电力系统模拟器市场规模、份额及成长分析（按组件、模组、最终用途和地区划分）－2025-2032年产业预测

预计到 2023 年，全球电力系统模拟器市场规模将达到 18 亿美元，到 2024 年将达到 19.2 亿美元，到 2032 年将达到 32.8 亿美元，预测期（2025-2032 年）的复合年增长率为 6.9%。

目前，全球电力系统模拟器市场正受到持续能源转型的驱动，其特点是风能和太阳能等可变再生能源来源併入电网所带来的复杂性。这些模拟器对于电力公司、电网营运商和研究人员至关重要，能够有效地对不断演进的电网进行建模、评估并确保其可靠性和稳定性。然而，市场成长也面临一些挑战，例如高阶模拟软体和硬体的高成本和复杂性。此外，能够有效率地利用这些先进工具的熟练电力系统工程师也十分短缺。最后，精确模拟现实世界电网的变化是一项耗时的挑战，因此需要持续努力来维护模拟模型的准确性。

全球电力系统模拟器市场成长要素

推动全球电力系统模拟器市场成长的主要因素是全球能源结构从传统石化燃料为可变的再生能源来源。这项转型正在改变电力系统的动态特性，并需要先进的模拟技术来有效应对这些能源来源固有的波动性。此类模拟在确保系统稳定性、应对间歇性挑战以及优化不同能源资源的整合方面发挥着至关重要的作用。在不断变化的能源格局中，对先进模拟工具的需求日益迫切，以确保电力系统的可靠性和高效性，从而支持可再生能源的广泛应用。

全球电力系统模拟器市场限制因素

全球电力系统模拟器市场面临的主要限制因素是先进模拟软体和即时硬体（尤其是用于模型测试的硬体在环 (HIL) 系统）的高昂成本。此外，这些工具的复杂性需要专业技术人员，而这类人员数量有限。这给考虑实施或升级其模拟能力的组织带来了挑战，因为所需的成本和专业知识可能相当可观。因此，这些因素可能会阻碍电力系统模拟解决方案在各个领域的成长和应用，从而限制其广泛普及和有效性。

全球电力系统模拟器市场趋势

全球电力系统模拟器市场呈现显着成长趋势，这主要得益于硬体在环 (HIL) 模拟技术的日益普及。这种创新方法能够将物理控制设备（例如风力发电机控制设备）整合到即时模拟的电力系统环境中。随着能源系统日益复杂，对有效性能评估的需求不断增长，HIL 模拟提供了一种进行真实测试的手段，从而提高可靠性和效率。此外，对再生能源来源和智慧电网技术的投资不断增加，也进一步推动了这一趋势，为电力系统模拟调查方法的发展创造了良好的环境。

目录

介绍

• 调查目标
• 调查范围
• 定义

调查方法

• 资讯收集
• 二手资料和一手资料方法
• 市场规模预测
• 市场假设与限制

执行摘要

• 全球市场展望
• 供需趋势分析
• 细分市场机会分析

市场动态与展望

• 市场概览
• 市场规模
• 市场动态
  • 驱动因素和机会
  • 限制与挑战
• 波特分析

关键市场考察

• 关键成功因素
• 竞争程度
• 关键投资机会
• 市场生态系统
• 市场吸引力指数（2024）
• PESTEL 分析
• 总体经济指标
• 价值链分析
• 定价分析

电力系统模拟器市场规模（按组件划分）及复合年增长率（2025-2032 年）

• 市场概览
• 硬体
• 软体
• 服务

电力系统模拟器市场规模（依模组划分）及复合年增长率（2025-2032 年）

• 市场概览
• 负荷流量
• 短路测试
• 谐波
• 瞬态现象
• 其他的

电力系统模拟器市场规模（依最终用途划分）及复合年增长率（2025-2032 年）

• 市场概览
• 电力
• 工业的
• 其他的

电力系统模拟器市场规模及复合年增长率（2025-2032）

• 北美洲
  • 美国
  • 加拿大
• 欧洲
  • 德国
  • 西班牙
  • 法国
  • 英国
  • 义大利
  • 其他欧洲地区
• 亚太地区
  • 中国
  • 印度
  • 日本
  • 韩国
  • 亚太其他地区
• 拉丁美洲
  • 巴西
  • 其他拉丁美洲地区
• 中东和非洲
  • 海湾合作委员会国家
  • 南非
  • 其他中东和非洲地区

竞争资讯

• 前五大公司对比
• 主要企业的市场定位（2024 年）
• 主要市场参与者所采取的策略
• 近期市场趋势
• 公司市占率分析（2024 年）
• 主要企业公司简介
  • 公司详情
  • 产品系列分析
  • 依业务板块进行公司股票分析
  • 2022-2024年营收年比比较

主要企业简介

• Siemens AG（Germany）
• General Electric Company（United States）
• ABB Ltd.（Switzerland）
• Schneider Electric SE（France）
• DIgSILENT GmbH（Germany）
• OPAL-RT TECHNOLOGIES, Inc.（Canada）
• RTDS Technologies Inc.（Canada）
• The MathWorks, Inc.（United States）
• PowerWorld Corporation（United States）
• CYME International T&D（Canada）
• Eaton Corporation plc（Ireland）
• DNV GL（Norway）
• Fuji Electric Co., Ltd.（Japan）
• Neplan AG（Switzerland）
• Plexim GmbH（Switzerland）
• AspenTech（United States）
• IncSys, Inc.（United States）
• Manitoba Hydro International Ltd.（Canada）
• Electrocon International Inc.（United States）
• PSI AG（Germany）

结论与建议

Global Power System Simulator Market size was valued at USD 1.8 billion in 2023 and is poised to grow from USD 1.92 billion in 2024 to USD 3.28 billion by 2032, growing at a CAGR of 6.9% during the forecast period (2025-2032).

The global power system simulator market is currently driven by the ongoing energy transition, characterized by the incorporation of variable renewable energy sources such as wind and solar into the power grid, which introduces significant complexities. These simulators are essential for utilities, grid operators, and researchers to effectively model, assess, and ensure the reliability and stability of the evolving grid. However, the market faces challenges that could impede growth, including the high costs and intricacies associated with advanced simulation software and hardware. Additionally, there is a scarcity of skilled power system engineers capable of utilizing these sophisticated tools efficiently. Lastly, accurately modeling real-world grid changes poses a time-consuming challenge, highlighting the need for ongoing effort to maintain simulation model precision.

Top-down and bottom-up approaches were used to estimate and validate the size of the Global Power System Simulator market and to estimate the size of various other dependent submarkets. The research methodology used to estimate the market size includes the following details: The key players in the market were identified through secondary research, and their market shares in the respective regions were determined through primary and secondary research. This entire procedure includes the study of the annual and financial reports of the top market players and extensive interviews for key insights from industry leaders such as CEOs, VPs, directors, and marketing executives. All percentage shares split, and breakdowns were determined using secondary sources and verified through Primary sources. All possible parameters that affect the markets covered in this research study have been accounted for, viewed in extensive detail, verified through primary research, and analyzed to get the final quantitative and qualitative data.

Global Power System Simulator Market Segments Analysis

Global Power System Simulator Market is segmented by Component, Module, End Use and region. Based on Component, the market is segmented into Hardware, Software and Services. Based on Module, the market is segmented into Load Flow, Short Circuit, Harmonic, Transient and Others. Based on End Use, the market is segmented into Power, Industrial and Others. Based on region, the market is segmented into North America, Europe, Asia Pacific, Latin America and Middle East & Africa.

Driver of the Global Power System Simulator Market

The primary catalyst for growth in the Global Power System Simulator market is the worldwide shift from conventional fossil fuels toward variable renewable energy sources. This transition transforms grid dynamics, necessitating advanced simulation technologies to effectively manage the fluctuations inherent in these energy sources. Such simulations play a crucial role in ensuring grid stability, addressing the challenges posed by intermittency, and optimizing the integration of diverse energy resources. As the energy landscape evolves, the demand for sophisticated simulation tools becomes increasingly vital for securing a reliable and efficient power grid capable of supporting renewable energy proliferation.

Restraints in the Global Power System Simulator Market

A major limitation in the Global Power System Simulator market is the high expense associated with advanced simulation software and real-time hardware, specifically hardware-in-the-loop (HIL) systems used for model testing. Furthermore, the complexity of these tools necessitates a workforce with specialized skills, which are in limited supply. This creates challenges for organizations looking to adopt or upgrade their simulation capabilities, as the costs and expertise required can be substantial. Consequently, these factors may hinder the growth and accessibility of power system simulation solutions in various sectors, limiting their widespread utilization and effectiveness.

Market Trends of the Global Power System Simulator Market

The global power system simulator market is experiencing a significant upward trend, primarily driven by the increasing adoption of Hardware-in-the-Loop (HIL) simulation technologies. This innovative approach allows for the integration of physical control devices, such as wind turbine controllers, into real-time simulated power grid environments. As energy systems become more complex and the demand for effective performance assessment rises, HIL simulation provides an avenue for conducting realistic tests that enhance reliability and efficiency. This trend is further supported by growing investments in renewable energy sources and smart grid technologies, fostering a robust landscape for advancements in power system simulation methodologies.

Table of Contents

Introduction

• Objectives of the Study
• Scope of the Report
• Definitions

Research Methodology

• Information Procurement
• Secondary & Primary Data Methods
• Market Size Estimation
• Market Assumptions & Limitations

Executive Summary

• Global Market Outlook
• Supply & Demand Trend Analysis
• Segmental Opportunity Analysis

Market Dynamics & Outlook

• Market Overview
• Market Size
• Market Dynamics
  • Drivers & Opportunities
  • Restraints & Challenges
• Porters Analysis
  • Competitive rivalry
  • Threat of substitute
  • Bargaining power of buyers
  • Threat of new entrants
  • Bargaining power of suppliers

Key Market Insights

• Key Success Factors
• Degree of Competition
• Top Investment Pockets
• Market Ecosystem
• Market Attractiveness Index, 2024
• PESTEL Analysis
• Macro-Economic Indicators
• Value Chain Analysis
• Pricing Analysis

Global Power System Simulator Market Size by Component & CAGR (2025-2032)

• Market Overview
• Hardware
• Software
• Services

Global Power System Simulator Market Size by Module & CAGR (2025-2032)

• Market Overview
• Load Flow
• Short Circuit
• Harmonic
• Transient
• Others

Global Power System Simulator Market Size by End Use & CAGR (2025-2032)

• Market Overview
• Power
• Industrial
• Others

Global Power System Simulator Market Size & CAGR (2025-2032)

• North America (Component, Module, End Use)
  • US
  • Canada
• Europe (Component, Module, End Use)
  • Germany
  • Spain
  • France
  • UK
  • Italy
  • Rest of Europe
• Asia Pacific (Component, Module, End Use)
  • China
  • India
  • Japan
  • South Korea
  • Rest of Asia-Pacific
• Latin America (Component, Module, End Use)
  • Brazil
  • Rest of Latin America
• Middle East & Africa (Component, Module, End Use)
  • GCC Countries
  • South Africa
  • Rest of Middle East & Africa

Competitive Intelligence

• Top 5 Player Comparison
• Market Positioning of Key Players, 2024
• Strategies Adopted by Key Market Players
• Recent Developments in the Market
• Company Market Share Analysis, 2024
• Company Profiles of All Key Players
  • Company Details
  • Product Portfolio Analysis
  • Company's Segmental Share Analysis
  • Revenue Y-O-Y Comparison (2022-2024)

Key Company Profiles

• Siemens AG (Germany)
  • Company Overview
  • Business Segment Overview
  • Financial Updates
  • Key Developments
• General Electric Company (United States)
  • Company Overview
  • Business Segment Overview
  • Financial Updates
  • Key Developments
• ABB Ltd. (Switzerland)
  • Company Overview
  • Business Segment Overview
  • Financial Updates
  • Key Developments
• Schneider Electric SE (France)
  • Company Overview
  • Business Segment Overview
  • Financial Updates
  • Key Developments
• DIgSILENT GmbH (Germany)
  • Company Overview
  • Business Segment Overview
  • Financial Updates
  • Key Developments
• OPAL-RT TECHNOLOGIES, Inc. (Canada)
  • Company Overview
  • Business Segment Overview
  • Financial Updates
  • Key Developments
• RTDS Technologies Inc. (Canada)
  • Company Overview
  • Business Segment Overview
  • Financial Updates
  • Key Developments
• The MathWorks, Inc. (United States)
  • Company Overview
  • Business Segment Overview
  • Financial Updates
  • Key Developments
• PowerWorld Corporation (United States)
  • Company Overview
  • Business Segment Overview
  • Financial Updates
  • Key Developments
• CYME International T&D (Canada)
  • Company Overview
  • Business Segment Overview
  • Financial Updates
  • Key Developments
• Eaton Corporation plc (Ireland)
  • Company Overview
  • Business Segment Overview
  • Financial Updates
  • Key Developments
• DNV GL (Norway)
  • Company Overview
  • Business Segment Overview
  • Financial Updates
  • Key Developments
• Fuji Electric Co., Ltd. (Japan)
  • Company Overview
  • Business Segment Overview
  • Financial Updates
  • Key Developments
• Neplan AG (Switzerland)
  • Company Overview
  • Business Segment Overview
  • Financial Updates
  • Key Developments
• Plexim GmbH (Switzerland)
  • Company Overview
  • Business Segment Overview
  • Financial Updates
  • Key Developments
• AspenTech (United States)
  • Company Overview
  • Business Segment Overview
  • Financial Updates
  • Key Developments
• IncSys, Inc. (United States)
  • Company Overview
  • Business Segment Overview
  • Financial Updates
  • Key Developments
• Manitoba Hydro International Ltd. (Canada)
  • Company Overview
  • Business Segment Overview
  • Financial Updates
  • Key Developments
• Electrocon International Inc. (United States)
  • Company Overview
  • Business Segment Overview
  • Financial Updates
  • Key Developments
• PSI AG (Germany)
  • Company Overview
  • Business Segment Overview
  • Financial Updates
  • Key Developments

Conclusion & Recommendations