數位孿生技術的進步改變了能源行業

Advancements in Digital Twin Technology Transforming the Energy Sector

出版日期: 2023年06月27日 | 出版商:

Frost & Sullivan | 英文 47 Pages | 商品交期: 最快1-2個工作天內

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簡介目錄

透過單一平台進行精確建模和流程整合，以增強發電、輸電和配電分析

為了實現全球排放目標，到2030年，再生能源需要佔能源消耗的至少 42%，到2050年達到 60%，高於2021年的 17%。全球電力行業向再生能源發電轉型，以遏制溫室氣體排放，但再生能源是間歇性的。因此，在發電結構中所佔比例的增加將影響傳統發電廠的營運以及輸配電網。再生能源比例的不斷增加減少對傳統蒸氣渦輪電廠和燃煤電廠的依賴和運轉率。這一趨勢給傳統發電廠帶來了一些挑戰。從根本上來說，再生能源的間歇性會破壞電網的穩定性。數位孿生技術透過提高傳統發電的靈活性、提高再生能源發電的可預測性以及提高電網彈性來應對這些挑戰。

這項研究涵蓋了數位孿生系統的基礎知識和運行原理，並對發電和輸配電系統中的數位孿生應用進行了深入分析。還包括能源領域數位孿生技術的關鍵成長機會、成長促進因素和抑制因素、關鍵創新和研發活動。

還包括多個案例研究，展示了數位孿生給能源行業帶來的好處。它還探討了參與開發能源應用創新數位孿生解決方案的主要相關人員，分析了全球專利格局，重點關注關鍵專利持有人/申請人和關鍵研究領域。

數位孿生在能源領域的應用介紹
數位孿生技術在常規發電中的必要性
常規電廠數位孿生運行機制
燃煤電廠案例研究中的數位孿生
數位孿生使再生能源發電廠更適應運行條件
透過案例研究數位孿生進行太陽能發電廠績效審核
輸配電數位孿生
資產數位孿生可提高輸配電設備的效率和使用壽命
電網數位孿生可在不影響彈性的情況下實現最佳電網擴展
案例研究數位孿生增強電網經濟性和彈性

特色公司

Siemens Energy（美國）
Envelio（德國）
能源領域數位孿生技術知名公司

能源領域數位孿生技術知識產權分析

中國壟斷數位孿生技術專利

成長機會宇宙

成長機會1：在整個價值鏈中部署整合數位孿生
成長機會2：數位孿生即服務商業模式
成長機會3：OEM與公用事業公司之間的合作

下一步

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簡介目錄

Product Code: DA98

Precise Modeling and Process Integration from a Single Platform to Enhance Analytics in Power Generation, Transmission, and Distribution

To meet global emission reduction targets, renewable energy must account for at least 42% of energy consumption by 2030 and 60% by 2050, compared to 17% in 2021. Although the global power generation sector is moving toward renewable power to curb greenhouse gas emissions, renewable energy is intermittent. Therefore, its increased share in the power generation mix affects both conventional power plant operations and the transmission and distribution grid. The increased share of renewables has lowered dependence and capacity utilization of conventional steam turbine and coal-fired power generation plants. This trend poses several challenges to conventional power plants. Essentially, the intermittency of renewables can compromise grid stability. Digital twin technology addresses these challenges by enhancing the flexibility of conventional power generation, improving the predictability of renewable power generation, and improving grid resiliency.

This study covers the fundamentals and working principle of digital twin systems, offering detailed analysis of digital twin applications across power generation and transmission and distribution systems. It includes key growth opportunities, growth drivers and restraints, major innovations, and research and development activities in digital twin technology for the energy sector.

The study also includes multiple case studies that illustrate the advantages digital twins offer the energy sector. It discusses key stakeholders involved in the development of innovative digital twin solutions for energy applications, including an analysis of the global patent landscape that highlights key patent owners/applicants and the major areas of research.

Strategic Imperatives

Why Is It Increasingly Difficult to Grow?The Strategic Imperative 8™: Factors Creating Pressure on Growth
The Strategic Imperative 8™
The Impact of the Top 3 Strategic Imperatives on the Digital Twin Technology Advancements in the Energy Sector
Growth Opportunities Fuel the Growth Pipeline Engine™
Research Methodology

Growth Opportunity Analysis

Scope of Analysis
Segmentation
Growth Drivers
Growth Restraints

Introduction to Digital Twin

Digital Twin Explained
Working Principle of Digital Twin
Types of Digital Twins by Application

Digital Twin Applications in the Energy Sector

Introduction to Digital Twin Applicability in the Energy Sector
Need for Digital Twin Technology in Conventional Power Generation
Working Mechanism of Digital Twin for Conventional Power Plants
Case Study: Digital Twin for Coal-fired Power Plant
Digital Twin Enhances the Renewable Power Plant's Adaptability to Operating Conditions
Case Study: Digital Twin to Audit Solar Power Plant Performance
Digital Twin for Power Transmission and Distribution
Asset Digital Twin Enhances Efficiency and Longevity of Power Transmission and Distribution Equipment
Grid Digital Twin Enables Optimal Grid Expansion without Compromising Resiliency
Case Study: Digital Twin Enhances Grid Economics and Resiliency