近年来,随着非洲能源结构持续向绿色化、分布式化转变,如何在偏远地区、弱电网环境下实现稳定供电,成为影响当地经济发展与民生质量的关键。在肯尼亚建设的 6MW 混合微网能源电站集群,通过分布式协同调度与智能能源管理,实现多种能源形态的高比例消纳、最优组合与低成本运行,成为了传统市电电网之外的另一种选择,为当地提供了高可用性、低油耗、强智能的电力支持。
In recent years, as Africa’s energy landscape continues to shift toward greener and more distributed structures, ensuring stable power supply in remote areas and weak-grid environments has become critical to both local economic development and quality of life.The 6MW hybrid microgrid power station cluster built by MPMC (Shoufan Power) in Kenya offers an alternative to traditional utility grids. Through distributed coordinated dispatch and intelligent energy management, the system enables high renewable-energy penetration, optimal energy blending, and low-cost operation—delivering highly available, fuel-efficient, and intelligently managed power to the region.
规模:
共 4 个站点,总装机容量 6MW
配置结构:
光伏(>1MW/站)+储能(≥1MWh/站)+柴油发电机组(2×500kW + 2×250kW)
储能规格:
80% DOD、6000 次循环寿命,直流耦合,双机备份冗余结构
控制系统:
MPMC 自主研发 SCADA + EMS,实现全站智能联动、远程管理、现场运维监测、跨区域多电站协同
Scale
4 station sites. Total installed capacity: 6 MW
System Configuration
Solar PV (>1 MW per site)+Battery Energy Storage (≥1 MWh per site)+Diesel Generator Sets (2×500 kW + 2×250 kW)
Energy Storage Specifications
80% DOD、6,000-cycle lifespan、 DC-coupled architecture、Dual-unit backup redundancy
Control System
MPMC’s self-developed SCADA + EMS enables full-site intelligent coordination, remote management, on-site O&M monitoring, and cross-regional multi-station collaboration
光储为主、柴发为辅的
高效混合能源体系
Hybrid Energy System
光伏 + 储能(主用)
Solar PV + Energy Storage (Primary System)
在技术层面,本项目旨在解决传统光伏发电场发电能力无法完全响应负载波动的问题。使不稳定的电力来源通过有效调节和管控变成稳定的电力供应方,绕开了传统电厂的高消耗高运维等弊端,最大化利用清洁能源实现可持续地、稳定地电力供应。
Technically, this project is designed to address the inherent limitation of traditional solar power plants—the inability to fully respond to load fluctuations. By using advanced regulation and control, the system transforms intermittent renewable energy into a stable power supply, bypassing the high fuel consumption and heavy O&M burdens of conventional power plants, while maximizing the use of clean energy for sustainable, stable electricity delivery.
我们为每个1兆瓦光伏电站配置容量不低于1兆瓦时的储能系统,采用了先进的直流耦合架构。该架构能够有效减少交直流转换过程中的能量损失,从而显著提高光伏发电量的利用率与可用度。
Each 1 MW solar station is equipped with an energy storage system of no less than 1 MWh, adopting an advanced DC-coupled architecture. This architecture significantly reduces energy losses from AC/DC conversion processes, leading to a substantial improvement in PV utilization efficiency and availability.
该系统电池包采用80%深度放电(DOD)与6000次循环寿命的高标准设计,完美契合高频次、高强度的运行场景。在此卓越的耐久性基础上,系统能够可靠地执行削峰填谷、负荷平衡以及在电网与离网模式间实现无缝切换等关键功能,为电站的稳定与经济运行提供核心保障。考虑到这些电站需要支撑对应城镇10年左右的发展需求,我们特意设计成可直接扩展的模式,方便当地供电公司根据需求实时扩容。
The battery system is designed to a high standard, featuring 80% Depth of Discharge (DOD) and a 6,000-cycle lifespan, making it perfectly suited for high-frequency, high-intensity operating scenarios. Built on this exceptional durability, the system can reliably perform key functions such as peak shaving, load balancing, and seamless switching between grid-connected and off-grid modes, providing essential support for stable and economical power station operation. Given that these stations must accommodate approximately ten years of development for the surrounding towns, the system is intentionally designed with direct scalability, enabling local utilities to expand capacity in real time as demand grows.
柴油发电机组(备用)
Diesel Generator Sets (Backup System)
为确保在长时间阴雨或设备维护时仍可保证供电,项目在每站配置 2×500kW + 2×250kW 柴油发电机组。机组仅作为备用,在光储无法支撑时自动启动。SCADA 会自动控制机组进入最优油耗点运行区间。配置励磁后合闸技术,确保快速响应突发负载。这种运行机制大幅减少机组运行时间,提高燃油效率,同时避免机组因低负载工况引起的损耗。
To ensure uninterrupted power supply during extended periods of cloudy weather or equipment maintenance, each station is equipped with 2×500 kW + 2×250 kW diesel generator sets. These units operate strictly as backup and will start automatically only when the solar-plus-storage system cannot support the load.The SCADA system autonomously controls the generators to operate within their optimal fuel-efficiency range. With excitation-synchronized closing technology, the system can quickly respond to sudden load changes.This operating mechanism significantly reduces generator runtime, improves fuel efficiency, and prevents wear caused by prolonged low-load operation.
完整的电网级运行能力
Full Grid-Level Operating Capabilities
项目全站具备以下核心功能,可在极端情况下仍然保持稳定运行。
The project delivers complete grid-forming and grid-support functions, ensuring stability even under extreme conditions.
系统运行逻辑图
● PQ 模式:功率调节
● VF 模式:独立电压/频率控制
● VSG 模式:虚拟同步机,提升系统稳定性
● 黑启动:在电网失电时独立恢复供电
● 构网能力:可在无电网区域独立形成可用的电力网络
● 智能发电调配能力:可根据光伏波动以及负载波动情况,智能指令储能的充放电能力以及柴发的启停和带载比例,保证全电站送电的稳定性
● 无功调节能力:所有的PCS均具备全额度的无功吸收能力,有效帮助大电网稳定电气特性
● PQ Mode:
Active/reactive power control
● VF Mode:
Independent voltage & frequency control
● VSG Mode:
Virtual synchronous generator for enhanced system stability
● Black Start:
Independent restart capability in case of grid outage
● Grid-Forming Ability:
Can create a stable power network in off-grid areas
● Intelligent Generation Dispatch:
Automatically manages PV fluctuations, load variations, battery charge/discharge, and generator start/stop and load-sharing to maintain station-wide power stability
● Reactive Power Regulation:
All PCS units support full-range reactive power absorption to help stabilize the larger grid’s electrical characteristics
智能调控系统
打造“会思考的电站”
Intelligent Control System
Intelligent Control System
SCADA 全站互联:实时同步、远程控制
SCADA Full-Site Interconnection:Real-Time Synchronization · Remote Control
本系统构建了覆盖所有站点与主控中心的实时通讯网络,不仅支持远程监控、启停指令与参数配置等核心远程操作,更通过集成StarLink卫星通讯作为备份链路,显著提升了系统的通讯冗余与可靠性。
The system establishes a real-time communication network connecting all station sites with the central control center. It supports core remote operations—including monitoring, start/stop commands, and parameter configuration—and further enhances communication redundancy and reliability by integrating StarLink satellite communication as a backup link.
MPMC 工程师为当地项目人员讲解系统
在数据管理方面,系统具备长达10年的数据留存能力,并集成了报表自动生成、仓储管理与维护工单流等高级功能。同时,整套SCADA系统采用SL3级网络安全框架,确保运营数据与控制系统能够有效抵御各类网络风险,为全域运维提供坚实保障。
For data management, the system offers up to 10 years of data retention and incorporates advanced features such as automated report generation, warehouse management, and maintenance work-order workflows. Additionally, the entire SCADA system is built on an SL3-level cybersecurity framework, ensuring that operational data and control systems are well protected against various cyber risks and providing a robust safeguard for system-wide operation and maintenance.
EMS 智能策略调度
EMS Intelligent Strategy Dispatch
我们的能源管理系统(EMS)通过融合多源数据与精准预测,动态优化能源组合,旨在实现三大核心目标:光伏发电效率最大化、柴油机运行最少化、储能响应最灵活。
Our Energy Management System (EMS) dynamically optimizes the energy mix by integrating multi-source data and precise forecasting. It is designed to achieve three core objectives: maximize PV generation efficiency, minimize diesel runtime, and maximize the flexibility of energy storage response.
SCDA界面
● 气象驱动,智能调度:实时分析光照强度与天气突变预警。自动提前调整储能策略与负荷分配。确保系统在各类天气下均能实现全天候稳定供电。
● 精打细算,极致降耗:持续监测光伏发电潜力与储能状态。仅在必要时才启动柴油发电机,并确保其始终运行在最佳油耗区间, 最大限度地降低燃油消耗与运行成本。
● 多能协同,高效运行:自动匹配实时负载需求,灵活调节光伏、储能、柴油机等多种发电源的组合,最大化提升站点整体运行效率。
● 面向未来,弹性扩展:系统具备强大的电网扩展能力。未来可无缝接入更多站点,构建成更稳定、更经济的区域级超大微电网系统。
● Weather-Driven Intelligent Dispatch:
Continuously analyzes solar irradiance and weather-change alerts, automatically adjusting storage strategies and load allocation in advance to ensure stable, around-the-clock power supply under all weather conditions.
● Cost Optimization & Ultra-Low Consumption:
Monitors PV potential and battery status in real time. Diesel generators are activated only when necessary and always kept within their optimal fuel-efficiency zone, minimizing fuel consumption and operational costs.
● Multi-Energy Coordination for Efficient Operation:
Automatically matches real-time load demand and optimizes the combination of PV, storage, and diesel generation, maximizing overall station efficiency.
● Future-Ready & Scalable:
Built with strong grid-expansion capability, the system can seamlessly integrate additional
sites in the future, evolving into a more stable and economical large-scale regional microgrid.
非洲复杂环境下的
高稳定性验证
High-Stability Verification
肯尼亚独特的自然环境对能源系统构成多重挑战:持续高温、强烈紫外线、风沙侵袭及频繁的电网波动,无不要求设备具备卓越的耐候性与系统稳定性。在MPMC实际部署的6MW微电网系统中,所有设备在严苛条件下结构完好、无腐蚀发生,储能系统运行稳定可靠;光储与柴油能源之间切换迅速、无缝衔接;SCADA系统更实现了高效的远程运维与低人员依赖。这一系列交付成果,充分印证了MPMC在微网整体设计、高适应性设备选型与智能控制系统集成方面的综合技术实力与产品可靠性。
Kenya’s unique natural environment poses multiple challenges to energy systems: persistent high temperatures, intense ultraviolet radiation, sand and dust exposure, and frequent grid fluctuations—all of which demand exceptional durability and system stability. In MPMC’s deployed 6MW microgrid system, all equipment has maintained structural integrity under harsh conditions with no corrosion, and the energy storage system has operated with stable and reliable performance. The system achieves rapid, seamless switching between solar-storage power and diesel generation, while the SCADA platform enables efficient remote O&M with minimal on-site manpower dependency. Together, these results demonstrate MPMC’s comprehensive technical strength and product reliability in microgrid system design, high-resilience equipment engineering, and intelligent control system integration.
项目价值
Project Value
首帆动力MPMC肯尼亚微网项目成功构建了清洁能源综合利用的典范,展现出多维度综合价值。
The MPMC Kenya microgrid project has successfully created a benchmark for integrated clean-energy utilization, demonstrating multidimensional value.
对用户而言,该系统能显著降低柴油消耗与日常运营成本,同时提供7×24小时稳定可靠的电力供应,不仅保障了生产生活的连续性与品质,更直接改善了当地的作业环境与居民生活条件。For end users, the system significantly reduces diesel consumption and daily operating costs, while providing stable and reliable 24/7 power supply. This not only ensures continuity and quality in both production and daily life, but also directly improves local working environments and living conditions.
对当地来说,项目通过规模化使用清洁能源,有效减少了污染物与碳排放,助力区域绿色生态建设;它显著提升了本地的能源自主性与供能韧性,并加速推动了可再生能源在当地能源结构中的高比例渗透。For the local region, the project enables large-scale adoption of clean energy, effectively reducing pollutants and carbon emissions and contributing to regional ecological sustainability. It enhances local energy independence and supply resilience, while accelerating the penetration of renewable energy within the regional energy mix.
对行业而言,该项目成功为东非及其他离网地区树立了一个可复制的微电网建设样板,为全球类似区域的能源解决方案提供了最佳实践。For the industry, the project establishes a replicable microgrid model for East Africa and other off-grid regions, offering a proven best-practice reference for energy solutions in similar environments worldwide.
未来,我们将继续以更先进的技术、更稳定的系统,为全球新能源发展助力。
Looking ahead, we will continue to support global renewable-energy development with more advanced technologies and more resilient systems.
