancements, including real-time data analytics, AI, and machine learning, enhance the capabilities of power system simulators, making them indispensable for efficient grid management. An instance highlighting this growth occurred in 2020 when the U.S. Department of Energy announced a significant investment in advanced grid modeling and simulation tools as part of its Grid Modernization Initiative. This investment aimed to support developing and deploying cutting-edge technologies to improve the nation's power grid's reliability, resilience, and security. Such initiatives underscore the critical role of power system simulators in achieving energy goals and addressing emerging challenges in the power sector, thereby driving the market's growth in North America.

Some of the major players operating in the market include ABB, Schneider Electric, Eaton, Siemens, General Electric Company, Operation Technology, Inc., Aspen Technology Inc, The MathWorks, Inc, OPAL-RT TECHNOLOGIES, PowerWorld Corporation.

TABLE OF CONTENTS

1.MARKET INTRODUCTION

• 1.1. Market Definitions
• 1.2. Main Objective
• 1.3. Stakeholders
• 1.4. Limitation

2.RESEARCH METHODOLOGY OR ASSUMPTION

• 2.1. Research Process of the Global Power System Simulator Market
• 2.2. Research Methodology of the Global Power System Simulator Market
• 2.3. Respondent Profile

3.EXECUTIVE SUMMARY

• 3.1. Industry Synopsis
• 3.2. Segmental Outlook
  • 3.2.1. Market Growth Intensity
• 3.3. Regional Outlook

4.MARKET DYNAMICS

• 4.1. Drivers
• 4.2. Opportunity
• 4.3. Restraints
• 4.4. Trends
• 4.5. PESTEL Analysis
• 4.6. Demand Side Analysis
• 4.7. Supply Side Analysis
  • 4.7.1. Merger & Acquisition
  • 4.7.2. Investment Scenario
  • 4.7.3. Industry Insights: Leading Startups and Their Unique Strategies

5.PRICING ANALYSIS

• 5.1. Regional Pricing Analysis
• 5.2. Price Influencing Factors

6.GLOBAL POWER SYSTEM SIMULATOR MARKET REVENUE (USD BN), 2022-2032F

7.MARKET INSIGHTS BY MODULE

• 7.1. Load Flow
• 7.2. Harmonics
• 7.3. Short Circuit
• 7.4. Device Coordination Selectivity
• 7.5. Arc Flash
• 7.6. Others

8.MARKET INSIGHTS BY COMPONENT

• 8.1. Hardware
• 8.2. Software
• 8.3. Services

9.MARKET INSIGHTS BY END-USERS

• 9.1. Power
• 9.2. Industrial
• 9.3. Others

10.MARKET INSIGHTS BY REGION

• 10.1. North America
  • 10.1.1. U.S.
  • 10.1.2. Canada
  • 10.1.3. Rest of North America
• 10.2. Europe
  • 10.2.1. Germany
  • 10.2.2. U.K.
  • 10.2.3. France
  • 10.2.4. Italy
  • 10.2.5. Spain
  • 10.2.6. Rest of Europe
• 10.3. Asia-Pacific
  • 10.3.1. China
  • 10.3.2. Japan
  • 10.3.3. India
  • 10.3.4. Australia
  • 10.3.5. Rest of Asia-Pacific
• 10.4. Rest of World

11.VALUE CHAIN ANALYSIS

• 11.1. Marginal Analysis
• 11.2. List of Market Participants

12.COMPETITIVE LANDSCAPE

• 12.1. Competition Dashboard
• 12.2. Competitor Market Positioning Analysis
• 12.3. Porter Five Forces Analysis

13.COMPANY PROFILED

• 13.1. ABB
  • 13.1.1. Company Overview
  • 13.1.2. Key Financials
  • 13.1.3. SWOT Analysis
  • 13.1.4. Product Portfolio
  • 13.1.5. Recent Developments
• 13.2. Schneider Electric
• 13.3. Eaton
• 13.4. Siemens
• 13.5. General Electric Company
• 13.6. Operation Technology, Inc
• 13.7. Aspen Technology Inc
• 13.8. The MathWorks, Inc
• 13.9. OPAL-RT TECHNOLOGIES
• 13.10. PowerWorld Corporation

14.ACRONYMS & ASSUMPTION

15.ANNEXURE