Numerical simulation and analysis of solid-liquid two-phase threedimensional unsteady flow in centrifugal slurry pump

Based on RNG k-ε turbulence model and sliding grid technique, solid-liquid two-phase three-dimensional(3-D) unsteady turbulence of full passage in slurry pump was simulated by means of Fluent software. The effects of unsteady flow characteristics on solid-liquid two-phase flow and pump performance were researched under design condition. The results show that clocking effect has a significant influence on the flow in pump, and the fluctuation of flow velocity and pressure is obvious, particularly near the volute tongue, at the position of small sections of volute and within diffuser. Clocking effect has a more influence on liquid-phase than on solid-phase, and the wake-jet structure of relative velocity of solid-phase is less obvious than liquid-phase near the volute tongue and the impeller passage outlet. The fluctuation of relative velocity of solid-phase flow is 7.6% smaller than liquid-phase flow at the impeller outlet on circular path. Head and radial forces of the impeller are 8.1% and 85.7% of fluctuation, respectively. The results provide a theoretical basis for further research for turbulence, improving efficient, reducing the hydraulic losses and wear. Finally, field tests were carried out to verify the operation and wear of slurry pump.

Influence of Blade Thickness on Transient Flow Characteristics of Centrifugal Slurry Pump with Semi-open Impeller

As the critical component, the impellers of the slurry pumps usually have blades of a large thickness. The increasing excretion coefficient of the blades affects the flow in the impeller resulting in a relatively higher hydraulic loss, which is rarely reported. In order to investigate the influence of blade thickness on the transient flow characteristics of a centrifugal slurry pump with a semi-open impeller, transient numerical simulations were carried out on six impellers, of which the meridional blade thickness from the leading edge to trailing edge varied from 5-10 mm, 5-15 mm, 5-20 mm, 10-10 mm, 10-15 mm, and 10-20 mm, respectively. Then, two of the six impellers, namely cases 4 and 6, were manufactured and experimentally tested for hydraulic performance to verify the simulation results. Results of these tests agreed reasonably well with those of the numerical simulation. The results demonstrate that when blade thickness increases, pressure fluctuations at the outlet of the impeller become severe. Moreover, the standard deviation of the relative velocity in the middle portion of the suction sides of the blades decreases and that at the outlet of the impeller increases. Thus, the amplitude of the impeller head pulsation for each case increases. Meanwhile, the distribution of the time-averaged relative flow angle becomes less uniform and decreases at the outlet of the impeller. Hence, as the impeUer blade thickness increases, the pump head drops rapidly and the maximum efficiency point is offset to a lower flow rate condition. As the thickness of blade trailing edge increases by 10 mm, the head of the pump drops by approximately 5 m, which is approximately 10 % of the original pump head. Futhermore, it is for the first time that the time-averaged relative flow angle is being considered for the analysis of transient flow in centrifugal pump. The presented work could be a useful guideline in engineering practice when designing a centrifugal slurry pump with thick impeller blades.

Influence on the Solid−Liquid Two-Phase Flow from Cross-Section Area of Slurry Pumps for Deep-Sea Mining

To explore the mechanism of solid-liquid two-phase flow in deep-sea mining pumps,this paper investigates the influences of the impeller cross-section area on the multi-phase flow in the slurry pump.Experimental and numerical results are presented for two-phase flow in four impellers with different cross-section areas.They show that the degree of vortex strength and the passing capacity of particles increase as the cross-section area of the impeller.In addition,the correlations between the two-phase flow and cross-section area have been revealed by a mathematical model taking the force of the flow field into account.The simulation results confirm the theoretical analysis,while the experimental pump performances validate the numerical calculation.The influence of the cross-section area on two-phase flow and pump performance could provide theoretical support for the design of high-performance deep-sea mining slurry pumps.

水泥水化影响水合物层稳定性定量评价装置及影响程度的评测

针对海洋深水水合物层在固井过程水泥水化放热对水合物分解量的影响缺乏量化评价装置及方法的问题,充分考虑固井过程中水泥浆体系与水合物层的接触方式,建立了一套模拟水合物层固井的水合物稳定性评价实验装置,该装置实现了低温高压下水合物的生成、带压条件下水泥浆与水合物层接触的流动泵入,直观地测试了与水合物层直接接触下的水泥浆水化放热对地层温度、压力的影响。根据设计的实验装置,通过对水合物饱和度、水合物分解气量的推导计算,建立了一套水合物模拟地层的制作方法,并建立了水泥浆水化影响水合物层稳定性评价方法。根据南海地区浅层地质条件建立了模拟水合物地层,泵入G级油井水泥净浆、低密水泥浆体系和低热水泥浆体系等3组水泥浆体系,得出单位体积油井水泥候凝过程中分解水合物的气体的量分别为0.7356、0.1091和0.0649 mol/L,且评测表明,低热水泥浆体系能够大幅度缩短固井候凝的等待时间。该研究为油气固井过程中对浅层水合物的影响提供了直观测试方法,也证明了海洋深水水合物地层中使用低热水泥浆体系的必要性。

燃煤机组脱硫浆液循环泵定频运行控制策略优化及节能分析

为消纳可再生能源大规模并网发电,燃煤发电机组的调峰调频任务剧增,长时间处于深度调峰和变负荷过程,导致湿法烟气脱硫系统的性能下降、厂用电率大幅上升。为此,建立了超超临界660 MW燃煤发电机组的动态模型及基于双膜理论的湿法脱硫系统动态模型;模拟了变负荷过程中不同工况点切换浆液循环泵时脱硫系统的性能,发现变负荷过程中浆液和烟气流量的精准匹配可使脱硫系统在满足SO2排放的前提下实现最小的电能消耗;进一步,获得了变负荷过程中浆液循环流量阶跃变化时SO2出口质量浓度的预测模型,提出了浆液循环泵定频运行优化控制策略,可实现变负荷过程中浆液与烟气流量的最佳匹配;最后,分析了优化控制策略的节能潜力。研究结果表明:75%THA~50%THA降负荷过程中,变负荷速率为1.0%、1.5%和2.0%Pe/min,分别可节能20.12%、21.52%和22.82%;而在升负荷过程中,分别可节能10.04%、9.90%和8.66%,变负荷过程中烟气流速变化的差异是造成降负荷和升负荷过程中节能潜力不同的根本原因。

铌对渣浆泵高铬铸铁组织和性能影响

采用对比试验,分析讨论了铌对一种渣浆泵用高铬铸铁性能的影响。分别测量了材料的力学性能、硬度和耐磨性,并对组织进行了分析。结果表明,加入铌对高铬铸铁碳化物形态有明显的改变,这种改变提高了力学性能,同时也提高了材料耐磨性。

基于转轮除湿的蒸发式过冷水制取流态冰方法的研究

本文围绕蒸发式过冷水制取流态冰,提出了一种新型的基于转轮除湿的流态冰制取系统,通过转轮除湿营造低水蒸气分压力环境,实现水滴的管外过冷,避免了传统过冷水法的冰堵问题和真空法能耗高的问题,并且同溶液除湿型制冰方法相比,系统设备简单且除湿效果更好,实现了水滴更大的过冷度,依靠系统自身的冷凝热即可满足转轮再生需求。构建了完整制冰系统并分别建立了转轮除湿模型、CO_(2)热泵模型和蒸发制冰模型,通过模拟分析初步验证了系统的可行性与高效性,并研究了主要运行参数对系统性能的影响。结果表明:在最佳运行工况下,新型流态冰制取系统的制冰性能系数比传统过冷水法提高了25.9%,单周期制冰量提高了4.3倍。

泥浆射流泵冲蚀磨损特性

为了研究泥浆射流泵的冲蚀磨损特性,基于欧拉-拉格朗日方法对泥浆射流泵内部的固液两相流动开展了数值模拟,重点对泥浆射流泵内部液固两相流的冲蚀磨损规律进行了研究。结果表明:泥浆射流泵喉管进口和喉管中后段是产生冲蚀磨损的主要部位,吸入室和扩散管未产生明显冲蚀磨损。颗粒质量流量从1 kg/s增大到1.8 kg/s时,泥浆射流泵最大冲蚀速率增大了93.7%;泥浆流速从2 m/s增大到5 m/s时,最大冲蚀速率增大了11.48倍;颗粒直径从200μm增大到450μm时,最大冲蚀速率先减小后增大。相较于颗粒质量流量和颗粒直径,泥浆流速对射流泵内表面的冲蚀磨损影响更大,但产生冲蚀磨损的主要部位不会随泥浆流速、颗粒质量流量和颗粒直径发生明显改变。研究成果可为射流泵的设计提供参考。

基于钻孔信息的含水分层定位与富水区分析

针对煤系地层含水层组中含水层位与富水区精细分析问题,开展地质钻孔信息深度挖掘研究。理论分析了多种钻孔数据因素蕴含的富水信息,以东欢坨矿北二采区ⅣA含水层组为对象,开展了底板含水层组内岩性对比与含水分层定位,划定了富水区域。结论认为:充分利用地质钻孔信息,弥补抽水试验孔不足的缺陷,基于岩性、厚度与连续性、被上下隔水层限制的情况、岩芯裂隙与溶隙描述、泥浆漏失量是否偏大及是否抽水试验层段等钻孔信息,能够划定含水分层且更准确划定富水区,为疏放水钻孔的终孔目标层位及设孔位置选择提供具有实际意义的指导。

超大直径泥水平衡盾构气垫仓吸口改造技术研究

广东省广州市海珠湾隧道超大直径泥水平衡盾构穿越泥质粉砂岩复合地层,刀盘前以及密封仓中积渣滞排导致掘进参数恶化、刀具磨损严重、掘进效率受限、刀盘开口结泥饼等问题。针对超大直径泥水平衡盾构在复合地层中遇到的滞排问题,提出将P2.1泵吸口前移至泥浆门后方,增加了排浆吸口吸力,增强了浆液流动性及携渣能力,同时于P2.1泵前安装双管路液压闸阀采石箱,使大粒径渣土在P2.1泵前得以处理。气垫仓吸口改造后盾构掘进工效有所提升,对于改善刀盘前方以及泥水仓底滞排有一定效果,但由于鄂式破碎机无法动作,当掘进断面地层岩体较破碎、节理裂隙较发育时,极易发生吸口处渣土堆积、P2.1泵吸口压力突然降低、流量突然减少、挤压力上升、切口压力波动等情况,需频繁逆冲洗和开采石箱进行人工清理,进而影响了正常掘进环流,最终被迫恢复吸口及鄂式破碎机功能。相关研究成果可为同类工程提供参考。

叶轮结构对渣浆泵性能影响的数值与试验分析

作为输送煤炭的重要设备,渣浆泵在煤矿、燃煤电厂等化石能源领域得到了广泛应用,渣浆泵性能的提高可以有效降低化石能源行业的能源损耗。提出了一种具有分流叶片结构的新型叶轮,对不同叶轮结构的渣浆泵内部流场展开了分析;根据渣浆泵内旋涡的形状和结构,运用Q准则将旋涡分为前缘旋涡、后缘旋涡和间隙泄漏涡,剖析了各旋涡的产生机理及旋涡强度与流动状态的关系;利用熵产理论研究了渣浆泵的能量损失,并探讨了不同叶轮结构在两相流工况下的压力分布。结果表明,采用分流叶片可以降低渣浆泵因熵产造成的能量损失,抑制叶轮出口处的流动分离。

6kV浆液循环泵电机定子绕组接地故障分析及预控

某600 MW火电机组6 kV脱硫浆液循环泵电机在机组降负荷后短时升负荷时,带载热态启动过程中出现速断保护动作现象,测量电机绝缘电阻为零,更换备用电机运行。通过对电机解体,发现转子鼠笼端环焊块脱落、定子绕组外绝缘破损严重,确定绕组接地造成保护跳闸,从保护定值、运行操作、规程要求、检修维护多方面分析根本原因,提出工作票及运行规程优化建议,为预控此类故障提供参考思路。

湿法脱硫浆液循环泵的优化运行

为了响应国家节能减排的政策方向,国能三河发电有限责任公司二期两台机组脱硫系统进行了设备改造,环保参数满足国家相关环保排放要求。在此前提下对脱硫系统的出力能力、具体的设备实际情况等进行分析,提出了脱硫系统优化运行的方案,实现脱硫系统单台浆液循环泵或者单母线两台小容量浆液循环泵的不同优化运行方式。该方案在实际生产中起到了节能降耗的作用,提高了设备运行可靠性。

高压变频器在华电邹县发电厂的应用

本文介绍了新风光高压变频器在华电邹县电厂的应用,在了解浆液循环泵工艺的基础上,通过变频对原工频系统的改造,说明了变频器在软启动、改善生产工艺及节能方面的巨大优势,阐明了变频器在这方面的应用前景。

基于模型预测的脱硫浆液循环泵运行组合优化研究

浆液循环泵的优化组合运行对于脱硫装置的经济运行具有重要影响,在当前机组负荷工况波动大、净烟气SO_(2)浓度排放限制严格的情况下,依靠运行人员的经验手动调节达到经济运行有较大的困难。针对这一现状,基于FIR模型辨识方法,建立了脱硫装置的数据驱动预测模型,并结合专家知识及现场设备限制研发了循环泵组合在线优化建议系统,在保障脱硫装置安全、达标运行的前提下实现优化经济运行。实际生产应用结果表明,该系统投运后可降低20.5%的浆液成本和3.7%的电耗成本,对于火电厂节能减排及智能化改造工作具有参考意义。

基于模糊C均值聚类算法的浆液循环泵节能运行优化方法研究

在浆液循环泵运行阶段,受客观应用需求波动的影响,其功耗相对较高。为此,提出基于模糊C均值聚类算法的浆液循环泵节能运行优化方法。在浆液循环泵运行数据特征提取阶段,采用基于无监督的深度学习模型,借助随机初始化的卷积核,对输入的数据进行卷积计算,获取低维空间的特征映射,随后通过反卷积确定浆液循环泵运行参数特征;在节能运行优化阶段,引入模糊C均值聚类算法,通过聚类具有相同特征的数据,将相同聚类内功耗最小的参数作为同类运行工况下的优化结果。结果显示,测试循环泵的功耗虽然会随着通过的最大颗粒粒度的增加而呈稳定增大的趋势,但对应的增幅较小,与对照组相比,其分别在节能程度和节能适应性方面表现出了明显优势。

Underground mining slurry transportation viability

Underground mining requires lot of water pumping to surface which increases cost. Because of safety, support, ventilation and environment costs underground mines are closing down gradually all over the world. This innovative paper is based on method studies by computer programming with realistic data. With development of electronic control systems, coal water slurry mix can be remote controlled for transport to surface Separator-bunker. Main consumers need powdered coal/mineral like thermal power stations, for feeding to Fuel Burners of boilers, generating power or in steel plants for feeding into coke ovens to make hard coke for charging into Blast Furnaces for making pig iron. Feed for coal washeries also require crushed coal and output of washed coal as slurry can be sent to coke ovens of steel plants directly. Production from mine faces should be taken through lump-breaker and conveyed to a mixing chamber, near panel sump, from where adequate capacity slurry pump will propel up to pit-top. The projected financial benefit can be several millions of Rupees per year, as compared to road, rail conveyor or winders is shown, by run of a computer program in Java, with realistic cost figures from mines.

基于碳化硅陶瓷材料的磨矿分级系统给矿泵及过流件应用试验研究

本文针对某钼选矿厂Ⅰ段磨矿分级系统给矿泵过流件使用周期短,检修频繁,维护成本高等难题,开展了基于碳化硅陶瓷材料的给矿泵及过流件工业试验研究,并对碳化硅陶瓷材料进行了磨损、腐蚀试验。试验结果表明:碳化硅陶瓷泵及碳化硅陶瓷材料过流件应用效果良好,碳化硅陶瓷材料过流件使用周期是原来给矿泵的4倍,年维护成本是原来的1/3,且稳定了渣浆泵的输送工艺,降低了泵的检修频次,大大降低了职工的劳动强度。

基于神经网络PID的疏浚管道泥浆流速控制

疏浚作业中,泥浆管道内物料的组成、粒径、浓度等随水下地形土质等变化很大,易造成流速波动甚至堵管、爆管等故障,因此泥浆流速稳定控制对泥浆输送的效率和安全具有重要意义;疏浚管道输送系统具有非线性、大时滞和参数时变等特征,传统PID控制方法效果不佳,故此将BP神经网络和传统PID控制算法相结合,并将其应用于泥浆流速控制中;以河海大学管道输送实验平台为对象,采用受控自回归CAR模型描述泥泵变频器频率与管道泥浆流速之间的关系,通过实验和数值处理对模型进行离线辨识;在此基础上通过仿真对比传统PID、单神经元PID和BP-PID的流速控制性能,发现BP-PID控制器的超调量仅为3.8%,响应时间为11 s,控制性能较好;最后通过在体积浓度-10%到-30%泥浆范围内,泥浆浓度小幅度和大幅度增减实验,对流速控制方法进行了验证,结果表明在浓度平缓或剧烈波动时,采用BP-PID控制算法的流速控制系统,均能够在保证输送安全的前提下,快速、稳定地达到目标流速,具有较好的自适应控制性能。

基于CFD-DEM方法的矿浆泵磨损特性研究

基于CFD-DEM耦合的方法,同时结合Archard磨损模型,对小流量矿浆泵在不同流量、不同颗粒粒径等工况下进行数值模拟,分析了泵内颗粒运动规律、颗粒在不同流域的分布情况以及颗粒与泵过流部件的碰撞规律,研究了矿浆泵内过流部件尤其是蜗壳的磨损特性。结果显示,蜗壳存在一定堵塞,蜗壳靠近隔舌段颗粒形成低速堵塞区,蜗壳的磨损主要集中在上半部分及隔舌附近的位置;随着流量增大,颗粒速度增大,颗粒与壁面碰撞时动能增大,矿浆泵体磨损情况增强;小粒径颗粒工况下磨损情况更严重。