total installating power of electric powerplant
简明释义
电站总装机功率
英英释义
例句
1.Before construction, we need to calculate the total installating power of electric powerplant to ensure it meets demand.
在施工之前,我们需要计算电厂的总装机容量以确保其满足需求。
2.Investors are interested in the total installating power of electric powerplant when assessing project viability.
投资者在评估项目可行性时对电厂的总装机容量很感兴趣。
3.Regulatory bodies often review the total installating power of electric powerplant for compliance with standards.
监管机构通常会审查电厂的总装机容量以确保符合标准。
4.The total installating power of electric powerplant is crucial for determining the energy supply capacity.
电厂的总装机容量对于确定能源供应能力至关重要。
5.The total installating power of electric powerplant affects the grid stability during peak hours.
电厂的总装机容量会影响高峰时段的电网稳定性。
作文
The concept of total installing power of electric powerplant is crucial in understanding the capacity and efficiency of energy generation facilities. This term refers to the maximum output that a power plant can generate, measured in megawatts (MW) or gigawatts (GW). The total installing power of electric powerplant indicates how much electricity the facility can provide to meet the demands of consumers, industries, and businesses. It is essential for planning and managing the energy supply to ensure that there is enough power available during peak usage times.When evaluating the total installing power of electric powerplant, various factors come into play. These include the type of energy source used, such as fossil fuels, nuclear, or renewable sources like solar and wind. Each energy source has its own characteristics that affect the overall capacity. For instance, solar power plants depend on sunlight availability, while wind farms rely on wind speeds. Therefore, the total installing power of electric powerplant must be assessed in conjunction with these environmental factors to determine the reliability and sustainability of the energy supply.Moreover, the total installing power of electric powerplant also plays a significant role in energy policy and economic planning. Governments and energy authorities use this information to make informed decisions about investments in infrastructure, grid management, and energy distribution. A higher installed capacity can lead to lower energy prices due to increased competition and efficiency. Conversely, if the total installing power of electric powerplant is insufficient, it may result in energy shortages, blackouts, and increased costs for consumers.In addition, understanding the total installing power of electric powerplant is vital for future developments in the energy sector. With the global shift towards sustainable energy solutions, many countries are investing in expanding their renewable energy capacities. The total installing power of electric powerplant will need to reflect these changes as more wind turbines, solar panels, and other green technologies are integrated into the energy mix. This transition not only aims to reduce carbon emissions but also to enhance energy security and independence.Furthermore, advancements in technology are continuously shaping the total installing power of electric powerplant. Innovations in energy storage systems, smart grid technologies, and energy efficiency measures can significantly increase the effective capacity of existing plants. For example, battery storage solutions allow power plants to store excess energy generated during low-demand periods and release it during peak times, effectively increasing the total installing power of electric powerplant without necessitating new construction.In conclusion, the total installing power of electric powerplant is a fundamental metric that encapsulates the potential output of energy facilities. It influences energy policy, economic strategies, and technological advancements in the sector. As the world moves towards a more sustainable future, understanding and optimizing this capacity will be vital in ensuring reliable and affordable energy for all. Thus, stakeholders in the energy industry must prioritize the evaluation and enhancement of the total installing power of electric powerplant to meet the growing demands of society while promoting environmental sustainability.
电厂的总装机容量这一概念对于理解能源生产设施的容量和效率至关重要。这个术语指的是电厂能够产生的最大输出,通常以兆瓦(MW)或千兆瓦(GW)为单位。电厂的总装机容量表示该设施能够提供多少电力,以满足消费者、工业和企业的需求。它对于规划和管理能源供应至关重要,以确保在高峰使用时有足够的电力可用。在评估电厂的总装机容量时,多个因素会影响结果。这些因素包括所使用的能源来源类型,例如化石燃料、核能或可再生能源,如太阳能和风能。每种能源源都有其特性,影响整体容量。例如,太阳能电厂依赖阳光的可用性,而风电场则依赖于风速。因此,电厂的总装机容量必须结合这些环境因素进行评估,以确定能源供应的可靠性和可持续性。此外,电厂的总装机容量在能源政策和经济规划中也发挥着重要作用。政府和能源主管部门利用这些信息来做出关于基础设施投资、电网管理和能源分配的明智决策。更高的装机容量可能会导致由于竞争和效率提高而降低能源价格。相反,如果电厂的总装机容量不足,可能会导致能源短缺、停电和消费者成本增加。此外,了解电厂的总装机容量对能源行业未来的发展至关重要。随着全球向可持续能源解决方案的转变,许多国家正在投资扩大可再生能源的能力。电厂的总装机容量需要反映这些变化,因为越来越多的风力涡轮机、太阳能电池板和其他绿色技术被纳入能源组合。这一转型不仅旨在减少碳排放,还旨在增强能源安全和独立性。此外,技术进步不断塑造着电厂的总装机容量。能源存储系统、智能电网技术和能源效率措施的创新可以显著提高现有电厂的有效容量。例如,电池存储解决方案允许电厂在低需求期间存储多余的电能,并在高峰期间释放,从而有效地提高电厂的总装机容量,而无需新建设施。总之,电厂的总装机容量是一个基本指标,概括了能源设施的潜在输出。它影响能源政策、经济战略和行业中的技术进步。随着世界朝着更可持续的未来发展,理解和优化这一容量对于确保所有人都能获得可靠且负担得起的能源至关重要。因此,能源行业的利益相关者必须优先评估和提升电厂的总装机容量,以满足社会日益增长的需求,同时促进环境可持续性。
