Interacting Light Paths Attract KELEA (Kinetic Energy Limiting Electrostatic Attraction) and Can Lead to the Activation of Water

Water can acquire a kinetic activity, which is attributed to the absorption of an environmental force termed KELEA (kinetic energy limiting electrostatic attraction). This activity can lead to increased volatility of the water that can be measured as the progressive weight loss in closed but not completely sealed containers. It has been proposed that KELEA is a natural force required to prevent the fusion and possible annihilation of electrostatically attracted opposite electrical charges. As such, it may be especially available where there is a convergence of force fields of opposing electrical charges. At least conceptually, this may arise with facing light sources with centrally directed light beams. An oscillating attraction and release of KELEA may be facilitated by repetitively disrupting the light paths using an overhead flashing light source. This paper reports on preliminary studies that are based on this premise. Although not proving the premise, the reported experiments do indicate a simple method for activating water. Moreover, the described procedure should allow for further exploration of the underlying mechanism of water activation. The procedure involves the use of four, diagonally placed regular LED traffic lights, with an overhead strobe light. The volatility of water samples in closed but not completely sealed glass vials placed within the lighted area significantly increases in a manner that persists well beyond the periods of light exposure. The paper further shows that activated water can indirectly lead to the activation of nearby water. The reported observations are of both practical and theoretical importance.

KELEA: A Natural Energy That Seemingly Reduces Intermolecular Hydrogen Bonding in Water and Other Liquids

The alternative cellular energy (ACE) pathway was initially identified as a non-immunological defense mechanism against virus infections. It is particularly relevant to the suppression of stealth adapted viruses, which are not normally recognized by the cellular immune system. Many of the methods able to enhance the ACE pathway are consistent with the transfer of a natural energy to the body’s fluids. Additional support for this premise is provided in this paper. The vapor pressure and rate of evaporation of activated water, ethanol and gasoline increase to beyond atmospheric pressure over time. The term KELEA (kinetic energy limiting electrostatic attraction) is proposed for a natural energy that increases the volatility of fluids, seemingly through the loosening of intermolecular hydrogen bonding. KELEA activated fluids have many potential health, agricultural and industrial applications, as well as providing the opportunity for fundamental research.

KELEA Activation of Water and Other Fluids for Health, Agriculture and Industry

Water is a critical component in the functioning of the earth and of all living creatures. An important insight into the variable physical and biological properties of water has been provided by studies consistent with an external force termed KELEA (kinetic energy limiting electrostatic attraction) that weakens the intermolecular bonding of water molecules. Simple methods are described in this paper for producing and testing KELEA activated water. A summary is also provided of many major applications of KELEA activated water in health, agriculture and industry. While several of the proposed applications require more rigorous scientific documentation and further optimization, collectively they present the compelling opportunity for KELEA activated water to immediately transform medical, agricultural and industrial practices. A coordinated endeavor is proposed to better understand the science of KELEA and to develop simplified protocols for utilizing KELEA activated water and other fluids in the presently described and likely numerous additional applications. This ambitious undertaking envisions the cooperation among a range of specialized philanthropic organizations, working within different countries and with the strong support of national governments.

Tissue Regeneration without Scarring Achieved by Enhancing the Alternative Cellular Energy (ACE) Pathway

The inflammatory and fibrous responses to injuries are painful and are inhibitory to the regeneration of specialized cells. The fibrous scarring of skin injuries can also be disfiguring. Cells obtain energy not only from the metabolism of food, but also via the alternative cellular energy (ACE) pathway. The ACE pathway is reflected in a dynamic (kinetic) quality of the body’s fluids. It is postulated to result from the absorption of an environmental force called KELEA (kinetic energy limiting electrostatic attraction). The body’s ACE pathway can be enhanced by the parental administration and even the oral consumption of products comprising KELEA activated water. One of these products, termed Enercel, was originally considered a complex homeopathic remedy. Another product is water containing electrolysis-generated, copper-silver-citrate (CSC) complexes. This product was initially formulated to be bacteriocidal, especially for Gram positive bacteria. This article describes the independent successful use of each of these two products in achieving essentially painless, scar-free healing of skin injuries. The skin injuries were due to a variety of causes including: vascular insufficiency from diabetes;hot water burn;penetrating object;chronic infection;and surgical incision. It is proposed that the ACE pathway increases the resilience of cells of the innate immune system to the triggering of an inflammatory reaction by “danger signals” released from damaged tissues. KELEA activated water should be widely available for the urgent therapy of burns and other traumatic injuries to the skin. ACE pathway enhancing modalities also need to be evaluated in the repair of cellular damage occurring to the heart, brain and other internal organs of the body.

曝气-生态浮床联合技术净化河道水质效果及机理研究

为提升东减河水体质量,探究了曝气增氧-生态浮床联合技术对河道水体中氮磷及有机物的去除效果及机理.实验结果表明,联合技术对主汛期河道水体的COD去除率达到65%,总氮和磷酸盐去除率分别达到72%和46%.常规水质指标的相关性分析得出,氨氮、硝酸盐和亚硝酸盐是水体富营养化的主控因子.河道水温和藻类生长呈显著正相关,和溶解氧呈显著负相关.同时,在7—9月河道表层沉积物的有机氮和有机磷矿化释放作用增强且具有持续性.这些是造成该时段河道水质状况较差的关键因素.曝气-生态浮床联合技术既可以有效地去除河道水体中氨氮、总磷等污染物,还可以提高水体溶解氧含量,抑制水中藻类的生长.联合技术增加了河道底泥细菌群落的多样性和功能菌群的丰度,多种丰度较高的菌属与脱氮更为相关.其中脱氮功能菌有Thiobacillus、Sphingopyxis、Nitrospira、Pseudomonas、Thermomonas.除磷功能菌有Bacillus、Rhodobacter、Acinetobacter.同时检测出高丰度的黄杆菌属(Luteolibacter)是良好水质水体的指示生物.

腐殖酸-聚丙烯酸表面交联吸水性树脂的合成与性能

将交联剂N,N′-亚甲基双丙烯酰胺溶于甲醇溶液制成表面处理液,通过表面交联反应将磺化腐殖酸(HA)与聚丙烯酸(PAA)结合,制得一种适合于农林领域应用的腐殖酸-聚丙烯酸高吸水性树脂(HA-PAA).研究了表面处理液浓度、交联剂用量和腐殖酸量对HA-PAA吸水性能的影响规律和吸水机理,以及产物在沙土中的保水性能,并通过扫描电镜分析了HA-PAA的表面结构.研究结果表明,当含有10%HA时,HA-PAA耐电解质性能良好,吸水性能最佳;当沙土中添加0·2%的HA-PAA时,可明显改善沙土的贮水、保水性能.HA-PAA作为农林领域用保水剂,可发挥抗旱保墒和促进植物生长的双重作用.

用水总量控制指标的确定方法研究

基于最严格水资源管理制度的要求,用水总量控制"红线"就是要强化水资源管理的约束力,促进水资源优化配置,提高用水效率,确保水资源可持续利用。基于"用水总量控制指标确定时应考虑当地水资源特性和当地社会经济及生态环境对水的需求两方面因素"的原则,系统讨论了狭义、广义及严格意义地表(地下)水资源可利用量的概念,提出了确定用水总量控制指标的方法体系。最后以胶南市及乳山市为例,计算了两市各规划年的用水总量控制指标,为两市用水总量控制制度建设和控制指标分配提供了依据。

基于熵权的模糊综合评判法在地表水水质评价中的应用

以郑州市集中式地表饮用水源地花园口水源厂和邙山提灌站为评价对象,根据饮用水源地各监测点的实测数据以及地表水环境质量标准,通过模糊综合评判法对其水质作出了综合评价,在计算评价指标权重时运用了信息论中的熵权法,使评价结果更加客观、合理,从而为有针对性地保护饮用水源,进一步改善水质,优化水资源管理提供科学依据.

基于表观热惯量的土壤水分监测

土壤水分含量是监测农业干旱的重要指标,遥感法是大面积监测土壤水分时空特征的主要方法,热惯量法是遥感方法监测土壤水分的主要研究手段之一。本文提出了一个改进的表观热惯量模型计算表观热惯量,并通过地面验证试验对该模型的适用性进行了分析。在中国科学院栾城农业生态系统试验站,通过严格的控制试验,设计了10个不同植被覆盖、不同土壤水分含量的试验小区,针对表观热惯量的适用条件,利用实测的地表温度、植被指数、反照率、太阳辐射等参数计算了不同植被覆盖不同土壤水分含量下的表观热惯量,并与土壤体积含水量进行了相关和回归分析。结果表明:在植被覆盖度较低情况下[归一化植被指数(normalized difference vegetation index,NDVI)<0.35],表观热惯量法具有较好的效果,表观热惯量与土壤体积含水量之间的相关系数大于0.7,通过了95%的显著性检验,两者具有很高的相关性,可以用热惯量法监测土壤水分状况;在较高植被覆盖情况下(NDVI>0.35),表观热惯量与土壤体积含水量之间没有相关性,热惯量法监测土壤水分失效;NDVI为0.35可以作为热惯量法监测土壤水分状况是否可行的判断条件。

响应面法优化新型河虾调味酱感官品质

以淡水干虾为主料研制调味酱,并对其配方和工艺进行优化。河虾调味酱品质判定采用感官测评法,其中各项感官指标分值占比通过二元对比法获得。单因素试验表明,食盐、大蒜、洋葱与烤制后干虾质量比(g/g)分别为0.1,1.2,1.2时,感官评分较高。采用Box-Behnken响应面设计调味酱品质优化试验得到:当干虾烤制时长25.5min、朝天椒与干虾质量比5.05∶1(g/g)、味精与干虾质量比0.40∶1(g/g)时,此条件下酱料品质最优,感官评分预测值为77.4963,感官评分实测值为77.1。

采场底板突水的跨层应力壳力学模型

利用实验室大型非线性三维计算机数值模拟对煤层底板应力分布特征进行了深入研究,发现采场底板存在由集中应力形成的跨层应力壳,应力壳是承载上覆岩体压力的临时结构,壳基是椭球应力壳应力较集中的区域,椭球应力壳的形态及应力集中情况与采场结构有关。根据数值模拟试验得出了应力壳的形态方程,分析了跨层应力壳壳基、壳肩及壳顶的失稳模式,指出壳肩处经历联合破断,底板的最大破断深度则处于壳肩的位置,当壳肩达到最大破坏深度,采动裂隙和原始导升裂隙贯通,此时则容易形成突水;壳顶则随着高度的不断发展,跨层应力壳形成一个处于半封闭状态的半壳结构,此时采动裂隙导通煤层底板含水层,从而形成突水。

基于响应面法游湖沉积物-水界面溶解性碳交换通量

湿地作为陆地生态系统最重要的碳汇,是减缓全球大气中二氧化碳含量上升和全球气候变暖的重要途径。目前研究多针对于自然湿地中储碳量和碳密度的研究,对于因煤炭开采形成的采煤塌陷湿地碳密度及其变化研究则相对较少。基于对采煤塌陷湿地水体和沉积物中碳含量和影响因子的调查,研究采煤沉陷湿地沉积物-水界面不同形态碳交换通量规律,评估沉积物对于上覆水中碳素的源/汇特征,探讨不同环境因子单一及交互作用下沉积物-水界面各形态碳的交换通量的变化规律。针对徐州九里湖采煤塌陷湿地沉积物和水体进行研究,分别于2020年12月、2021年4月和2021年8月采集沉积物和上覆水,分析沉积物和水体中碳素的赋存特征以及影响碳素含量的关键因子。通过室内模拟试验,进行沉积物-水界面溶解性碳交换通量研究,并探讨主要环境因子对溶解性碳交换通量的影响。最后基于响应面法构建沉积物-水界面溶解性碳交换通量回归模型,预测采煤沉陷湿地溶解性碳最小释放条件,估算采煤塌陷湿地溶解性碳释放总量。结果如下:温度升高会导致溶解性碳交换通量增大,而pH对其影响较小;在高氧(9.0 mg/L)和低氧(3.0 mg/L)条件下,溶解性有机碳(DOC)和溶解性无机碳(DIC)交换通量相对较高,在中氧(6.0 mg/L)条件下,相对较小。得出在环境因子交互作用下的最优化条件,当温度为5.69℃、pH为7.18、溶解氧DO为6.38 mg/L时,DOC和DIC交换通量区的最小值分别为2.32、3.54 mg/(m^(2)·h)。估算出湿地8月沉积物DOC和DIC释放总量最高,分别为1.75、5.76 t;12月沉积物DOC和DIC释放总量最低,分别为0.98、2.01 t。结果表明,环境因子对DOC和DIC交换通量均有不同程度影响,温度通过改变吸附能力和生物活性的方式使DOC和DIC交换通量随温度增加而增大;pH影响着沉积物中碳酸盐的溶解度使得DIC在碱性环境中增加不明显,但对DOC交换通量影响较小。DOC和DIC释放总量变化规律一致,夏季温度较高,沉积物微生物活性强,促进DOC和DIC向上覆水中大量释放,冬季温度低,释放作用显著下降。沉积物-水界面溶解性碳交换通量只考虑了温度、p H和DO三个条件,然而影响物质在沉积物-水界面的迁移转化还包括沉积物自身特性、生物扰动以及重金属等因素,对于因采煤形成的湿地,沉积物中金属离子对溶解性碳的释放更应引起注意,在后面的研究中可以微生物为切入点,探究沉积物碳“源”与“汇”转换的临界条件。

长大深埋水工隧洞设计关键技术研究与实践

在分析我国长大深埋隧洞发展历程及研究现状的基础上,阐述了长大深埋隧洞工程遇到的主要工程地质问题,并结合多年积累的调水工程设计、施工、管理等经验,总结已完工及在建的高埋深长隧洞遇到的实际情况,针对突涌水、突泥和涌砂、岩爆、围岩大变形、高地温、高地应力、高外水等多种极为复杂的工程地质问题进行了分析和探讨。结果表明:在长大深埋隧洞设计前期,结合工程主要地质问题进行TBM设备选型至关重要;设计及施工过程中采用数值模拟、试验研究、超前地质预报、现场监测等手段,对高外水、软岩大变形、岩爆、高地温等不良地质洞段进行分析研究并动态调整设计;不良地质条件掘进易采用三低(低推力、低转速、低贯入度)、一快(快速掘进)、一连续(掘进)、宁慢勿停的掘进原则,可以避免国内外类似工程灾难性的后果发生。

桃林口水库分水枢纽工程对区间支流洪水影响

桃林口水库下游分水枢纽改造工程的实施,抬高了坝址处设计洪水位,顶托了石门子村支流洪水,利用一维恒定非均匀流计算方法,分析了工程改造对区间石门子村支流洪水的影响。

皖西大别山区水源涵养林质量提升关键技术研究

采用标准地调查法,对大别山水库库区水源涵养林的几个定位监测站的监测数据进行分析,对几种主要植被类型的枯落物吸水、土壤渗透性、抗蚀性、径流量等涵养水源功能以及抚育方式和空间配置与涵养水源的关系进行系统分析,探索可提升林分质量的技术措施。

三沂地区地表水资源拦蓄潜力的遥感调查研究

以三沂地区应用为例，从流域下垫面特征研究出发，阐述了利用遥感技术与信．包系统结合常规方法计算地表水资源的途径，分析了区域地表水拦蓄潜力。

高含水期微观剩余油赋存规律——以大港油田小集区块和港西区块为例

为了厘清开发后期高含水储集层内部微观剩余油分布特征,指导大港油田小集区块和港西区块油藏后续剩余油精细挖掘,利用紫外荧光体视显微镜进行观察,经图像处理后,将剩余油划分为弱波及、中波及和强波及3个级别,剩余油赋存状态划分为簇状、孔表薄膜状、狭缝状、角隅状和粒间吸附状5种。在高含水阶段,不同的剩余油赋存状态中,剩余油含量从高到低依次为簇状、孔表薄膜状、角隅状、粒间吸附状和狭缝状;聚/表复合驱后簇状剩余油和孔表薄膜状剩余油较多,后续可采用改善岩石润湿性的方法开采;砾岩剩余油分布较砂岩更加复杂,簇状剩余油和粒间吸附状剩余油较砂岩多,后续应考虑采用控制注入流体流度的方法开采。

水工混凝土建筑物抗渗性初探

主要介绍了渗漏对水工混凝土带来的一系列恶性循环危害，影响水工混凝土抗渗性的因素厦抗渗性对水工混凝土耐久性的影响等，从其影响因素阐明了对水工混凝土抗渗性研究的重要性。

表面处理技术在给排水管道防腐中的应用现状

从给排水管道的腐蚀机制出发,介绍了电镀技术、化学镀技术、涂层技术及阴极保护技术在管道防腐中的应用,旨在为合理选择管道防腐工艺提供借鉴。

砾砂层风压注浆工法研究

结合青岛地铁一期工程3号线河河区间饱水砂层浅埋暗挖隧道施工实践,在总结饱水砂层超前小导管风压注浆施工技术基础上,自创饱水砂层风压注浆工法,围岩加固满足后续工序要求,防水堵水效果显著。