Effects of Combined Instantaneous High-Pressure and Medium Temperature on Peroxidase Activity in Wax Gourd Juices

Based on the instantaneous pressurization and depressurization produced by high pressure single pole cylinder pump and valve, the effects of the continuous processing on the peroxidase (POD) activity in wax gourd juices were investigated. Results showed that the processing factors such as pressure, temperature, pH and processing time are important to the POD activity. POD in crude juices could be inactivated apparently above 50 MPa(pH 4.6, 35℃, 4 min), and activated at 20 MPa ( P < 0.01). Its remarkable inactivation could also be observed at 45 and 55℃ (20 MPa, pH 4.6, 4 min), and the evident activation appears at the material temperature 35℃ ( P < 0.01). The pH 3.0 could destroy POD almost completely (20 MPa, 35℃, 4 min), while pH 6.0 could not influence apparently the POD activity in crude juices( P > 0.05). In addition, the rules of POD activity along with the treatment time are variational under different processing pressures. The higher the treating pressure is, the shorter the processing time is needed to inactivate POD.

Effects of Combined Instantaneous High-Pressure and MediumTemperature on the Retention of Total Vitamin Cin Wax Gourd Juices

Based on the instantaneous high-pressure(IHP)produced by high-pressure single pole-cylinder pump, the effects of combining this pressure with medium temperature on the retention of total vitamin C(Vc)in wax gourd juices were investigated under 20 - 80 MPa, 35 - 58℃, pH 3. 0 - 6. 0 and processing time 0-8 min. Results showed that the loss of Vc increased with elevated processing temperatures(50 MPa, 4 min). When the temperature of raw juices was 35℃, the retention of total Vc was higher under 40 - 60 MPa than that under the pressure < 40 MPa or > 60 MPa, and it was up to 94%(4 min). The retention of total Vc decreases slowly within 6 min, but rapidly after 6 min. The pH can also influence the retention of total Vc, and this retention can come to a highest point at pH 6.0.

Coupling of Wind Energy and Biogas with a High Temperature Steam Electrolyser for Hydrogen and Methane Production

The production of environment friendly green fuels is based on energy from renewable sources. Among the renewable sources, wind power is a very growing power technology. An example which has been discussed very widely is hydrogen which is an ideal fuel for a fuel cell. Hydrogen is the energy of the future. It will be used as energy carrier as well as reactant to produce green fuels, like methane which is easier to handle. Direct coupling of a High Temperature Steam Electrolyser (HTSE) with a wind turbine can be used to generate hydrogen. Indeed performing the electrolysis process at high temperatures offers the advantage of achieving higher efficiencies compared to the conventional water electrolysis. The hydrogen produced can be then reacted with the CO2 content of biogas to form methane as green fuel. Thus, the concept presented in this paper illustrates the potential of the HTSE technology coupled with a wind turbine, this system being combined with biogas in a methanation unit. Developing scenarios and flow sheets and using mass and energy balance, the technical performance of the concept is investigated. A plant capacity of 10 MWel is considered. An annual production of 1104 metric tons per year (Mt/a) hydrogen and thus of 5888 Mt/a methane is reached. The overall plant efficiency is calculated to be 38%. The combination of wind power and biogas offers thus many advantages which can facilitate the penetration of the wind resource and the progression to the hydrogen economy.

Methane Production via High Temperature Steam Electrolyser from Renewable Wind Energy: A German Study

The transformation of the energy supply needs further development of energy storage technologies in order to integrate the fluctuating renewable energy. The conversion of renewable wind power into green methane offers a technical approach with the necessary storage and transport capacities. Thus, the concept of Power-to-Gas which is illustrated here by the coupling of wind energy with a High Temperature Steam Electrolyser (HTSE) and a methanation unit enabling the production of green fuel like hydrogen and methane is presented is this paper. In fact, hydrogen can be used as energy carrier as well for the production of green fuels, like methane which is simpler to store and to transport and which can be thus used as storage medium for the stabilization of the electrical power supply as well as fuel for transport and heat sector. Its production using high temperature electrolysis is able to reduce the carbon dioxide emissions if performed with renewable resources. This is the case if the electricity needed for the HTSE comes from a wind turbine and the CO2 needed for the methanation step comes from biogas. For such a plant, the location and the boundary conditions have a great importance. Thus, this study considers the coupling of a HTSE with a wind turbine and a methanation reactor, and focuses about the site selection, depending of the geographical and economic considerations. The study is limited first to the European area. Schleswig-Holstein is found as a very good location for this plant. It is one of the regions with the largest wind reserves in Germany. This region has also available a lot of biogas and meets all the other necessary requirements.

Oxidation behaviors of wrought nickel-based superalloys in various high temperature environments

Oxidation characteristics of Alloy 617 and Haynes 230 at 900 oC in simulated helium environment,hot steam environment containing H2 as well as in air and pure helium conditions were investigated.Compared to air condition,the oxidation rate of Alloy 617 was not significantly affected in helium and hot steam environments,while Haynes 230 showed lower oxidation rate in helium environment.On the other hand,the oxide morphology and structure of Alloy 617 were strongly affected by the environments,but those of Haynes 230 were less dependent on the environments.For Haynes 230,a Cr2O3 inner layer and a protective MnCr2O4 outer layer were formed in all environments,which contributed to the better oxidation resistance.As the mechanical properties,such as creep and tensile properties,were significantly affected by the oxidation behaviors,surface treatment methods to enhance oxidation resistance of these alloys should be developed.

Modeling of Packed Bed Methanol Steam Reformer Integrated with Tubular High Temperature Proton Exchange Membrane Fuel Cell

This work proposes a novel tubular structure of high-temperature proton exchange membrane fuel cell(PEMFC)integrated with a built-in packed-bed methanol steam reformer to provide hydrogen for power output.A two-dimensional axisymmetric non-isothermal model was developed in COMSOL Multiphysics 5.4 to simulate the performance of a tubular high temperature proton membrane fuel cell and a packed bed methanol reformer.The model considers the coupling multi-physical processes,including methanol reforming reaction,water gas shift reaction,methanol cracking reaction as well as the heat,mass and momentum transport processes.The sub-model of the tubular packed-bed methanol reformer is validated between 433 K and 493 K with the experimental data reported in the literature.The sub-model of the high temperature proton exchange fuel cell is validated between 393 K and 433 K with the published literature.Our results show that power output and temperature distribution of the integrated unit depend on methanol flow rates and working voltages.It was suggested that stable power generation performance of 0.14 W/cm_(2)and temperature drop in methanol steam reformer of≤10 K could be achieved by controlling the methanol space-time ratio of≥250 kg·s/mol with working voltage at 0.6 V,even in the absence of an external heat source.

高温气冷堆热态功能试验中一回路加热动态特性研究

高温气冷堆反应堆压力容器堆内构件由石墨和碳化硼烧结陶瓷材料组成,热态功能试验过程中需对一回路堆内构件进行加热除湿。针对高温气冷堆一回路热试系统特点,采用COMSOL Multiphysics 5.4计算软件构建了压力容器、蒸汽发生器和主氦风机三维数值模型,并通过示范工程加热试验值验证了模型的可靠性,并获得了一回路加热过程中温度场动态特性。为了解决高温气冷堆示范工程一回路首次加热效率低的问题,提出了将辅助蒸汽通入到蒸汽发生器,并动态调整辅助蒸汽运行参数来加热一回路氦气的方法,结果表明:相较于主氦风机单独加热方式,外加辅助蒸汽热源可节省加热时间约31.3 h,同时可将堆芯最终平衡温度由250℃提高至265℃;在满足运行准则的前提下,更有利于碳砖和石墨堆内构件的除湿。该研究结果为高温气冷堆一回路热试提供了有力支持。

定子通风槽钢结构对提高中型高压电机散热性能分析

为降低YJK450-6、400kW中型高压电机的通风散热性能,本文对该电机不同通风槽钢结构进行了散热性能研究。首先,在现有电机的直线标准型通风结构基础上,提出单列缩放型、双列直线型、双列缩放型3种轴-径向混合通风结构形式;在SpaceClaim软件中建立电机3维温度场数值计算模型,根据基本假设和边界条件结合电机内部热量传递公式计算出电机仿真设置参数,并导入Fluent软件进行仿真模拟,其中,计算温度场所用热源通过AnsoftMaxwell平台计算的电机损耗值获取。其次,通过网格无关性和温升试验验证本文建立的电机3维温度场数值计算模型;通过仿真模拟对比分析3种轴-径向混合通风结构与直线标准型结构对电机流场和温度场的影响;采用正交试验法对轴-径向混合通风结构进行参数优化,得到最佳散热结构和参数方案;进一步探究冷却风速对双列缩放型槽钢的电机换热性能的影响;结合定子绕组温升和电机整体的温升均匀性系数,对最佳散热结构和参数方案电机进行散热效果评价。仿真结果表明:本文建立的计算模型是有效的;双列缩放型通风槽钢结构的各项散热性能指标均最好,是最优通风槽钢结构;径向风道高度为6mm且数量为13的双列缩放型通风槽钢结构为最佳散热结构和参数方案;双列缩放型通风槽钢结构两侧的平均对流换热系数随冷却风速增大而增大,且槽钢迎风面的平均对流换热系数明显大于背风面;径向风道高度为6mm且数量为13的双列缩放型通风槽钢结构电机的内/外层绕组温升分布均匀性系数比直线标准型电机分别提高88.13%、20.11%。因此,优化设计通风槽钢结构有利于电机内部空气流动和散热,可实现有效降低电机内部温升的目的。

双碳目标下高温气冷堆替代中小型火电的思考

碳达峰碳中和是我国一项重要的国家战略决策,“双碳”目标的提出给能源行业带来了深刻的变革,我国能源结构将进一步优化,电力行业必须实现低碳转型,新能源取代火电已成为必然。本文分析了新形势下火电企业面临的巨大挑战、发电规模受到限制、经营成本不断上升,尤其是中小型火电机组,面临着淘汰和关停的局面,而高温气冷堆具有固有安全性、发电效率高、用途广泛的显著特点,使其替代中小型火电成为可能。本文通过厂址适应性、技术可行性、经济可行性三方面,分析了高温气冷堆替代中小型火电的可行性,并从相关法律法规适用性、内陆厂址所带来的问题、开展公众沟通等方面提出建议。

HTR-PM汽轮机轴封蒸汽断供原因分析及解决方案

介绍了高温气冷堆示范工程(HTR-PM)汽轮机轴封系统,并且对轴封蒸汽断供的原因进行了分析,提出了可以采用蒸汽发生器及管道内余汽供轴封、辅助电锅炉至轴封供汽管道改造、高温空气供轴封这3种解决方案。对3种方案进行对比,分析其在成本、可靠性和运行限制方面的优缺点,结果表明3种方案均是可行的。研究结果为HTR-PM汽轮机轴封蒸汽断供问题的解决提供了参考。

高温蒸汽养护复掺混凝土力学性能时变特性与模型研究

为研究高温蒸汽养护下粉煤灰-矿粉机制砂混凝土(简称复掺混凝土)力学性能时变特性与模型,本文结合某高速公路高温蒸汽养护复掺混凝土预制梁项目,设计了蒸汽-标准养护、蒸汽-自然养护和标准养护三种养护方式,测试了不同阶段复掺混凝土的抗压强度、劈裂抗拉强度和弹性模量,探究了抗压强度与劈裂抗拉强度、弹性模量的关系。结果表明:合适的蒸汽养护方式能促进复掺混凝土抗压强度、劈裂抗拉强度和弹性模量更快增长,其中对抗压强度形成作用最显著,后期的力学性能不倒缩;蒸汽养护恒温阶段复掺混凝土的力学性能具有最大的增长率,其次是升温阶段,降温阶段力学性能增长率最小;蒸汽-标准养护方式下复掺混凝土的抗压强度时变模型可取对数或对数与幂函数复合函数,劈裂抗拉强度、弹性模量时变模型可取幂函数。

中高温大曲发酵中小麦籽粒营养组分的动态变化分析

该研究利用离子色谱和高效液相色谱等方法,研究了中高温大曲不同发酵时期小麦营养成分的变化及其与微生物群落演替间关系。结果表明,曲皮和曲心分别消耗了直链淀粉含量的39.08%和49.12%,支链淀粉含量的84.43%和81.35%,A型淀粉粒的6.41%和26.92%,B型淀粉粒的66.67%和83.33%。麦谷蛋白含量从8 mg/g降为4.73 mg/g(曲皮)和3.53 mg/g(曲心)。黄酮含量从0.08 mg/g增加到0.12 mg/g(曲皮)和0.29 mg/g(曲心)。纤维素含量总体呈下降趋势,但曲心后期有平缓上升;阿拉伯糖和蔗糖含量增加,葡萄糖含量降低。曲心游离氨基酸含量增加幅度高于曲皮,其中谷氨酸含量最高。冗余分析表明18个品质指标与9个细菌属和11个真菌属的相对丰度显著相关(P<0.05),其中直链淀粉含量与叶杆菌属(Phyllobacterium),葡萄糖、果糖、支链淀粉含量与醋酸单胞菌属(Acetobacter)、双杆菌属(Undibacterium)、乳杆菌属(Lactobacillus)均显著正相关。因此,具有高支链淀粉和高葡萄糖含量的小麦品种可能更适用于制曲。该研究结果为探究大曲质量控制、小麦品质与大曲品质间关系,以及选育专用型原料(小麦)品种提供参考。

高温蒸煮结合蜗牛酶法改性葡萄皮不溶性膳食纤维工艺优化及体外降血糖作用

以葡萄皮为原料,采用高温蒸煮结合蜗牛酶法对葡萄皮不溶性膳食纤维(insoluble dietary fiber,IDF)进行改性处理,旨在提高可溶性膳食纤维(soluble dietary fiber,SDF)得率以及改善SDF和IDF的理化性质。研究不同因素对SDF得率的影响,并对改性前后的膳食纤维进行理化指标的测定。结果表明,适宜的改性工艺条件为:蒸煮时间60 min、蒸煮温度120℃、料液比1:25 g/mL、酶添加量3.50%、酶解温度34.0℃、酶解时间55 min,此工艺下SDF得率为10.25%。改性后SDF的持水力、持油力、膨胀力相比改性前SDF分别提高了1.74、1.53、1.13倍,改性后IDF的持水力、持油力、膨胀力相比改性前IDF分别提高了1.01、1.26、1.27倍。与未改性的SDF和IDF相比,改性后的SDF和IDF的结构变得更加疏松,且葡萄糖吸附能力、葡萄糖透析延迟指数和α-淀粉酶的抑制作用均显著(P<0.05)提高,其中改性后的SDF的葡萄糖吸附能力最强,葡萄糖透析延迟指数也均高于其它膳食纤维样品,在8 mg/mL时对α-淀粉酶的抑制率达到最大值(54.71%)。综上,高温蒸煮结合蜗牛酶法改性的葡萄皮SDF和IDF具有更为良好的特性,为改性葡萄皮膳食纤维提供了理论依据。

不同品种小麦中温大曲真菌群落多样性及其品质分析

该研究采用相关国标法测定5个品种小麦的主要品质指标,采用高通量测序技术分析5种小麦中温大曲的真菌菌群多样性,并对其感官品质和理化特性进行测定比较,进一步考察小麦主要品质指标、大曲理化特性与主要真菌属间的相关性。结果表明,中筋小麦中温大曲具有较高的感官综合评分、优良的理化特性和最高的真菌菌群丰富度。从5种小麦中温大曲中共注释到3个优势真菌门和12个优势真菌属,共有的主要优势真菌属为嗜热真菌属(Thermomyces)、曲霉属(Aspergillus)、伊萨酵母属(Issatchenkia)、Cutaneotrichosporon和假丝酵母属(Candida)。中筋小麦大曲含有丰度较为均衡的4种共有优势真菌属,而粉质率高的强筋小麦大曲含有最低丰度的曲霉属。8个优势真菌属与大曲理化特性存在一定相关性;小麦粗蛋白和湿面筋含量显著正相关于枝孢属(Cladosporium)(P<0.05),而显著负相关于Apiotrichum、节担菌属(Wallemia)、未分类的小囊菌科(unclassified_f_Microascaceae)及子囊菌门(unclassified_p_Ascomycota)(P<0.05),淀粉含量与优势真菌属的相关性则与上述相反,粉质率也影响部分真菌属。

临沂和周口地区中高温大曲细菌群落结构与基因功能差异性研究

为明确山东临沂和河南周口地区中高温大曲细菌群落结构及菌群基因功能的差异,本研究采用MiSeq高通量测序技术对2个地区中高温大曲的细菌群落结构进行了解析,并基于直系同源蛋白数据库(clusters of orthologous groups of proteins,COG)分析了其细菌类群潜在的功能。α多样性发现,两者在丰富度和多样性上差异均不显著(P>0.05)。相较于周口地区大曲,在门水平上,临沂地区大曲中放线菌门(Actinobacteria)和拟杆菌门(Bacteroidetes)平均相对丰度均显著偏低(P<0.05),在属水平上,不动杆菌属(Acinetobacter)平均相对丰度显著偏高(P<0.05),地杆菌属(Geobacter)和泛菌属(Pantoea)平均相对丰度均显著偏低(P<0.05)。LEfSe(linear discriminant analysis effect size)分析发现,Geobacter为周口地区大曲中的生物标志物,而临沂地区大曲中的生物标志物未在属水平体现;β多样性发现,两者在整体上存在明显差异;PICRUSt(phylogenetic investigation of communities by reconstruction of unobserved states)分析发现,临沂地区中高温大曲在转录、氨基酸和核苷转运与代谢功能上显著高于周口地区大曲(P<0.05)。由此可见,2个地区中高温大曲的细菌群落结构及菌群基因功能表达均存在明显差异。

高温高盐水中月桂酰胺丙基羟磺基甜菜碱在砂岩表面吸附规律研究

月桂酰胺丙基羟磺基甜菜碱表面活性剂在高盐含量水中具有较好的起泡性能,但在砂岩表面的吸附量尚不明确。本文利用Shim-pack VP-ODS 4.6 mm×250 mm色谱柱、紫外检测器,优化了流动相组成、流速、柱温等色谱条件,建立了高盐水中月桂酰胺丙基羟磺基甜菜碱的高效液相色谱检测方法。吸附性评价表明:温度为110℃、NaCl质量浓度为25×10^(4) mg/L的水中,质量分数小于1%的月桂酰胺丙基羟磺基甜菜碱在80~100目石英砂表面吸附量小于2 mg/g;在温度为110℃、水中NaCl质量浓度为(20~25)×10^(4) mg/L条件下,质量分数为0.4%月桂酰胺丙基羟磺基甜菜碱在80~100目石英砂表面吸附量随溶液中NaCl含量的增加而增加;在110℃、水中NaCl质量浓度为22.5×10^(4) mg/L、CaCl_(2)质量浓度为(0~3)×10^(4) mg/L条件下,质量分数为0.4%的月桂酰胺丙基羟磺基甜菜碱在80~100目石英砂表面吸附量随溶液中CaCl 2含量的增加而降低。研究结果对高温高盐水中甜菜碱表面活性剂的选择与应用有指导作用。

锆合金表面高温抗氧化涂层的研究进展

锆合金因其热中子吸收截面小、热膨胀系数低,以及与UO2良好的相容性而成为当前核反应堆中主要的构件材料。然而,在高温蒸汽氧化环境中,锆合金会快速氧化失效,并产生大量氢气,从而引发氢爆炸。为了提高核反应堆的安全性,对锆合金表面进行强化形成高温抗氧化防护涂层,是解决这一难题的有效途径。本文介绍了锆合金表面高温氧化行为,重点综述了高温抗氧化涂层(包括金属涂层、陶瓷涂层以及复合涂层)的氧化行为和失效机理,对比分析了不同锆合金表面涂层高温氧化性能。另外,还对锆合金表面高温抗氧化涂层的多元素成分设计、制备方法和梯度结构设计的发展方向进行了展望。

竹复合材料制备牙科纤维桩灭菌前后的力学性能变化及生物相容性研究

背景竹纤维是一种产量丰富的天然植物纤维,其力学性能可与玻璃纤维相媲美,是一种临床应用前景广阔的生物材料。目的研发一种低模量高强度的竹纤维复合材料作为牙科纤维桩材料。方法采用树脂传递模塑法制备竹纤维复合材料,将竹纤维复合材料随机分为两组,分别用于力学性能实验和生物相容性实验。力学性能实验分为对照组和灭菌组,对照组未灭菌,灭菌组通过121℃和2.2 MPa的高压灭菌器灭菌30 min。高精度微力学试验机分析灭菌前后竹复合材料的力学性能变化和断裂形式的荷载-位移曲线变化。扫描电子显微镜观察灭菌前后竹复合材料的表面形貌和断裂形貌。生物相容性实验包括CCK-8细胞毒性实验、细胞周期和凋亡实验、溶血实验。CCK-8细胞毒性实验分为阴性对照组、空白对照组和浸提液组,阴性对照组为正常培养基培养的细胞,空白对照组为无细胞的正常培养基,浸提液组为制备不同浓度(25%、50%、75%、100%)的竹纤维复合材料浸提液;细胞周期实验分为阴性对照组和处理组,阴性对照组为正常培养基培养的细胞,处理组为100%浓度的浸提液;细胞凋亡实验分为对照组和处理组,对照组为正常培养基培养的细胞,处理组为100%浓度的浸提液;溶血试验为实验组、阴性对照组和阳性对照组,实验组为100%浓度的浸提液,阴性对照组为0.9%氯化钠注射液,阳性组为蒸馏水,进一步验证竹纤维复合材料的生物相容性。结果未灭菌的对照组与灭菌组相比,弯曲模量[(9±2)GPa vs(11±4)GPa]和弯曲强度[(498±95)MPa vs(496±30)MPa]差异均无统计学意义(P>0.05)。载荷-位移曲线显示,未灭菌的对照组相比灭菌组有较好的断裂模式,未灭菌的对照组呈梯度破坏,灭菌组呈脆性断裂。扫描电镜显示,未灭菌的对照组和灭菌组的纤维和树脂表面形貌结合较好;未灭菌的对照组的断裂形貌为纤维拔出,灭菌组的断裂形貌为树脂基体的整体断裂。CCK-8结果显示,在短期内竹纤维复合材料100%浓度的浸提液吸光度值与阴性对照组相比,差异有统计学意义(P<0.01),100%浸提液的增殖能力最强。细胞周期结果显示,100%浓度的浸提液在第5天有较好的细胞增殖周期,与阴性对照组相比,差异无统计学意义(P>0.05)。细胞凋亡结果显示,100%浓度的浸提液在第5天无诱导细胞凋亡的作用,与阴性对照组相比,差异无统计学意义(P>0.05)。溶血试验表明,实验组竹纤维复合材料浸提液的溶血率为2.69%,溶血率<5%,与阳性对照组相比,差异有统计学意义(P<0.01)。结论灭菌前后的竹纤维复合材料力学性能相对稳定,且该复合材料具有良好的生物相容性,具有制备牙科纤维桩材料的潜力。

核电站蒸汽发生器传热管电磁超声导波自动化检测系统设计

蒸汽发生器传热管作为高温气冷堆核电站一回路压力边界的关键部件,承担着热交换及辐射屏障的重要作用,其结构完整性严重影响核电安全运行。针对该类特殊结构传热管的在役检查难题,设计了专用的电磁超声导波自动化检测系统,研制了内置单点检测式的磁场增强型电磁超声导波探头,开发了采用模块化组件的五轴联动多自由度自动运载装置,提出了基于机器视觉的管孔动态定位方法,建立了蒸汽发生器全尺寸模拟体试验平台并开展了定位精度测试与缺陷检测试验。试验结果表明所设计的自动化检测系统可实现任意位置目标管孔的高精度定位及自动行走,可识别模拟体上异种钢焊缝处与距离检测端约60 m处的刻槽缺陷,有效检测范围覆盖传热管全长,有望为高温气冷堆核电站蒸汽发生器特殊结构传热管的质量健康评价提供技术支撑。

生态环境视域下基层医院医疗废物处理研究

医疗废物含有大量的病毒、致病微生物以及化学药剂等,若直接排放对生态环境污染性大。因此,文章研究一种生态环境视域下基层医院医疗废物处理方法。该方法采用高温高压蒸汽灭菌与热解气化联合技术,对医疗废物进行前处理和深度处理。通过此法,废物中的病毒、致病微生物及化学药剂得到有效消减。研究结果表明,处理后二噁英含量显著降低,符合国家标准,杀菌率高达90%以上。这不仅验证了联合处理技术的有效性,也显示了对生态环境的保护作用。此方法为基层医院处理医疗废物提供了新的解决方案,有助于减少环境污染,促进生态平衡。