Evaluating the Technical and Economic Feasibility of Adding a Power Recovery System to the Steam Condenser of a Lignite Coal-Fired Power Plant

Steam is the typical working fluid to drive turbo-generators in coal-fired power plants. It is an effective working fluid, but some of its energy is extracted in an unusable form when condensed. A Power Recovery Cycle (PRC) using a more volatile Secondary Working Fluid (SWF) added to the steam cycle could improve energy efficiency. PRCs have been applied to the flue gas and for combined cycle systems but not to traditional plant steam cycles. This paper details an analysis of adding a steam cycle PRC to a 500 MW lignite coal-fired power plant. A validated model of the plant was developed and PRCs using the three most attractive SWFs, benzene, methanol and hydrazine, were then added to the model. Adding a benzene, methanol, or hydrazine steam cycle PRC will produce an additional 59, 34, and 49 MW, respectively. An AACE Class 4 factored broad capital cost estimate and comparable operating costs and revenue estimates were developed to evaluate PRC feasibility. The benzene, methanol, and hydrazine processes had 2019 Net Present Values (NPVs) @12% of -$32, -$59, and +$35 million ± 40%, respectively. Thus, a PRC may be profitable at current or modest increases to U.S. Upper Midwest electricity prices of around $0.0667/kWh.

Off-Design Simulation of a CSP Power Plant Integrated with aWaste Heat Recovery System

Concentrating Solar Power(CSP)plants offer a promising way to generate low-emission energy.However,these plants face challenges such as reduced sunlight during winter and cloudy days,despite being located in high solar radiation areas.Furthermore,their dispatch capacities and yields can be affected by high electricity consumption,particularly at night.The present work aims to develop an off-design model that evaluates the hourly and annual performances of a parabolic trough power plant(PTPP)equipped with a waste heat recovery system.The study aims to compare the performances of this new layout with those of the conventional Andasol 1 plant,with the aim of assessing the improvements achieved in the new design.Based on the results,it can be concluded that the new layout has increased the annual generated power to almost 183 GWh(an increase of about 7.60% is achieved compared to the Andasol 1 layout that generates 169 GWh annually).Additionally,the proposed installation has achieved an efficiency of 20.55%,which represents a 7.87% increase compared to the previous design(19.05%).The Levelized Cost of Electricity(LCOE)of the new layout has been reduced by more than 5.8% compared to the Andasol 1 plant.Specifically,it has decreased from 13.11 to 12.35 c/kWh.This reduction in LCOE highlights the improved cost-effectiveness of the newlayout,making it amore economically viable option for generating electricity compared to the conventional Andasol 1 plant.

Development of Sensible Heat Storage Materials Using Sand, Clay and Coal Bottom Ash

In this paper, the mechanical and thermal properties of a sand-clay ceramic with additives coal bottom ash (CBA) waste from incinerator coal power plant are investigated to develop an alternative material for thermal energy storage (TES). Ceramic balls are developed at 1000°C and 1060°C using sintering or firing method. The obtained ceramics were compressed with a compression machine and thermally analyse using Decagon devise KD2 Pro thermal analyser. A muffle furnace was also used for thermal cycling at 610°C. It was found that the CBA increased the porosity, which resulted in the increase of the axial tensile strength reaching 3.5 MPa for sand-clay and ash ceramic. The ceramic balls with the required tensile strength for TES were selected. Their volumetric heat capacity, and thermal conductivity range respectively from 2.4075 MJ·m-3·°C-1 to 3.426 MJ·m-3·°C-1 and their thermal conductivity from 0.331 Wm-1·K-1, to 1.014 Wm-1·K-1 depending on sand origin, size and firing temperature. The selected formulas have good thermal stability because the most fragile specimens after 60 thermal cycles did not present any cracks. These properties allow envisioning the use of the ceramic balls developed as filler material for thermocline thermal energy storage (structured beds) in Concentrating Solar Power plants. And for other applications like solar cooker and solar dryer.

Research on solar aided coal-fired power generation system and performance analysis

Integrating solar power utilization systems with coal-fired power units, the solar aided coal-fired power generation (SACPG) shows a significant prospect for the large-scale utilization of solar energy and energy saving of thermal power units. The methods and mechanism of system integration were studied. The parabolic trough solar collectors were used to collect solar energy and the integration scheme of SACPG system was determined considering the matching of working fluid flows and energy flows. The thermodynamic characteristics of solar thermal power generation and their effects on the performance of thermal power units were studied, and based on this the integration and optimization model of system structure and parameters were built up. The integration rules and coupling mecha- nism of SACPG systems were summarized in accordance with simulation results. The economic analysis of this SACPG system showed that the solar LEC of a typical SACPG system, considering CO2 avoidance, is 0.098 $/kW·h, lower than that of SEGS, 0.14 $/kW·h.

新型光煤互补发电系统热力性能及技术经济性研究

为了减弱太阳能波动对光煤互补发电系统性能的影响,提出了新型光煤互补发电系统,建立了关键设备模型及子系统模型并进行验证,对新型光煤互补发电系统的热力性能及技术经济性进行了研究。结果表明:系统热力性能随运行负荷的下降而下降,随太阳辐照强度增加而先升高后下降;系统年均输出功率为699 MW,年均节煤率为7.506 g/(kW·h),年均光电效率为10.82%;储热时长为10 h时系统技术经济性最优,此时全寿命周期内净现值为4.18×10^(4)万元,内部收益率为11.81%,动态投资回收期为12.6 a,平均度电成本为0.402元/(kW·h),盈利能力较强。

用于燃煤电厂烟气CO_(2)捕集的新型节能工艺

使用单乙醇胺(MEA)进行碳捕集的工艺存在一个关键问题:进行溶剂再生需要大量再沸器热能。为了降低再沸器的热量需求,本研究提供了一种新型的节能工艺,该工艺在富蒸汽压缩(RVC)的工艺方案中引入了富液预热器(RSP),其中富液预热器的热源是燃煤电厂脱硫前的烟气。为显示该RVC+RSP工艺的协同效应和节能效果,采用Aspen Plus分别对基础工艺、RVC工艺、RSP工艺和RVC+RSP工艺进行建模,之后对每个工艺进行节能分析,并评估新型耦合工艺和基础工艺在操作参数发生变化时对节能效果的影响。结果表明:在RVC工艺中引入RSP后,捕获每单位二氧化碳的再生能耗从3.86 MJ/kg降至2.47 MJ/kg,与基础的工艺方案相比,RVC+RSP工艺节省了38.4%的再沸器能耗和19%的总等效能耗,在操作参数波动时该耦合工艺依然能够节约16%以上的等效能耗。

新型光煤互补发电系统动态特性与调峰性能研究

基于某660 MW燃煤发电机组提出了新型光煤互补发电系统,建立了关键设备模型及子系统模型并进行了验证,通过建模仿真的方法对系统动态特性及调峰性能进行了研究。结果表明:配置储热系统后,当太阳辐照强度突降时,系统能在10 min左右恢复平衡且主要参数变化较小;在配置储热时长为10 h的储热子系统后系统能够实现典型日的连续稳定运行;通过配置储热系统和抽汽储热过程,系统负荷范围由198.00~660.00 MW拓宽至187.62~723.13 MW,调峰性能显著提升。

考虑光热电站和柔性负荷的电氢热综合能源系统联合优化运行

为解决现有综合能源系统运行灵活性差及风、光消纳难的问题,同时充分利用氢能实现碳减排目标,本文提出一种考虑光热电站和柔性负荷的电氢热综合能源系统联合优化运行方法。首先,基于光热电站和含电转氢余热利用的氢能系统模型构建电氢热综合能源系统。其次,考虑需求侧电氢热柔性负荷的特征和调节价值,构建含可平移、可转移、可削减负荷的电氢热柔性负荷模型。然后,进一步构建考虑电氢热柔性负荷调节特性的电氢热综合能源系统联合优化运行模型。最后,通过算例仿真验证所提方法能够兼顾经济运行与低碳效果,不仅可以提高光热电站与氢能系统的联合运行能力,而且能够有效提升系统运行的经济性和低碳性,电、氢、热负荷峰谷差分别降低6.68%、11.95%、8.35%,系统运行总成本降低24.4%。

考虑火电-熔盐储热耦合特性的风光火储能源调度

构建以可再生能源为主体的新型电力系统已经成为中国能源发展的必然趋势。以某大型能源基地为仿真对象,建立含有熔盐储热的多能互补系统运行收益模型。该系统通过将火电机组耦合熔盐储热系统,实现能源的存储、错峰利用,提高可再生能源的消纳率。该模型考虑了火电机组多级调峰收益和爬坡成本、储能系统运行成本及可再生能源弃电惩罚成本,以系统运行净收益最高为目标对模型进行优化求解,探究火电机组储热改造对可再生能源消纳和系统运行经济性的影响。加入熔盐储热系统后,系统的整体经济性和可再生能源利用率得到显著提升,场景2每日运行净收益为838.14万元,较场景1增加了47.36万元。场景2的风能利用率从93.91%增加到97.33%,光伏利用率也从95.51%增加到98.44%。

基于LSTM的煤场热值损失多因素线性回归预测

针对火力发电厂煤场热值损失问题,提出了一种基于长短期记忆(LSTM)的多因素线性回归综合热值损失预测模型。使用LSTM神经网络预测煤场所在地的环境因素,建立煤堆热值变化与时间累积下各因素总值之间的回归方程,代入预测因素的影响值以计算未来的热值损失。在煤场进行实地数据采样,对高位热值进行同值灰分处理,利用所记录的环境因素数据对因变量热值进行多因素回归分析,建立热值损失数学模型。通过构建LSTM神经网络预测多因素变化,将预测数据导入回归模型进行热值变化的预测。仿真结果表明:多因素LSTM神经网络对环境因素的预测精度要高于单因素及传统差分自回归移动平均(ARIMA)模型,并且具有较强的稳定性。

内陆水面漂浮式光伏开发分析与可行技术方案

光伏作为我国目前最重要的新能源发电形式之一,对实现我国双碳战略目标有着重要的作用。基于开发水库、内陆水面漂浮式光伏电站的各类影响因素及政策导向,分析了未来开发内陆水面漂浮式光伏电站,形成水光互补发电格局的挑战与前景。对漂浮式光伏电站的技术方案进行了调查、研究与初步设计,形成了可供参考的内陆漂浮式光伏开发初步方案。

风光互补发电在污水处理厂的研究和设计

风光互补发电是以风力资源和太阳能资源为基础的互补性发电方式,在现代社会中具有不可替代的优势。全文利用文献研究法,立足于污水处理厂视角,首先针对性地从风力发电部分、太阳能发电部分分析风光互补发电系统的组成结构,最后以山丹县污水处理厂为例,结合改造工程对风光互补发电系统的应用效果进行分析。

严寒地区宜居低碳牧居建筑设计

为改善捡烧牛粪燃能的利用方式,探索广大高原严寒牧区牧民住房绿色低碳转型路径,释放放牧草地生态系统蕴含的巨大减排增汇潜力和价值,文中以装配式低碳牧居替代捡烧牛粪的帐篷为导向,综述了近年来国内外严寒牧区牧民住房在装配式建筑、骨架与围护结构、光风互补供电系统和太阳能供暖系统四个方面绿色低碳技术的进展与态势,结合牧户调查、技术研发和牧居示范工程建设的实践,归纳、探讨了净零碳排放牧居技术路径,解析了取得初步成果的主要参数、经验和不足,为严寒地区牧居低碳化设计提供借鉴。得出“三室一廊”牧居、装配式骨架结构、低能耗围护结构、可再生能源替代和精细化管理可能成为牧区人与自然和谐共生现代化中新一代牧居的美好图景的结论。

煤电二氧化碳捕集能量梯级利用与机组效率分析

燃煤电厂配置二氧化碳捕集系统需消耗大量蒸汽用于吸收剂再生与循环利用,蒸汽消耗降低机组发电效率和发电量。机组热力系统和二氧化碳捕集系统的跨界区能量耦合利用是减少发电效率损失的重要途径。以全容量二氧化碳捕集的630 MW机组为对象,构建全容量烟气的二氧化碳捕集系统模型和汽轮机组热力系统热平衡图,借助等效焓降法研究碳捕集系统工艺参数选择及多种余热利用方法对汽轮机组发电效率的影响。结果表明:全容量二氧化碳捕集系统后需消耗569.18 t/h蒸汽,导致原机组循环效率从43.84%降至35.74%。再沸器凝结水余热用于富液加热时,再生热耗降低0.2 GJ/t,节约蒸汽用量43.05 t/h,机组循环效率升至36.35%,和余热用于机组回热系统效果相当,但前者系统更简单。再生气余热和二氧化碳压缩机级间余热可用于机组凝结水加热,节约机组低压缸抽汽,提高循环效率;再生气温度、流量和余热量与碳捕集系统富液分流工艺的分流比有关,随着冷富液流量增加,碳捕集系统能耗和机组发电效率损失均呈先降低再升高趋势,当冷富液、主富液、凝结水加热富液质量比0.20∶0.75∶0.05时,机组发电效率最高;二氧化碳压缩机级数越少可利用的热量越大,机组发电效率越高,但同时消耗更多电能。通过优化,配置全容量二氧化碳捕集系统的630 MW机组发电功率由无优化时的510.09 MW增至528.96 MW。

考虑置信容量和调峰能力的新能源基地光热电站配置方法

光热电站具有清洁低碳、长时间储能的友好并网特性,能有效平抑新能源出力波动。相比于传统火电机组,光热电站的调节能力依然存在不足,可能会降低新能源基地外送能力。为此,基于光热电站接入前后外送可靠性不变原则,建立针对光热电站置信容量及调峰能力的评估方法和模型。在此基础上,以新能源基地综合发电经济性为目标,考虑机组约束、外送约束、光热电站置信容量和调峰能力约束建立模型。通过算例仿真,采用时序模拟技术,对光热电站的储热时长和容量优化配置模型进行求解,给出典型场景下的光热电站配置方案,得到风光容量配比最优的容量配置方案,并分析不同风光容量配比下的经济性情况。所提的光热电站储热时长和容量配置方法能够有效提升新能源基地的低碳性,优化光热电站的投资收益。

“双碳”目标下能量互补系统对燃煤机组的优化提升

为了优化传统燃煤机组大惯性的问题,以及减少碳排放量,从而实现燃煤机组效率的提升。研究采用串并联方式构建了一种太阳能-燃煤能量互补机组,并采用参数辨识的方法实现机组调控。结果显示,不论是受到阶跃干扰还是斜坡干扰,研究所提能量互补系统均优于传统发电系统,其调节速度更快、波动更小、安全性更高。

A燃煤电厂多模式耦合供热系统运行优化研究

A燃煤电厂多种供热改造系统耦合运行,为提高供热系统节能效果,降低发电煤耗,通过EBSILON软件搭建理论模型。研究结果表明:按照余热利用占比由高到低分别为高背压供热方式、热泵供热方式、抽汽供热方式;为提高机组的余热利用占比,应优先提高高背压供热量;单机的可利用余热有限,超过余热量时,剩余热量需要采用抽汽供热方式,因此,随着总供热量增加,抽汽量、机组电功率和高背压供热占比都会出现拐点;通过对历史运行数据采用神经网络算法训练,获得供热量预测模型,结合EBSILON模型对电厂供热节能优化提出指导意见。

热管空气预热器应用于燃煤电厂可行性研究

三分仓回转式空气预热器是普遍应用于当前大型燃煤电厂的蓄热式热交换设备,随着脱硝装置氨逃逸问题越来越突出,硫酸氢铵(ABS)引起的空预器堵灰问题愈发严重。本文对采用前置式重力热管空气预热器解决上述问题的可行性进行了分析,表明该方式能有效缓解当前回转式空气预热器堵塞、腐蚀等突出问题,为当前燃煤电厂安全运行提供有益借鉴。

一电厂尿素热解工艺系统研究与改造

针对一电厂原电加热器尿素热解系统能耗高、故障率高以及脱硝系统运行不稳定等问题,提出采用炉内气气换热器代替电加热器的改造方案。炉内气气换热器布置在燃煤机组低温再热器水平段上方,换热管材质为06Cr25Ni20。炉内气气换热器导致燃煤耗量增加约2.7%,烟气温度下降低于5℃,锅炉效率降低0.03%,对锅炉效率的影响可以忽略不计。通过经济性分析,改造后该电厂每年节省费用1.267 2×10^(6)元,具有显著的经济效益。

太阳能光谱分频光伏光热驱动钾基吸附剂碳捕集系统集成设计

钾基吸附剂干法脱碳技术在燃烧烟气CO_(2)捕集中极具应用前景,但其再生能耗依赖于燃煤发电自身能量,如何在不影响电站能效条件下满足碳捕集所需能量成为挑战。与此同时,聚光光伏光电转换过程中,由于光谱能量同电池带隙能不匹配,约80%左右的能量会转化为废热,影响光伏电池安全高效工作,如何减少废热对其发电效率的影响并更好地利用剩余光谱能量成为挑战。文章提出太阳能全光谱分频光伏光热驱动钾基吸附剂碳捕集思路,即利用分频膜将适于光伏的可见光波段分配给光伏电池进而转化为电能,将剩余波段聚光集热利用为钾基吸附剂碳捕集过程供能。研制了原理样机并开展实验,结果显示400~600Wm^(-2)辐照条件下,聚光集热温度大于170℃,光伏平均发电功率为9.2W,钾基吸附剂可完全实现再生。以某330MW典型电站为案例开展系统分析,结果表明,系统较单一燃煤碳捕集效率增加13.1个百分点,较光伏发电系统太阳能综合利用率提升明显;与同规模单一燃煤碳捕集和光伏发电的简单叠加相比,系统总出功增加25.1MW,实现1+1>2的集成效果,证明该系统节能减排效果显著。综合考虑各类收益,系统静态投资回收期为4.6年,表明系统具有一定的经济效益。文章提出的全光谱太阳能分频光伏光热驱动钾基吸附剂碳捕集工艺可应用于太阳能和化石资源丰富的中西部地区,为清洁能源与化石能源并行利用提供新思路,具有突出的应用价值和前景。