100 từ vựng và cụm từ vựng tiếng Anh về ngành nghề Quản lý dự án xây dựng công trình cấp điện

“100 từ vựng và cụm từ vựng tiếng Anh chuyên ngành Quản lý dự án xây dựng công trình cấp điện” là tài liệu hữu ích cho các kỹ sư và nhà quản lý dự án. Tài liệu này giúp bạn nắm vững các thuật ngữ quan trọng trong quá trình lập kế hoạch, triển khai, và giám sát dự án xây dựng hạ tầng cấp điện, từ giai đoạn khởi công đến nghiệm thu dự án.

Từ vựng nghề Quản lý dự án xây dựng công trình cấp điện

Power Plant Construction – Xây dựng nhà máy điện
Electrical Infrastructure – Hạ tầng điện
Transmission Line – Đường dây truyền tải
Substation Design – Thiết kế trạm biến áp
Energy Management – Quản lý năng lượng
Load Analysis – Phân tích tải
Power Distribution – Phân phối điện
Grid Stability – Ổn định lưới điện
Circuit Breaker – Máy cắt mạch
Transformer Installation – Lắp đặt máy biến áp
Electrical Safety – An toàn điện
Power Generation – Phát điện
Capacity Planning – Lập kế hoạch công suất
System Integration – Tích hợp hệ thống
Voltage Regulation – Điều chỉnh điện áp
Energy Efficiency – Hiệu quả năng lượng
Project Budgeting – Dự toán ngân sách dự án
Load Forecasting – Dự đoán tải
Electrical Equipment – Thiết bị điện
Power Outage Management – Quản lý sự cố mất điện
Grid Expansion – Mở rộng lưới điện
Substation Upgrade – Nâng cấp trạm biến áp
Installation Procedures – Quy trình lắp đặt
Maintenance Scheduling – Lịch trình bảo trì
Electrical Code Compliance – Tuân thủ mã điện
Power Quality Management – Quản lý chất lượng điện
Energy Storage Solutions – Giải pháp lưu trữ năng lượng
Project Risk Management – Quản lý rủi ro dự án
Feasibility Study – Nghiên cứu khả thi
Power System Design – Thiết kế hệ thống điện
Load Shedding – Cắt giảm tải
Transformer Maintenance – Bảo trì máy biến áp
Electrical System Testing – Kiểm tra hệ thống điện
Power Grid Monitoring – Giám sát lưới điện
Energy Audit – Kiểm toán năng lượng
Electrical Distribution Network – Mạng lưới phân phối điện
Technical Specification – Đặc điểm kỹ thuật
Energy Efficiency Audits – Kiểm toán hiệu quả năng lượng
Power System Analysis – Phân tích hệ thống điện
Load Balancing – Cân bằng tải
Project Management Software – Phần mềm quản lý dự án
Power Line Inspection – Kiểm tra đường dây điện
Electrical Wiring – Đi dây điện
Energy Consumption Analysis – Phân tích tiêu thụ năng lượng
System Upgrades – Nâng cấp hệ thống
Technical Documentation – Tài liệu kỹ thuật
Power Generation Equipment – Thiết bị phát điện
Emergency Response Plan – Kế hoạch ứng phó khẩn cấp
Distribution System Design – Thiết kế hệ thống phân phối
Electrical Load Management – Quản lý tải điện
System Maintenance – Bảo trì hệ thống
Energy Resource Planning – Lập kế hoạch tài nguyên năng lượng
Power Consumption Monitoring – Giám sát tiêu thụ điện
Electrical Project Planning – Lập kế hoạch dự án điện
Voltage Optimization – Tối ưu hóa điện áp
Power System Stability – Ổn định hệ thống điện
Capacity Optimization – Tối ưu hóa công suất
Electricity Demand Forecasting – Dự báo nhu cầu điện
Load Management Strategies – Chiến lược quản lý tải
Grid Reliability – Độ tin cậy của lưới điện
Power Infrastructure – Hạ tầng điện lực
Electrical Testing Procedures – Quy trình kiểm tra điện
Energy Management Systems – Hệ thống quản lý năng lượng
Transmission System Design – Thiết kế hệ thống truyền tải
Power Efficiency Metrics – Chỉ số hiệu quả điện
Project Scheduling – Lịch trình dự án
Energy Policy Compliance – Tuân thủ chính sách năng lượng
Power System Diagnostics – Chẩn đoán hệ thống điện
Substation Operation – Vận hành trạm biến áp
Electrical Load Analysis – Phân tích tải điện
Infrastructure Investment – Đầu tư hạ tầng
Power System Protection – Bảo vệ hệ thống điện
Electrical System Design – Thiết kế hệ thống điện
Power Demand Management – Quản lý nhu cầu điện
Installation Safety Procedures – Quy trình an toàn lắp đặt
Energy Efficiency Improvement – Cải thiện hiệu quả năng lượng
Power Transmission Equipment – Thiết bị truyền tải điện
System Integration Testing – Kiểm tra tích hợp hệ thống
Utility Management – Quản lý tiện ích
Power Quality Standards – Tiêu chuẩn chất lượng điện
Electrical Infrastructure Upgrades – Nâng cấp hạ tầng điện
Energy Savings Analysis – Phân tích tiết kiệm năng lượng
Power System Modeling – Mô hình hóa hệ thống điện
Technical Support Services – Dịch vụ hỗ trợ kỹ thuật
Electrical Safety Protocols – Quy trình an toàn điện
Power System Configuration – Cấu hình hệ thống điện
Energy Management Strategies – Chiến lược quản lý năng lượng
Electrical Infrastructure Assessment – Đánh giá hạ tầng điện
Capacity Planning Tools – Công cụ lập kế hoạch công suất
Power Distribution Efficiency – Hiệu quả phân phối điện
Project Cost Estimation – Ước lượng chi phí dự án
Power System Simulation – Mô phỏng hệ thống điện
Grid Modernization – Hiện đại hóa lưới điện
Electrical Maintenance Best Practices – Các phương pháp bảo trì điện tốt nhất
Power System Resilience – Khả năng phục hồi của hệ thống điện
Energy Systems Integration – Tích hợp hệ thống năng lượng
Project Risk Assessment – Đánh giá rủi ro dự án
Power System Upgrades – Nâng cấp hệ thống điện
Technical Feasibility Studies – Nghiên cứu tính khả thi kỹ thuật
Electrical System Reliability – Độ tin cậy của hệ thống điện

Bài viết sử dụng thuật ngữ trên

Power Plant Construction: The power plant construction is scheduled to begin next month.
Electrical Infrastructure: Upgrading the electrical infrastructure is crucial for meeting future energy demands.
Transmission Line: The new transmission line will improve electricity delivery across the region.
Substation Design: Substation design involves planning the layout and equipment for efficient power distribution.
Energy Management: Effective energy management can significantly reduce operational costs.
Load Analysis: Load analysis helps in understanding the power requirements of different areas.
Power Distribution: Power distribution systems need to be regularly maintained to ensure reliability.
Grid Stability: Ensuring grid stability is essential to prevent power outages.
Circuit Breaker: A circuit breaker is used to protect electrical circuits from overloads.
Transformer Installation: Transformer installation must be performed by certified professionals.
Electrical Safety: Electrical safety protocols are crucial to prevent accidents on the job site.
Power Generation: The power generation capacity of the new plant will be 500 megawatts.
Capacity Planning: Capacity planning is essential for predicting future electricity needs.
System Integration: System integration ensures that different electrical components work together seamlessly.
Voltage Regulation: Voltage regulation helps maintain a consistent voltage level in the power system.
Energy Efficiency: Improving energy efficiency can lead to substantial cost savings.
Project Budgeting: Project budgeting involves estimating and controlling the costs of the power plant project.
Load Forecasting: Load forecasting predicts future power needs based on current trends.
Electrical Equipment: The electrical equipment used must meet industry standards for safety and performance.
Power Outage Management: Power outage management strategies are crucial for minimizing downtime.
Grid Expansion: Grid expansion will enable the electricity network to serve more customers.
Substation Upgrade: A substation upgrade is needed to handle increased power loads.
Installation Procedures: Following proper installation procedures ensures the safety and efficiency of electrical systems.
Maintenance Scheduling: Maintenance scheduling helps prevent unexpected failures and extend the life of equipment.
Electrical Code Compliance: Electrical code compliance is mandatory to ensure safety and regulatory adherence.
Power Quality Management: Power quality management addresses issues like voltage sags and surges.
Energy Storage Solutions: Energy storage solutions are important for balancing supply and demand.
Project Risk Management: Project risk management identifies potential issues and develops mitigation strategies.
Feasibility Study: A feasibility study determines whether the proposed power project is viable.
Power System Design: Power system design involves creating a blueprint for the electrical network.
Load Shedding: Load shedding is used to reduce power consumption during peak periods.
Transformer Maintenance: Regular transformer maintenance prevents failures and prolongs equipment life.
Electrical System Testing: Electrical system testing verifies that components function correctly before going live.
Power Grid Monitoring: Power grid monitoring helps detect and address issues in real time.
Energy Audit: An energy audit identifies opportunities for improving energy use.
Electrical Distribution Network: The electrical distribution network delivers power from substations to consumers.
Technical Specification: Technical specifications define the requirements for electrical equipment and installations.
Energy Efficiency Audits: Energy efficiency audits assess how well energy is being used and identify savings opportunities.
Power System Analysis: Power system analysis evaluates the performance and stability of the electricity grid.
Load Balancing: Load balancing ensures that electricity demand is evenly distributed across the grid.
Project Management Software: Project management software helps track progress and manage tasks effectively.
Power Line Inspection: Regular power line inspection is essential for maintaining safety and reliability.
Electrical Wiring: Proper electrical wiring installation is critical for ensuring a safe and functional system.
Energy Consumption Analysis: Energy consumption analysis helps identify patterns and areas for improvement.
System Upgrades: System upgrades enhance performance and efficiency of the electrical network.
Technical Documentation: Technical documentation provides detailed information on system design and installation.
Power Generation Equipment: The power generation equipment includes turbines, generators, and transformers.
Emergency Response Plan: An emergency response plan outlines procedures for dealing with power outages and accidents.
Distribution System Design: Distribution system design focuses on creating efficient power delivery networks.
Electrical Load Management: Electrical load management techniques balance the demand and supply of electricity.
System Maintenance: Regular system maintenance ensures the continuous operation of electrical infrastructure.
Energy Resource Planning: Energy resource planning involves managing and optimizing energy supplies.
Power Consumption Monitoring: Power consumption monitoring tracks electricity use to identify inefficiencies.
Electrical Project Planning: Electrical project planning involves outlining the steps and resources needed for completion.
Voltage Optimization: Voltage optimization improves the efficiency of electrical systems by adjusting voltage levels.
Power System Stability: Power system stability ensures the grid remains operational during disturbances.
Capacity Optimization: Capacity optimization maximizes the efficiency of power generation and distribution.
Electricity Demand Forecasting: Electricity demand forecasting predicts future electricity needs based on trends.
Load Management Strategies: Load management strategies help control and balance electricity demand.
Grid Reliability: Ensuring grid reliability is crucial for preventing widespread power failures.
Power Infrastructure: Upgrading power infrastructure supports growing energy needs.
Electrical Testing Procedures: Following electrical testing procedures ensures system safety and performance.
Energy Management Systems: Energy management systems optimize the generation and use of energy resources.
Transmission System Design: Transmission system design focuses on the layout and efficiency of power transmission lines.
Power Efficiency Metrics: Power efficiency metrics measure the effectiveness of energy use and identify areas for improvement.
Project Scheduling: Effective project scheduling ensures that all tasks are completed on time.
Energy Policy Compliance: Energy policy compliance ensures that projects adhere to regulatory standards.
Power System Diagnostics: Power system diagnostics helps identify and resolve issues in electrical networks.
Substation Operation: Efficient substation operation is key to reliable power distribution.
Electrical Load Analysis: Electrical load analysis helps in understanding the power needs of various systems.
Infrastructure Investment: Infrastructure investment is necessary for expanding and upgrading electrical networks.
Power System Protection: Power system protection safeguards against faults and outages.
Electrical System Design: Electrical system design involves planning the layout and components of electrical networks.
Power Demand Management: Power demand management strategies help balance supply and demand effectively.
Installation Safety Procedures: Following installation safety procedures prevents accidents and ensures compliance.
Energy Efficiency Improvement: Energy efficiency improvement strategies can reduce operating costs and environmental impact.
Power Transmission Equipment: Power transmission equipment includes transformers, circuit breakers, and lines.
System Integration Testing: System integration testing ensures that all components work together as intended.
Utility Management: Utility management involves overseeing the operation and maintenance of electrical services.
Power Quality Standards: Adhering to power quality standards ensures reliable and stable electricity supply.
Electrical Infrastructure Upgrades: Electrical infrastructure upgrades are essential for meeting increased demand.
Energy Savings Analysis: Energy savings analysis identifies ways to reduce energy consumption and costs.
Power System Modeling: Power system modeling helps simulate and analyze electrical network behavior.
Technical Support Services: Technical support services provide assistance for troubleshooting and maintaining electrical systems.
Electrical Safety Protocols: Implementing electrical safety protocols protects workers and prevents hazards.
Power System Configuration: Power system configuration involves setting up and adjusting system components for optimal performance.
Energy Management Strategies: Energy management strategies focus on improving energy use and reducing waste.
Electrical Infrastructure Assessment: Electrical infrastructure assessment evaluates the condition and performance of existing systems.
Capacity Planning Tools: Capacity planning tools assist in forecasting and managing future power needs.
Power Distribution Efficiency: Enhancing power distribution efficiency ensures that energy is delivered effectively.
Project Cost Estimation: Accurate project cost estimation is crucial for budgeting and financial planning.
Power System Simulation: Power system simulation helps predict how changes will affect electrical networks.
Grid Modernization: Grid modernization involves updating infrastructure to improve efficiency and reliability.
Electrical Maintenance Best Practices: Following electrical maintenance best practices extends the lifespan of equipment.
Power System Resilience: Power system resilience ensures that the grid can recover quickly from disruptions.
Energy Systems Integration: Energy systems integration coordinates different energy sources and technologies.
Project Risk Assessment: Project risk assessment identifies potential issues and their impact on the project.
Power System Upgrades: Power system upgrades improve the capability and reliability of electrical networks.
Technical Feasibility Studies: Technical feasibility studies assess whether proposed solutions are practical and achievable.
Electrical System Reliability: Ensuring electrical system reliability is essential for consistent and dependable power supply.

Bài tập

The new ________ will help meet the increasing energy demands of the city.
We need to upgrade our ________ to improve efficiency.
The construction of the ________ is crucial for improving regional power delivery.
The engineer is working on the ________ for the new substation.
Effective ________ is necessary to reduce energy consumption and costs.
A detailed ________ will help in understanding future power needs.
The ________ system needs regular maintenance to ensure reliability.
Ensuring ________ is essential to prevent widespread outages.
A ________ is used to prevent electrical overloads and ensure safety.
The team is focused on the ________ for the new transformer.
Implementing proper ________ procedures is crucial for worker safety.
The plant’s ________ capacity is expected to be 500 megawatts.
________ involves predicting future electricity requirements based on current data.
________ ensures that different components of the electrical system work together.
Proper ________ helps maintain a stable and consistent voltage level.
Improving ________ can lead to significant cost savings in energy usage.
________ involves planning and controlling the costs associated with the project.
Accurate ________ is necessary for predicting future energy needs.
All new ________ must comply with safety and performance standards.
Effective ________ strategies are crucial for minimizing power outages.
The project includes ________ to extend the reach of the electrical network.
The recent ________ has improved the efficiency of the power grid.
Adhering to ________ ensures the safety and effectiveness of electrical installations.
Regular ________ is planned to prevent unexpected equipment failures.
All installations must adhere to the ________ to ensure safety and compliance.
________ addresses issues like voltage drops and power quality.
Implementing ________ solutions is essential for balancing supply and demand.
________ helps identify and manage potential project issues before they arise.
A ________ is conducted to determine if the power project is viable.
The team is working on the ________ for the new electricity grid.
________ helps manage electricity loads during peak times.
Regular ________ is required to maintain the efficiency of the transformers.
________ ensures that all electrical components are functioning as required before launch.
________ helps monitor the performance of the power grid in real-time.
An ________ can help identify areas where energy use can be improved.
The ________ delivers electricity from the substations to the end-users.
The project needs to meet the ________ specified in the technical requirements.
An ________ can highlight opportunities for improved energy efficiency.
A thorough ________ helps evaluate the stability and performance of the power grid.
________ helps ensure that electricity demand is distributed evenly across the network.
Using ________ can enhance the tracking and management of the project tasks.
________ is necessary to ensure that power lines are safe and functional.
Proper ________ is essential for a safe and reliable electrical system.
An ________ helps identify where energy is being used and potential savings.
The team is planning ________ to improve the efficiency of the electrical network.
________ provides detailed instructions for the setup and operation of electrical systems.
The new ________ includes advanced turbines and generators for increased output.
The ________ outlines the procedures for responding to emergencies and power outages.
Effective ________ is critical for ensuring efficient power delivery.
________ helps manage and balance electrical loads to prevent overloads.
________ involves regular checking and upkeep of the electrical systems.
________ involves managing and planning the use of energy resources.
________ is used to track and analyze how much electricity is being consumed.
Proper ________ ensures all aspects of the electrical project are planned and executed well.
________ helps optimize voltage levels to improve system efficiency.
Ensuring ________ is key to maintaining power system reliability and performance.
________ ensures that the available power is used effectively and efficiently.
________ helps predict future electricity needs based on historical data.
________ helps manage electricity demand to prevent system overloads.
Maintaining ________ is essential to prevent widespread power failures.
Investment in ________ is necessary to support the growing energy demands.
Following proper ________ helps ensure system safety and efficiency.
Implementing ________ can improve how energy resources are managed and used.
Proper ________ involves designing efficient and effective power transmission systems.
________ helps evaluate how well energy is being used and where improvements can be made.
Effective ________ helps manage time and resources throughout the project.
Ensuring ________ is necessary to comply with regulatory standards and guidelines.
________ helps detect and resolve issues within the power system.
________ is critical for efficient operation and distribution of power.
A detailed ________ is essential for understanding and planning electrical load needs.
________ supports development and improvements to the power network.
________ ensures that the power system is protected against faults and disruptions.
________ involves creating detailed plans for the electrical infrastructure.
________ strategies help manage and optimize electricity demand and supply.
Following ________ helps ensure that installations are safe and effective.
Implementing ________ can lead to better use of energy and reduced costs.
The project will require new ________ to transmit electricity efficiently.
________ ensures that different system components work together as planned.
Effective ________ is crucial for maintaining and operating utility services.
Adhering to ________ ensures that power quality remains high and stable.
Upgrading the ________ will help meet the increased energy demands of the area.
________ identifies where savings can be made in energy use and management.
________ helps simulate and predict how the power system will behave under different conditions.
________ provides support for troubleshooting and maintaining electrical systems.
Implementing ________ helps ensure the safety of workers and prevents electrical hazards.
Proper ________ involves setting up and configuring power systems for optimal performance.
Effective ________ can improve energy use and reduce waste in the system.
________ helps evaluate the performance and condition of electrical infrastructure.
Using ________ helps forecast and manage future power needs.
Improving ________ ensures that electricity is distributed more effectively.
Accurate ________ is essential for planning and managing project finances.
________ helps predict the impact of changes on the power network.
________ involves updating the power grid to enhance its performance and reliability.
Following ________ helps extend the life of electrical equipment and systems.
Ensuring ________ helps the power system recover quickly from disruptions.
________ coordinates the use of different energy sources and technologies.
A thorough ________ identifies potential issues and their impact on the project.
Implementing ________ improves the capability and reliability of the power system.
________ assesses whether technical solutions are practical and achievable.
Maintaining ________ is crucial for ensuring a dependable and consistent power supply.