Data from Twenty-Three FRB’s Confirm the Universe Is Static and Not Expanding

Fast Radio Bursts from far away galaxies have travelled through the IGM and provide a tool to study its composition. Presently there are 23 FRB’s whose host galaxies have been identified and the redshift found. This gives us the opportunity to test Dispersion Measure versus redshift predictions made by two models. The Macquart relation for an expanding Universe and the New Tired Light relationship in a static universe. In New Tired Light, redshifts are produced when a photon is absorbed and re-emitted by the electrons in the IGM which recoil on both occasions. Some of the energy of the photon has been transferred to the kinetic energy of the recoiling electron. The photon has less energy, a lower frequency and a longer wavelength. It has been redshifted. Since dispersion is due to an interaction between radio signals and these same electrons one would expect a direct relationship between DM and redshift in the New Tired light model. The relation is DM=(mec/2hre)ln(1+z)and contains no adjustable parameters—just a combination of universal constants related to the electron and photon. Notice that the relation is independent of the electron number density ne since a change in ne affects both the DM and redshift equally. A graph of DM versus ln(1 + z) will be a straight line of gradient (mec/2hre)and, using SI units, substituting for the constants gives 7.318 × 1025 m−2. Using the data from the 23 well localized FRB’s, with the weighting of the DM’s for expansion removed (so that the data corresponds to a static universe), a graph of DM versus ln(1 + z) has a gradient of 6.7 × 1025 m−2—9% below the predicted (mec/2hre). The Macquart relation involves highly processed data and adjustable parameters to allow for “dark energy” and “dark matter” (neither of which has yet been found) and can be reduced to DM = 850z (in units of pc∙cm−3). Using the data from this set of localized FRB’s gives a trendline with gradient 1.10 × 103 pc∙cm−3—almost 30% higher than that predicted in an expanding universe model. The FRB data clearly comes down in favour of a static universe rather than an expanding one. Combining the DM-z relationship for the 23 well localized FRB’s, with the Hubble diagram, drawn using the NED-D compilation of redshift independent extragalactic distances, produces a value of “ne” the mean electron number density of the IGM, of ne=0.48 m−3close to the value ne=0.5 m−3, long since predicted by NTL.

Application of high-pressure water jet technology and the theory of rock burst control in roadway

This paper puts forward using high-pressure water jet technology to control rock burst in roadway, and analyzes the theory of controlling rock burst in roadway by the weak structure zone model. The weak structure zone is formed by using high-pressure water jet to cut the coal wall in a continuous and rotational way. In order to study the influence law of weak structure zone in surrounding rock, this paper numerically analyzed the influence law of weak structure zone, and the disturbance law of coal wall and floor under dynamic and static combined load. The results show that when the distance between high-pressure water jet drillings is 3 m and the diameter of drilling is 300 mm, continuous stress superposition zone can be formed. The weak structure zone can transfer and reduce the concentrated static load in surrounding rock, and then form distressed zone. The longer the high-pressure water jet drilling is, the larger the distressed zone is. The stress change and displacement change of non-distressed zone in coal wall and floor are significantly greater than that of distressed zone under dynamic and static combined load. And it shows that the distressed zone can effectively control rock burst in roadway under dynamic and static combined load. High-pressure water jet technology was applied in the haulage gate of 250203 working face in Yanbei Coal Mine, and had gained good effect. The study conclusions provide theoretical foundation and a new guidance for controlling rock burst in roadway.

Mechanism of rock burst caused by fracture of key strata during irregular working face mining and its prevention methods

To study the occurrence mechanism of rock burst during mining the irregular working face,the study took irregular panel 7447 near fault tectonic as an engineering background.The spatial fracture characteristic of overlying strata was analyzed by Winkler elastic foundation beam theory.Furthermore,the influence law of panel width to suspended width and limit breaking span of key strata were also analyzed by thin plate theory.Through micro-seismic monitoring,theoretical analysis,numerical simulation and working resistance of support of field measurement,this study investigated the fracture characteristic of overlying strata and mechanism of rock burst in irregular working face.The results show that the fracture characteristic of overlying strata shows a spatial trapezoid structure,with the main roof being as an undersurface.The fracture form changes from vertical‘‘O-X"type to transverse‘‘O-X"type with the increase of trapezoidal height.From the narrow mining face to the wide mining face,the suspended width of key strata is greater than its limit breaking width,and a strong dynamic load is produced by the fracture of key strata.The numerical simulation and micro-seismic monitoring results show that the initial fracture position of key strata is close to tailgate 7447.Also there is a high static load caused by fault tectonic.The dynamic and static combined load induce rock burst.Accordingly,a cooperative control technology was proposed,which can weaken dynamic load by hard roof directional hydraulic fracture and enhance surrounding rock by supporting system.

变区段煤柱工作面诱冲机理及防治技术研究

针对某矿变区段煤柱工作面开采冲击危险性较高的问题,运用数值模拟方法对工作面采掘过程中煤柱区域垂直应力分布规律进行研究,分析了不同宽度区段煤柱应力积聚特征,揭示了变区段煤柱工作面诱冲机理,并制定了“近场-远场”协同卸压方案。研究结果表明,较宽的区段煤柱(30 m和55 m)受采空区侧向支承压力和超前支承压力影响,煤柱应力集中程度较高;受“近场高静载+远场动载”叠加影响,变区段煤柱工作面回采期间易诱发冲击地压;采取近场高承压煤体强卸压+远场高位坚硬顶板超前预裂断顶卸压协同控制方案后,微震能量事件始终维持在104J以下,表明控制方案能够有效降低工作面采掘期间的冲击危险性。

3D网布包覆仪表板乘客侧气囊静态点爆与外观质量的控制措施

3D网布包覆仪表板以其产品轻量化、零件开发周期短、表皮颜色纹理切换自由度高等自身优势,近年来被新能源汽车所青睐,并广泛应用。对这一兴起的新型热压包覆仪表板,进行外观质量的有效控制来满足客户对内饰质量越来越高的需要,便显得尤为重要。

矿震诱发冲击地压机理研究

根据弹性波理论推导出矿震产生的应力波诱发动力扰动的公式,建立冲击地压理论模型从而推导出冲击地压发生的发生理论;并利用ABAQUS数值模拟技术模拟了矿震诱发冲击地压的过程;并探究围岩巷道受到静—动荷载叠加作用时,冲击地压的发生条件;根据现实中某矿矿震引发的冲击地压测得的数据,验证了矿震诱发冲击地压这一理论。模拟结果表明,当围岩巷道受到的地应力静载过大,达到临界塑性区时,微小的矿震会引发围岩巷道出现冲击地压现象。

小庄煤矿冲击地压分源解危措施及效果分析

针对冲击地压难以精准防治的问题,结合动静组合叠加理论,开展了分源监测,提出了冲击地压危险源层次化监测和分源解危措施,即对煤岩破断之后所萌生的动载荷监测工作,需要借助微震法对全矿井实施监测。同时借助地音法对重点工作面实行监测,借助应力在线监测的方法以及钻屑法抽样监测的方法,实现局部危险区域内的煤体静载荷全面监测。基于检测结果,制定了针对掘进工作面迎头及顶煤的冲击地压解危方案并在现场进行了实施。结果表明:采掘扰动是诱发冲击地压发生的重要因素,采用冲击地压解危方案后,钻屑平均值分别由卸压前的2.44、2.26 kg/m降低至1.98、1.87 kg/m,起到了明显的卸压效果,为合理防治冲击地压提供了思路。

基于地震波CT探测的冲击地压危险性评价与防治

为了解决工作面回采过程中存在的冲击危险区域的不确定性和煤岩体内部静载荷分布的模糊性,采用地震波CT探测技术,对回采工作面采取静载荷探测和冲击危险性评估,对冲击危险区域进行了重新确定,并制定了有针对性的卸压方案,提高了工作面回采期间的冲击地压防治效果。结果表明,小庄煤矿40302工作面回采期间,发现中等危险区域共9处,弱危险区域14处,其他区域为无冲击危险区域。通过采用地面L型水平井分段压裂技术、煤层大直径卸压钻孔、煤层爆破及顶板预裂爆破技术对冲击危险区域进行卸压,有效降低了工作面回采期间的冲击风险,为工作面安全回采提供了保障。

厚硬顶板刀把形采空区下综放工作面冲击地压机制研究

不规则的开采空间结构可增大煤矿冲击地压危险,研究多煤层复杂开采空间结构下工作面冲击机制对煤炭资源安全采出具有重要意义。综合采用理论分析、数值模拟、现场监测等方法,研究了某矿井W1123综放工作面的动静载分布特征,分析了冲击显现机制,提出了针对性的防冲措施并进行现场应用。结果表明,上覆刀把形采空区和厚硬顶板综合作用下W1123工作面动静载分布具有区域性特征,当工作面仅受到刀把形采空区的“刀柄”作用或同时受“刀柄”和“刀身”作用时,工作面中下部和区段煤柱静载集中、动载扰动剧烈,工作面回风巷围岩也存在动静载集中,且距离刀把形采空边界越近则围岩动静载越高;仅受“刀身”作用时,工作面回风巷围岩静载集中受动载扰动。工作面静载集中区和动载扰动区重合,动静载叠加造成冲击显现。依据刀把形采空区结构特征,W1123工作面回采期间冲击类型依次为强动载型、高静载强动载型、高静载型。数值模拟和现场监测揭示的冲击危险区与理论分析结果一致。针对W1123工作面静动载分布特征,优化设计了冲击地压防治措施,增大了厚硬顶板处理高度和破碎程度、增加了工作面运输巷煤体爆破和煤柱切顶以降低顶板和煤体应力和能量集中;优化措施实施后,工作面微震事件日均能量总体下降54%,大能量事件大幅减少,冲击地压危险显著降低。该研究结果可为相似条件矿井的冲击地压防治提供借鉴。

深井断层切割煤柱冲击地压防治实践

针对大采深影响下断层切割煤柱区域冲击地压防治难题,采用理论分析、现场实测方式对断层切割煤柱区域冲击危险性进行了分析与研究,得到如下结论:断层切割煤柱区域在静载条件下趋近于失稳状态,推采过程中动静载应力叠加,煤柱冲击危险性升高;通过断层切割煤柱失稳模型和现场微震、应力及其它数据监测分析发现,工作面初采阶段及单、双工作面见方阶段,微震能量积聚显著,应力集中区域明显,在此过程中断层切割煤柱存在整体失稳现象,通过大直径钻孔卸压、爆破预裂顶板及加强支护等冲击地压防护措施加强对此区域的冲击地压监测与防治,实现断层切割煤柱区域的安全回采。

基于集中静载荷探测的冲击地压危险性预评价

为了解工作面冲击危险状态,提前采取防冲措施,降低后期防治强度,理论分析了集中静载荷与冲击地压发生的相关性,建立了基于集中静载荷探测的冲击危险性预评价模型,并开展了实践验证。结果表明:集中静载荷在冲击地压启动过程中起主导作用,并可在工作面开采前探测并卸载;区域性集中静载荷可通过地震波法探测得出,基于地震波参数建立的冲击危险性预评价模型能够对工作面危险性做出评价,并且能够指导预卸压工作实施和检验解危效果。

缓倾斜煤层临空巷道冲击地压防治研究

针对在缓倾斜煤层中工作面临空侧巷道的冲击矿压问题,研究分析了影响临空侧巷道冲击地压的主要因素,采用仿真模拟得出了远场矿震和近场强矿震作用下临空侧巷道的动载作用过程。通过实际应用表明:采用顶板预裂爆破、大直径钻孔卸压和煤体爆破卸压等综合防治措施,结合“锚索+双网+大托盘”的联合支护方式后,104 J以上大能量事件发生频次降低了50%以上,周期来压步距平均值由17.84 m降至11.98 m,来压范围减少了50%以上,有效降低了临空侧巷道冲击地压风险。

防止聚乙烯料仓静电燃爆的重要措施——反吹风系统的设置

分析了目前聚乙烯料仓反吹风系统的设置情况．指出根据安全料位确定反吹风进风口最佳高度,运用 经验公式计算反吹风风量,利用流体力学分析软件进行流场分析．通过以上步骤,找出原设计缺陷保证新设计的 科学性,从而避免静电燃爆事故．

煤矿冲击矿压动静载叠加原理及其防治

煤矿冲击矿压动力灾害日趋严重,且浅部也出现了该现象。理论研究了动载与静载叠加诱发冲击矿压的能量和应力条件,系统地提出了动静载叠加诱发冲击矿压的原理,并分析了煤矿动静载特征,根据应变率对煤矿载荷状态进行了界定,试验研究了煤岩力学特性与应变率的关系以及动静叠加作用下煤的破坏形态。结果表明:随着应变率增大,煤岩强度、弹性模量呈指数关系增大,当静载占比较大时,煤岩呈剪切破坏;当动载占比较大时,煤岩呈现劈裂甚至爆裂破坏。当动静叠加接近煤岩强度时,单轮或多轮动载作用可诱发煤岩冲击破坏;当动静叠加远小于煤岩强度时,多轮动载虽然能使煤岩产生损伤但难以诱发冲击破坏。动静叠加诱发冲击矿压表现为2种类型:1高静载型,深部开采时,围岩静载较高,矿震产生的微小动载增量可使叠加载荷超过煤岩冲击破坏临界而诱发煤岩冲击破坏;2强动载型,浅部开采时,围岩静载较小,强矿震的冲击动载较大,叠加载荷超过煤岩冲击破坏临界导致煤岩冲击破坏。基于冲击矿压的动静载叠加诱发原理,讨论了冲击矿压监测及防治思路和方法。

薄煤层动静组合诱发冲击地压的机制

理论分析了动静组合诱发冲击地压的应力条件和能量转化过程,揭示了动静组合诱发冲击地压机制,数值计算分析了工作面应力分布特征与煤厚之间的关系,采用微震监测数据分析了卸压爆破产生的应力波传播规律,并分析研究了薄煤层动静载特征及诱发冲击地压过程。结果表明:薄煤层工作面应力集中程度较厚煤层高,峰值应力区距离煤壁较近,应力梯度较大;采动动载直接与高应力叠加,且开采导致的应力降以及单位体积煤体释放的弹性变形能远高于厚煤层,在动静组合作用下,薄煤层工作面易于达到动静组合诱发冲击地压的应力和能量条件,显著符合动静组合诱冲机制。最后基于动静载组合诱发薄煤层冲击地压的机制,探讨了薄煤层冲击地压防治原则和技术方法。

断顶爆破防治冲击矿压技术体系及效果评价研究

断顶爆破在坚硬顶板条件下的冲击矿压灾害防治中应用广泛。基于动静载叠加原理,理论分析了断顶爆破防治冲击矿压的作用机制,在对冲击危险预评估和冲击危险动态演化特点分析的基础上,揭示了冲击危险具有分时、分区和分级的"三分"特征,建立了分时、分区、分级断顶爆破防治冲击矿压技术体系,应用于坚硬顶板型冲击矿压防治工程实践,并通过采取理论计算、钻屑监测和微震监测手段进行断顶爆破效果评价。结果表明:爆破后形成的裂隙区贯通为连续的弱面是控制冲击矿压最重要的区域,断顶爆破能够减弱由于顶板瞬间破断或垮落释放的动载强度,降低上覆悬顶施加在煤体内的静载强度并促使煤体峰值应力向工作面前方转移,达到降低冲击矿压危险的目的;依据揭示的冲击危险分时、分区、分级的"三分"特征,建立了"开切眼倾向断顶爆破、临空煤柱侧走向断顶爆破、工作面内超前预裂爆破和及时解危断顶爆破"的分时分区分级断顶爆破防治冲击矿压技术体系,相应进行了断顶效果评价,其中开切眼倾向断顶爆破后工作面初次来压和周期来压阶段顶板聚集的能量分别降低72%和76%;临空煤柱侧断顶爆破后煤柱内钻屑值下降0.55 kg/m;工作面内预裂爆破区域在回采期间出现微震总能量、单日最大能量均明显降低,微震频次显著增加的整体规律,验证了分时分区分级断顶爆破技术体系对防治冲击矿压的有效性。

动静载作用下冲击地压启动条件及防治技术

基于冲击地压的能量机理,提出了冲击地压启动的2种形式,一种是发生冲击地压所需能量在静载的缓慢作用下达到,在外界扰动下发生;另一种是处于准静态平衡的煤岩体,在强烈动载的帮助下瞬间达到,同时释放大量能量。根据冲击地压应力来源及加载方式,提出了有针对性的防治技术,即:对于静载起主导作用的冲击地压,应以煤层卸压为主,而对动载起主导作用的冲击地压,则更应侧重于顶板弱化等降低煤岩冲击动载的防治技术。

深部盘区巷道群集中静载荷型冲击地压机理与防治

针对深部矿井,盘(采)区巷道群屡次发生冲击地压这一问题,以我国新建千米深井盘区巷道群冲击地压发生为背景,理论分析了巷道群无动载诱发冲击启动的机理与防治方法。结果表明,巷道底煤的厚度对底板水平应力集中影响较大;褶曲构造带也显著影响巷道群应力环境;巷道底臌量与底板释放动载荷量值、底煤厚度均成正相关关系;深部煤层巷道群冲击启动原理,是巷道群自身应力叠加在巷间煤柱,提供了基础静载荷;灾害发生地段底煤厚度以及褶曲构造影响,提供了时机静载荷,2者叠加导致巷间煤柱垂直载荷超过了临界值,同时底板煤体承受的载荷超过了其极限承载力;深部煤层巷道群冲击地压属集中静载荷型,采用基于集中静载荷疏导的深孔区间爆破法可防治冲击地压灾害。

锚杆静-动力学特性及其冲击适用性

利用自主研制的静-动加载试验系统开展了等强与非等强螺纹钢锚杆的静力拉伸实验及有无预应力加载的动力冲击实验。结果表明:在静荷载作用下等强与非等强螺纹钢锚杆都经历了"线弹性变形—屈服平台—强化阶段—径缩破坏"的4个阶段;冲击加载时锚杆的屈服阶段可划分为瞬态屈服与稳态屈服,瞬态屈服的峰值载荷明显高于稳态屈服载荷,且相同直径条件下与静力加载相比锚杆屈服伸长量减小;当冲击能量低于9 kJ时,锚杆杆体能承受多次冲击扰动,且冲击后能够保证足够的杆体强度,但当冲击能量高于9 kJ时,锚杆抗冲吸能性能显著下降,低能量冲击时非等强螺纹钢锚杆的抵抗能力明显优于等强螺纹钢锚杆;无论从锚杆的动态轴力-位移曲线还是从锚杆的峰值载荷与伸长量上看,预应力对冲击载荷下锚杆的动力响应特征无明显影响,但进行防冲支护时,有必要提高预应力加载水平。

邻近采空区巷道外错布置防治冲击地压技术

为预防邻近采空区侧回采巷道繁发冲击矿压,根据动静载叠加诱发回采巷道冲击破坏模型,采用理论分析的方法,揭示了邻近采空区巷道冲击破坏机理及其冲击地压频发的理论依据,基于动静载主要构成得出了邻近采空区巷道冲击破坏的2种模式以及必要准则,从而提出了降低动静载叠加影响的邻近采空区巷道外错布置技术,并且确定了巷道降低静载避开支承压力集中区以及削弱动载以增大传播介质衰减指数为原则的巷道布置原理,最后邻近采空区巷道外错布置技术在跃进煤矿得到了成功实践,取得了明显、有效的防治冲击地压效果。