采矿工程毕业设计翻译

英文原文Fuzzy evaluation on coal seam geological condition of coal face inten million ton MineAbstract：Based on coal seam geological condition in Jisan Mine，quantitative evaluation on concrete coal seam geological condition is made by using fuzzy evaluation with the view of coal mining and coal face production.The evaluation content and its realization of coal seam geological condition，the structure and the index system of evaluation factor，the membership functions and weights of evaluation factor ，evaluation model and reliability are expounded in detail ，eighty-two coal face that will be exploited is classified，Fuzzy evaluation is the basal work to select coal mining technology and ensure a ming running efficiently，safely and steadily.Key words：fuzzy evaluation；membership function1 INTRODUCTIONWith the development of mining ，the difference of coal seam geological conditions will affect the suitability of coal mining technology and coal face outputs ，i.e. qualification and economic indicator.To ensure a mining running efficiently，safely and steadily ，coal seam geological conditions must be known roundly and detailed .Fuzzy evaluation on coal seam geological conditions is a evaluation on concrete coal seam geological condition with the comprehensive view of coal mining. The main characteristic of evaluation is that a coal face is a evaluation cell.The aticle tells of fuzzy evaluation on coal seam geological conditions in Jisan Mine.2 CONDITIONS OF SEAM AND GEOLOGYThere are three sections that are exploited in Jisan Mine，i.e. north section﹑east section﹑west section，they belongs to Sanxia coal seam. Sanxia coal seam is at the bottom of Shanxizu，mean thickness of coal seam is 5.26 metres，from east to west in Mine，thickness of coal seam reduce from 5 metres to 3.5 metre. Rock character of roof is sandrock or siltite，rock character of bottom is siltite or thin sandrock. There are many faults in Jisan Mine，there are fourteen faults that their drops are bigger thantwenty metres，and there are many smaller faults. Based on the coal seam geological conditions，strike longwall mining method in fully mechanized coalface is adopted.3 FACTORS AND INDEX OF EV ALUATION3.1 STRUCTURE OF EV ALUATION FACTORSAccording to the principle of system，feasibility and simplicity，based on coal seam geological characteristic ，the structure of evaluation factors is figure 3.1.It consists of seven compound factors and eleven smaller factors，these factors are quantified by fault density q1﹑fault length exponent q2﹑fault fall exponent q3﹑variation of coal seam and band coefficient γ﹑seam thickness m﹑seam angle α﹑seam hardness R﹑immediate roof hardnessσ﹑ratio of immediate roof and seam mining thickness N﹑false roof thickness h0﹑immediate bottom hardness q c﹑coal face length l and coal face advance length s.Figure 3-1 structure of evaluation factors of coal face3.2 INDEX SYSTEM OF EV ALUATIONExplanation of eleven smaller evaluation factors is as follows：(1)fault effect：describing fault effect on mining needs three index，faultdensity-fault number in unit area；fault length-sum of fault length in unit area；fault fall exponent-ratio of fault fall and seam thickness.(2) variation of coal seam and band coefficient ： ratio of seam thickness sample standard deviation and seam thickness mean. (3) Seam thickness ： seam sample thickness mean. (4) Seam angle ： seam sample angle mean.(5) Seam hardness ： seam compression strength.(6) Immediate roof hardness ： immediate roof compression strength. (7) Main roof holding power ：(8) False roof effect ： false roof thickness.(9) Immediate bottom hardness ： immediate roof compression strength. (10) C oal face length (11) C oal face advance3.3 MEMBERSHIP FUNCTIONS OF EV ALUATION FACTORSThe membership function of evaluation factor is the quantitative description on fuzzy relationship between the change of a geological factor and the mining effect. Membership function is the foundation to build a fuzzy evaluation model.Adopting statistic analogism method ， method of undetermined coefficients and heterogeneous fuzzy statistic method ， membership functions are obtained as follows ： （1）membership function of fault effectμa =2/ （1+exp （0.0018+0.042×q 1+0.064×q 2+0.00071×q 3））（2）membership function of variation of coal seam and band coefficient（3）membership function of seam thickness⎪⎩⎪⎨⎧><≤+⨯-<=5.01.05.02.06.132.00.1)(000000h h h h h h μ（4）membership function of seam angle⎪⎩⎪⎨⎧≥<≤<=3N 1.03N 0.31.8 + N) Exp(-0.29 1.9-0.3N 0.05(N)μN（5）membership function of seam hardness0.17.2()0.51ln 0.917.2421.042c c R c c c c R R R R R μ<⎧⎪=⨯-≤≤⎨⎪>⎩⎪⎪⎩⎪⎪⎨⎧<≤>≥-<≤+⨯+⨯<=-8040403002.08.10.1301671.0012.01069.1ln(164.0)(24σσσσσσσσμσ（6）membership function of immediate roof hardness100010001001000.17.2)ln(5.00)(≥≤<≤⎪⎩⎪⎨⎧-=s s s s s S μ（7）main roof holding power⎪⎪⎪⎩⎪⎪⎪⎨⎧<≤+-<≤+-<≤+-<≤<≤=5036528.10286.036180.101389.018125.104167.01260.1631667.0)(R R R R R R R R R R R μ（8）false roof effect⎩⎨⎧≥<≤⨯-=25.0025.00)(21)(5.0γγγγμγ（9）immediate bottom hardness⎪⎪⎪⎪⎩⎪⎪⎪⎪⎨⎧≥<≤-⨯<≤+⨯<≤-⨯<≤-⨯<≤-⨯=1500.1150130275.00085.0130100483.0000667.0100805.00125.080607.0015.060401.0005.0)(l l l l l l l l l l l l L μ （10）coal face length⎪⎪⎪⎪⎪⎩⎪⎪⎪⎪⎪⎨⎧≥<≤<≤+⨯-<≤<≤-⨯<≤+⨯<≤-⨯<≤+⨯=0.50.10.55.470.05.45.370.12.05.38.20.18.25.252.19.05.20.243.012.00.24.123.045.04.10.105.025.0)(m m m m m m m m m m m m m m m μ （11）coal advance length⎪⎪⎪⎪⎪⎩⎪⎪⎪⎪⎪⎨⎧≥<≤<≤+⨯-<≤<≤-⨯<≤+⨯<≤-⨯<≤+⨯=0.50.10.55.470.05.45.370.12.05.38.20.18.25.252.19.05.20.243.012.00.24.123.045.04.10.105.025.0)(m m m m m m m m m m m m m m m μ 3.4 WEIGHTS OF EV ALUATION FACTORSWeight of evaluation factors is a quantity that show relative importance of per factor in system ，it is the key to unify systemic structure and function.Coam seam geological evaluation of coal face ascertains weights of evaluation factors by AHP.AHP is a easy method to quantify the quanlitative event.Appliacation of AHP needs five steps ：building hierarchical model 、constructing judgement matrix 、single hierarchy collation and consistency check 、total hierarchy collation 、consistency check of total hierarchy collation.Comfirmatiom of judgement matrix is the key to use AHP ，value of judgement matrix is the quantitative description on relative importance of per factor ，the valves are one to nine and their reciprocals.Table1 shows the value ，Table2 to 4 show judgement matrix ，Table5 shows weights of evaluation factors.Figure 3B6~C judgement matrix3.5 FUZZY EV ALUATION MODELCoal seam geological conditions are multilayered evaluated by fuzzy evaluation model，fuzzy evaluation model images single factor evaluation value to total evaluation value by certain algorithm，whether propertis of evaluation sample is bad orgood are assured by total evaluation valve ，in order to comprehesively consider effect degree of per factor ，weighted avarage evaluation model is used ，the model ：∑==⋅=ni ij i j m j r W b 1.....,1,2, In fomula ：b j ——evaluation valve ； W i ——weight matrix 。

Chapter 3 .1 Mining methodmining method 采矿方法；mining operation 采矿作业；transportation 运输；ventilation 通风；ground control 顶板管理；the cost of per ton of coal 吨煤成本；recovery 回采率；subside v. subsidence n.地表沉陷；subsidence control 地表沉陷控制cover 覆盖层；overburden 上覆地层；immediate roof 直接顶；floor 底板；dip （Pitch）倾角；hardness 硬度；strength 强度；cleavage 解理；gas，methane 瓦斯daily operation 日常工作single operation 单一工序unit operation 单元作业auxiliary operation辅助作业cutting n. 切割，掏槽；blasting n. 爆破loading n. 装煤haul v. 运输，搬运drainage n.排水power n. 动力power Supply 动力供应communication n. 通讯lighting n.照明。

disruption in production 停产；reduction in production 减产；compromise 折衷room and pillar 房柱式by far 到目前为止i n common with … 和…一样underground mining 井工开采outcrop 露头，露出地面的岩层；crosscut 联络巷、石门；drift 平硐；entry 平巷；development stage 开拓阶段；production stage 生产阶段；face 工作面。

continuous miner 连续采煤机；haulage capacity 运输能力；main entry 主巷。

练习1矿井系统选择的标准图9.2显示了各种采矿方法的生产分布图。

由于现在在短壁工作面工作的少于12个人，所以采用长臂综采法。

很显然连续采煤法越来越受欢迎不是因为每个单元的生产能力增加，而是因为相同吨位的产出需要的人少。

然而，长臂开采的生产率更高是因为每个采矿单元与生俱来的连续开采潜力使其有更大的生产能力。

虽然如此，讨论选择一个系统比另一个系统好要考虑很多因素，这样会让每种形式的细节分析变得明显。

这个表格列出了很多矿井选择特定系统时考虑的各种因素，提供了像自然条件，开采经验，社会关注点，市场条件等重要因素。

一些选择是相当明显的，然而一些是不明显的。

通常，这些选择更能反映出个人偏见。

例如，当缝隙是坚硬的或包含坚硬的杂质，传统的开采方法（爆破）比通过连续开采剥开煤层更容易。

当眼前的隧道顶部很坏时,长臂开采更容易也能够提供更全面的支撑。

常规开采需求的大量设备可能会导致柔软底部的撕裂，所以常规开采比连续开采需要一个坚固的底部。

由于常规开采在房柱式系统已经比在任何老矿区实行时间都长，由于劳动监察部门最熟悉这种方法和设备，在新矿的开采方法选取中这将是一个重要的考虑因素。

然而，如果对于新的从业人员，选择这种传统方法是不太可能的，因为它需要更多的技巧去协调许多设备以及人力。

但是，对于维护人员就不是这样的。

由于传统设备比连续采矿设备更简单，更可靠，更容易保持状态，一个没有经验的维修组更适合使用常规开采的矿区。

市场对于采矿系统的发展有过很大的影响。

而连续开采通常认为已经开始约在1947年，实际上再更早就有了。

在1920年代早期，McKinley Entry Driver，一个出生很早地使用连续开采方法的矿工，加入的很多条目在Illinois.然而煤炭生产靠它，和几乎如今的所有连续开采矿工，这对于全国上下的取暖需求不是很畅销，所以它产生了低回报。

随着实用市场的到来，所有的煤都是粉碎后使用的，连续采煤机已获得广泛的认可。

题目：XXX煤矿开采设计说明书专业：采矿工程本科生:指导老师：摘要：本设计所做只考虑甘肃靖远煤业集团XXXX煤矿一号煤层。

该井田地质条件较复杂，地质资源储量2。

1亿吨，可采储量1。

21亿吨,设计生产能力150万t/a,服务年限57a.矿井瓦斯涌出量较高，为高瓦斯矿井.矿井采用双斜井开拓。

初期开凿有主斜井、副斜井和回风立井。

采用单一走向长壁后退式开采，综合机械放顶煤采煤.分区域通风方式，抽出式通风。

关键词：综合机械化放顶采煤法服务年限生产能力通风设计类型：模拟型AbstractThe design is about the exploitation design of 1coal seam of Dashuitou coal mine inGansu Province . The geological condition of coal mine is complexity。

The workable mine reserves is 216Mt and the designed mine capbility is1。

2Mt/a ，so the mime serveice life is 72years。

The mine gas emission is higher, so it is highly gassy mine well。

Mine with double shafts development. The initial digging in inclined, deputy shafts and return air shaft. By using single longwall mining to back type, comprehensive mechanical top coal caving mining。

Points area，drew the ventilation type .Keywords：Mechanized caving mining method serveice life production capacity ventilationPaper type：Simulation type前言毕业设计是采矿工程专业培养计划中最后一个,也是最关键、最重要的一个教学环节，是教学时间最长（14~16周），参与教师最多，学生独立学习量最大,教育任务最重的一个实践性教学环节.毕业设计的效果直接影响培养目标的实现和学生就业后在专业上的发展。

原文：DEVELOPING OF TRANS-CENTURY MINING SUBJECTWITH NEW TECHNOLOGY AND NEW THEORYAbstract：Mining subject needs further development and towards which the development would being the problems concerned over all along and to be succeeded with the public good enough attention to discussions to reach an identify of views admittedly. The emergence in succession of new-and-high techs in the mid-and late twentieth century is perhaps the most fascinating and epoch-marking event that has given to all the subjects certain but different degrees of impacts to become more closely interrelative and interdepartmental each other and feature specifically from that of the past for their entirely new conceptions in the result of formulating many new theories，new technologies and new subjects that mining subject is inevitably and unexceptionally the one inclusive. The acuter gives in this paper his opinion regarding the problem of the development of mining subject proving with many convincible facts and most informative new idea,Key words: mining subject; mineral industry; mineral economics; new-and-high tech.1 The Importance of Mining Industry in the National EconomyToday, it has been paid unprecedented attention to the development of technology worldwide.The advance of space engineering,information engineering，biological engineering and marine engineering，the discovery and the research and development of the new energy and new materials increasingly change every aspect of human life both at present and in the future.The words "Science and Technology being the First Production Force" has fatherly and penetratingly pointed out the important role of new technology in the course of national economy construction.In the competition of several big countries in the world striving for the exploration of outer space，one should not forget the essential fact that there are more than five billion people living on the earth. To assure the survival of mankind on the earth，four essential requirements should be considerably fulfilled，namely，the nutrients，materials，fuels and the environment. The nutrients mainly are air，water，forests，grains and miscellaneous plants，all of which are acquired from the nature. The materials refer to iron，ferrous metals，rare metals，precious metals，chemical raw materials and building materials. The fuels cover coal，petroleum，natural gas ,oil shale，uranium，thorium and other radioactive elements. These also occur in nature. The last one is the ecological environment depending on which mankind lives. In the above three essential substances，the materials and fuels are through mining engineering extract from bining industry is a conventional industry, however，with the advance of the new technologies and the introduction of them into mining industry which will be reduced of itself final1y- a technology-intensive industry. The emergence of highly mechanized and automated mines and robot-operated manless working face marks the renewal and substitution of technologies of mining industry and proves the fact that mining industry.However，is conventional industry, but not sunset industry. As long as mankind live on the earth，mining industry will last forever and never decline and fall，instead，as man's living demands increases，the output of fuels and raw materials will be increased by a big marg and mineral industry will still gain a much greater development.2The Object of Study of the Mining Subject2. 1 The Tasks and the Special Features of 1liining SubjectHistorically and the Special Features of 1liining Subject the development of mining subject has its own course of change and development both at home and abroad. Since mining industry is closely related with geology, metallurgical and energy industry consequently in the subject relationships，they are interrelative and interdepartmental each other. As mining subject branch of science dealing with the extraction and utilization of minerals and the resources from inside the earth，on the sake of the complexity and multiplicity of the rock mass and mineral resources of great nature which makes the basic theories of mining subject being more complicated than that of any other engineering subject. Especially in the following aspects featured: the objects of mining subjects are the ore bodies occurred in nature that they differ each other in structure，quality，and property.3Five Urgent Requirements on the Tendency towards the Trans-century Development of Modern Mining Subjects3. 1 Renewing the Knowledge of Strata 11ZechanicsAbove all rock and or ore properties are the prerequisites of the subjects of the study of mining engineering regardless of whether it is excavation，comminuting or strata ,stability strata mechanics is required to make the study along two aspects:(1)From the micro-study to the macro-study(2) The study of the contradictions between rock-breaking and rock stability in the course of mining and excavating. Therefore it is a very broad field of academic studyComparing with common solid materials，rocks are featured structurally for their non-homo.3.2 AnewKnowledgeofMiningEngineeringSystem-the"hian-Nature-Rfachine" Systern ，System engineering had found in recent years very rapid development，and wide applications m mining engineering. Been modeled after the "man-machine’s Generally, mining systems engineering considerably studies had system model used in aerospace engineering and other departments of en Bering. In recent years，Prof. Fettwice of the Montan University of Austria and the author of this paper both had put forth the opinion that the objects of mining engineerm8 Machine are ore bodies and rock strata, the activities of mining engineering are those played with by the man in getting the knowledge of the environment underground.3.3 Reforming the Conventional Mining Technologies and Industries withModern New technologiesThe major policy of China of reforming the conventional industries with new-and-high techsof great importance and no doubt to its conventional industries.The essential features of new-and-high techs are highly technology-intensive.Just as discussed in the beginning of this paper，speaking with respect to the reforming of mining engineering and coal industry with new-and-high techs，it is essential to introduce merely those ones which enable to make these two industries swiftly commercialized. Since mine is concerned with the natural surroundgas of ground，the newtechs，however，as those used in aerospace engineering in the care for "going up to sky" when used for 0gettingdown intothe earthin mining engineering practices evidently are needed to make completely different modalities. In 1080s，Berlin Poly }ethnic university had applied optic fiber telecommunication technology- in underground mining，giving rise to abundant interference problems of earth magnetism，electricity and light wave, and the insulation of strata to the conduction electronic waves. The BPM man had the problems s finally tailed，however，through a long time of research work. Therefore，to have the minerals industries well prepared technically for the 21st century，to paying great attention the following fields of study are required3.3.4Making the study of market-economy mineral economics theoriesFor a long time that the mineral economics theory in China had been given distinct features of planning economy，while in the theory itself，mineral resources were not recognized ascommodities and had no prices. Consequently，even though the mineral products had pricesbut were distorted ones making all national mining enterprises non-profitable and to exist depending on governmental policy-subsidization. Now the country, however，has changed intosocialist market economy, most mineral enterprises radically cannot accommodate themselvesto this new situation，in particular，from the point of view of "Enriching the peasants" policyto put forward to the exploitation of mineral resources，the near-term policy of the so-called“wherever there’ water，flow it fast"，which had made the mineral industry from the repeated view-point of and the enriching the Pleasants policy, has caused the price deficit due to lowselling-price of minerals into even worse situation of disorder，no-restraint and anarchy ofscrambling for extracting the mineral resources putting the mineral industries in a tight spot unabling to feed themselves. Under this circumstance，the importance of undertaking the softscience research right now becomes more conspicuous to the mineral industries than ever before. One can predict that had the theoretical study of mineral economics theory been made ,portent break troughs，that it would radically change the face of our mineral industries.3.5 Relationship between Mineral Engineering and Natural EcologyMining engineering is the removal of rocks and minerals to the surface throughexcavations from underground deep in the earth or from the ground surface leaving the excavated space so formed. Every turn meters Surface every year subsidence in China. of the commodity flow of mining products reaches billion cubic Obviously it has caused many negative effects，for example:(1)uses of waste rock which results in the damages of farming lands and houses;(2) Large volrefuse and tailings occupy large area of land; and (3) Coal and oil burning products give off waste materials，such as exhaust gas，waste liquids，and solids and pollute the environment. In China，80 percent of 1. 1 billion tons of coalburned as fuel，from which，dust，sulpher and the of NO2and CO2 and the effective less heating effect seriously constitutes a menace to the ecological environment of China and the neighboring countries.4Suggestions opment of to the Science and Technology Circles of the Nation for the Develop-the Mining Subject4.1 An Unguent AppealNo doubt the "flying up into the sky" technology is the one most advanced，however，thegetting down into the earth" technology in mining engineering is no less complex，and even more difficult to pin down. It is no wonder that people consider that mineral engineering beingmuch simpler and pay less attention for lack of the knowledge of the resulting in the low rate ofmineral recovery and low rate of mineral extracting. For this country, but to spend a greatmany of valuable hard currency to import those actually need not to import raw materials andelse，naturally this is not favorable to the development of national economy. Hoping the science and technology circles，in particular their leading departments，renewing their recognitions to this awkward situation，and give necessary support to the urgently-needed topics of research studies of the mineral industries.4.2 National Resource PolicyNational resource policy concerns the future for many generations.Hoping the government population institutions relevant learn Iron the lesson of the past population policy，to take measures as early as possible to have the print up of mineral resources centralized.4.3 Mineral Investment PolicyThe investment policy and the set up of mineral industries should be dire; iron: tm common industries to assure in the long run the first energy supply 1vit} necessary and appropriate support.4.4 Make Ready the SuccessorsTo make ready the successors for the mineral industries and the development of the mining subjects，suggesting to give preferential treatment to the university.Admissionssystem and the recruitment of mineral workersand set mineral science.Foundation as an important subject independent from the foundations of those.Basic science in the natural science foundation.The aim of writing this paper is to hone that in the tonguingA of this centuryminim subject in China will have a new prosperous development with the of new technology to theory under the guidance of the national science policy.译文：新技术和新理论的采矿业跨世纪发展摘要：煤炭产业需要更长远的发展，对工作中所讨论的热点在工业中出现新的理论和高科技成功使用在二十世纪末是最美好的，作为被关心的问题需要较快一步的发展，在20世纪中后期产生的新型、高速的新技术是最有吸引力和标志性的，即使在所有行业中不同的冲击变得起来越相关以及部门间彼此合作并明确地叙述许多新的理论，煤炭行业的新科技和新理论是不可避免的，并且包括一切的不可能性。

ROOM-AND-PILLAR METHOD OF OPEN-STOPE MINING空场采矿法中的房柱采矿法Chapter 1.A Classification of the Room-and-Pillar Method of Open-Stope Mining第一部分，空场采矿的房柱法的分类OPEN STOPING空场采矿法An open stope is an underground cavity from which the initial ore has been mined. Caving of the opening is prevented (at least temporarily) by support from the unmined ore or waste left in the stope,in the form of pillars,and the stope walls (also called ribs or abutments). In addition to this primary may also be required using rockbolts , reinforcing rods, split pipes ,or shotcrete to stabilize the rock surface immediately adjacent to the opening. The secondary reinforcement procedure does not preclude the method classified as open stoping.露天采场台阶是开采了地下矿石后形成的地下洞室。

通过块矿或采场的支柱和（也称为肋或肩）采场墙形式的废料的支持来（至少是暂时的）预防放顶煤的开幕。

除了这个，可能还需要使用锚杆，钢筋棒，分流管，或喷浆，以稳定紧邻开幕的岩石表面。

Ore handlingIntroductionOre handling,which may account for30-60%of the total delivered price of raw materials, covers the processes of transportation,storage,feeding,and washing of the ore en route to,or during,its various stages of treatment in the mill.Since the physical state of ores in situ may range from friable,or even sandy material,to monolithic deposits with the hardness of granite,the methods of mining and provisions for the handling of freshly excavated material will vary extremely widely.Ore that has been well broken can be transported by trucks,belts,or even by sluicing,but large lumps of hard ore may need individual blasting.Modem developments in microsecond delay fuses and plastic explosive have resulted in more controllable primary breakage and easier demolition of occasional very large lumps.At the same time,crushers have become larger and lumps up to2 m in size can now be fed into some primary units.Open-pit ore tends to be very heterogeneous,the largest lumps often being over1.5m in diameter.The broken ore from the pit,after blasting,is loaded directly into trucks,holding up to200t of ore in some cases,and is transported directly to the primary crushers.Storage of such ore is not always practicable,due to its"long-ranged"particle size which causes segregation during storage,the fines working their way down through the voids between the larger particles;extremely coarse ore is sometimes difficult to start moving once it has been stopped.Sophisticated storage and feed mechanisms are therefore often dispensed with,the trucks depositing their loads directly into the mouth of the primary crusher.The operating cycle on an underground mine is complex.Drilling and blasting are often performed on one shift,the ore broken in this time being hoisted to the surface during the other two shifts of the working day.The ore is transported through the passes via chutes and tramways and is loaded into skips,holding as much as30t of ore,to be hoisted to the surface. Large rocks are often crushed underground by primary breakers in order to facilitate loading and handling at this stage.The ore,on arrival at the surface,having undergone some initial crushing,is easier to handle than that from an open pit mine and storage and feeding is usually easier,and indeed essential,due to the intermittent arrival of skips at the surface.The removal of harmful materialsOre entering the mill from the mine(run-of-mine ore)normally contains a small proportion of material which is potentially harmful to the mill equipment and processes.For instance,large pieces of iron and steel broken off from mine machinery can jam in the crushers.Wood is a major problem in many mills as this is ground into a fine pulp and causes choking or blocking of screens,etc.It can also choke flotation cell ports,consume flotation reagents by absorption and decompose to give depressants,which render valuable minerals unfloatable.Clays and slimes adhering.to the ore are also harmful as they hinder screening,filtration,and thickening,and again consume valuable flotation reagents.All these must be removed as far as possible at an early stage in treatment.Hand sorting from conveyor belts has declined in importance with the development of mechanised methods of dealing with large tonnages,but it is still used when plentiful cheap labour is available.Crushers can be protected from large pieces of"tramp"iron and steel by electromagnets suspended over conveyor belts(Figure2.1).These powerful electromagnets can pick up large pieces of iron and steel travelling over the belt and,at intervals,can be swung away from the belt and unloaded.Guard magnets,however,cannot be used to remove tramp iron from magnetic ores,such as those containing magnetite,nor will they remove non-ferrous metals or non-magnetic steels from the ore.Metal detectors,which measure the electrical conductivity of the material being conveyed,can be fitted over or around conveyor belts.The electrical conductivity of ores is much lower than that of metals and fluctuations in electrical conductivity in the conveyed material can be detected by measuring the change that tramp metal causes in a given electromagnetic field.When a metal object causes an alarm,the belt automatically stops and the object can be removed.It is advantageous with non-magnetic ores to precede the metal detector with a heavy guard magnet which will remove the ferromagnetic tramp metals and thus minimise belt stoppages.Large pieces of wood which have been"flattened out"by passage through a primary crusher can be removed by passing the ore feed over a vibrating scalping screen.Here the apertures of the screen are slightly larger than the maximum size of particle in the crusher discharge,allowing the ore to fall through the apertures and the flattened wood particles to ride over the screen and be collected separately.Wood can be further removed from the pulp discharge from the grinding mills by passing the pulp through a fine screen.Again,while the ore particles pass through the apertures,the wood collects on top of the screen and can be periodically removed.Washing of run-of-mine ore can be carried out to facilitate sorting by removing obscuring dirt from the surfaces of the ore particles.However,washing to remove very fine material,or slimes,of little or no value,is more important.Washing is normally performed after primary crushing as the ore is then of a suitable size to be passed over washing screens.It should always precede secondary crushing as slimes severely interfere with this stage.The ore is passed through high-pressure jets of water on mechanically vibrated screens. The screen apertures are usually of similar size to the particles in the feed to the grinding mills, the reason for which will become apparent.In the circuit shown in Figure2.2material passing over the screen,i.e.washed ore,is transported to the secondary crushers.Material passing through the screens is classified into coarse and fine fractions by a mechanical classifier or hydrocyclone or both.It may be beneficial to classify initially in a mechanical classifier as this is more able to smooth out fluctuations in flow than is the hydrocyclone and it is better suited to handling coarse material.The coarse product from the classifier,designated"washing plant sands",is either routed direct to the grinding mills or is dewatered over vibrating screens before being sent to mill storage.A considerable load,therefore,is taken off the dry crushing section.The fine product from classification,i.e.the"slimes",may be partially dewatered in shallow large diameter settling tanks known as thickenersand the thickened pulp is either pumped to tailings disposal or,if containing values,pumped direct to the concentration process,thus removing load from the grinding section.In the circuit shown,the thickener overflows are used to feed the high-pressure washing sprays.Water conservation in this manner is practised in most mills.Wood pulp may again be a problem in the above circuit,as it will tend to float in the thickener,and will choke the water spray nozzles unless it is removed by retention on a fine screen.Ore transportationIn a mineral processing plant,operating at the rate of400,000td-1this is equivalent to about28t of solid per minute,requiting up to75m3min-1of water.It is therefore important to operate with the minimum upward or horizontal movement and with the maximum practicable pulp density in all of those stages subsequent to the addition of water to the system. The basic philosophy requires maximum use of gravity and continuous movement over the shortest possible distances between processing units.Dry ore can be moved through chutes,provided they are of sufficient slope to allow easy sliding,and sharp turns are avoided.Clean solids slide easily on a15-25°steel-faced slope, but for most ores,a45-55°working slope is used.The ore may be difficult to control if the slope is too steepThe belt conveyor is the most widely used method of handling loose bulk materials. Belts now in use are with capacities up to20,000th-1and single flight lengths exceeding 15,000m("Bulk Materials Handling",2005),with feasible speeds of up to10m s-1.The standard rubber conveyor belt has a foundation of sufficient strength to withstand the driving tension and loading strains.This foundation,which may be of cotton,nylon,or steel cord,is bound together with a rubber matrix and completel y covered with a layer of vulcanised rubber.The carrying capacity of the belt is increased by passing it over troughing idlers.These are support rollers set normal to the travel of the belt and inclined upward from the centre so as to raise the edges and give it a trough-like profile.There may be three or five in a set and they will be rubbercoated under a loading point,so as to reduce the wear and damage from impact.Spacing along the belt is at the maximum interval which avoids excessive sag.The return belt is supported by horizontal straight idlers which overlap the belt by a few inches at each side.To induce motion without slipping requires good contact between the belt and drive pulley.(Figure2.3).This may not be possible with a single180~turn over a pulley and some form of"snubbed pulley"drive or"tandem"drive arrangement may be more effective.The belt system must incorporate some form of tensioning device to adjust the belt for stretch and shrinkage and thus prevent undue sag between idlers,and slip at the drive pulley. In most mills,gravity-operated arrangements are used which adjust the tension continuously (Figure2.4).Hydraulics have also been used extensively,and when more refined belt-tension control is required,especially in starting and stopping long conveyors,load-cell-controlled electrical tensioning devices are used.The reliability of belt systems has been enhanced by advances in control technology, making possible a high degree of fail-safe automation.A series of belts should incorporate an interlock system such that failure of any particular belt will automatically stop preceding belts. Interlock with devices being fed by the belt is important for the same reasons.It should not be possible to shut down any machine in the system without arresting the feed to the machine atthe same time and,similarly,motor failure should lead to the automatic tripping of all preceding belts and machines.Sophisticated electrical,pneumatic and hydraulic circuits have been widely employed to replace all but a few manual operations.Several methods can be used to minimise loading shock on the belt.A typical arrangement is shown in Figure2.5where the fines are screened on to the belt first and provide a cushion for the larger pieces of rock.Feed chutes must be designed to deliver the bulk of the material to the centre of the belt and at a velocity close to that of the belt.Ideally it should be the same,but in practice this condition is seldom obtained,particularly with wet sand or sticky materials.Where conditions will allow,the angle of the chute should be as great as possible,thereby allowing it to be gradually placed at lesser angles to the belt until the correct speed of flow is obtained.The material,particularly if it is heavy,or lumpy,should never be allowed to strike the belt vertically.Baffles in transfer chutes,to guide material flow,are now often remotely controlled by hydraulic cylinders.The conveyor may discharge at the head pulley,or the load may be removed before the head pulley is reached.The most satisfactory device for achieving this is a tripper.This is an arrangement of pulleys by which the belt is raised and doubled back so as to give it a localised discharge point.It is usually mounted on wheels,running on tracks,so that the load can be delivered at several points,over a long bin or into several bins.The discharge chute on the tripper can deliver to one or both sides of the belt.The tripper may be moved by hand,by head and tail ropes from a reversible hoisting drum,or by a motor.It may be automatic, moving backwards and forwards under power from the belt drive.Shuttle belts are reversible self-contained conveyor units mounted on carriages,whichpermit them to be moved lengthwise to discharge to either side of the feed point.The range of distribution is approximately twice the length of the conveyor.They are often preferred to trippers for permanent storage systems because they require less head room and,being without reverse bends,are much easier on the belt.Where space limitation does not permit the installation of a belt conveyor,gravity bucket elevators can be used(Figure2.1).These provide only low handling rates with both horizontal conveying and elevating of the material.The elevator consists of a continuous line of buckets attached by pins to two endless roller chains running on tracks and driven by sprockets.The buckets are pivoted so that they always remain in an uptight position and are dumped by means of a ramp placed to engage a shoe on the bucket,thus turning it into the dumping position.Sandwich conveyor systems can be used to transport solids at steep inclines from30to 90°.The material being transported is"sandwiched"between two belts which hold the material in position and prevent it from sliding back down the conveyor even after the conveyor has stopped or tripped.As pressure is applied to material to hold it in place,it is important the material has a reasonable internal friction angle.The advantage of sandwich belt conveyors is that they can transport material at steep angles at similar speeds to conventional belt conveyors("Sandwich Conveyors",2005).Screw conveyors are another means of transporting dry or damp particles or solids.The material is pushed along a troughby the rotation of a helix,which is mounted on a central shaft.The action of the screw conveyor allows for virtually any degree of mixing of different materials and allows for the transportation of material on any incline from the horizontal to vertical.The main limitation of screw conveyors is their capacity,which has a maximum rate of about300m3/h(Perry and Green,1997).Hydraulic transport of the ore stream normally takes over from dry transportation at the grinding stage in most modem mills.Pulp may be made to flow through open launders by gravity in some unders are gently sloping troughs of rectangular,triangular or semicircular section,in which the solid is carried in suspension,or by sliding or rolling.The slope must increase with particle size,with the solid content of the suspension,and with specific gravity of the solid.The effect of depth of water is complex;if the particles are carried in suspension,a deep launder is advantageous because the rate of solid transport is increased.If the particles are carried by rolling,a deep flow may be disadvantageous.In plants of any size,the pulp is moved through piping via centrifugal pumps.Pipelines should be as straight as possible to prevent abrasion at bends.The use of oversize pipe is dangerous whenever slow motion might allow the solids to settle and hence choke the pipe. The factors involved in pipeline design and installation are complex and include the solid-liquid ratio,the average pulp density,the density of the solid constituents,the size analysis and particle shape,and the fluid viscosity(Loretto and Laker,1978).Centrifugal pumps are cheap in capital cost and maintenance,and occupy little space (Wilson,1981;Pearse,1985).Single-stage pumps are normally used,lifting up to30m and in extreme cases100m.Their main disadvantage is the high velocity produced within the impeller chamber,which may result in serious wear of the impeller and chamber itself, especially when a coarse sand is being pumped.Ore storageThe necessity for storage arises from the fact that different parts of the operation of mining and milling are performed at different rates,some being intermittent and some continuous,some being subject to frequent interruption for repair,and others being essentially batch processes.Thus,unless reservoirs for material are provided between the different steps,the whole operation is rendered spasmodic and,consequently,uneconomical.The amount of storage necessary depends on the equipment of the plant as a whole,its method of operation,and the frequency and duration of regular and unexpected shutdowns of individual units.For various reasons,at most mines,ore is hoisted for only a part of each day.On the other hand,grinding and concentration circuits are most efficient when running continuously. Mine operations are more subject to unexpected interruption than mill operations,and coarse-crushing machines are more subject to clogging and breakage than fine crushers, grinding mills and concentration equipment.Consequently,both the mine and the coarse ore plant should have a greater hourly capacity than the fine crushing and grinding plants,and storage reservoirs should be provided between them.Ordinary mine shutdowns,expected or unexpected will not generally exceed a24h duration,and ordinary coarse-crushing plant repairs can be made within an equal period if a good supply of spare parts is kept on hand. Therefore,if a24h supply of ore that has passed the coarse-crushing plant is kept in reserve ahead of the mill proper,the mill can be kept running independent of shutdowns of less than a 24h duration in mine and coarse-crushing plant.It is wise to provide for a similar mill shutdown and,in order to do this,the reservoir between coarse crushing plant and mill must contain at all times unfilled space capable of holding a day's tonnage from the mine.This is not economically possible,however,with many of the modem very large mills;there is a trend now to design such mills with smaller storage reservoirs,often supplying less than a two-shift supply of ore,the philosophy being that storage does not do anything to the ore,and can,in some cases,have an adverse effect by allowing the ore to oxidise.Unstable sulphides must be treated with minimum delay,and wet ore cannot be exposed to extreme cold as it will freeze and be difficult to move.矿石处理矿石运搬所花费的费用，大概占所有原材料输送的过程的30%-60%。

2013 届毕业文献翻译题目文献翻译专业班级采矿工程学号 09010901xx学生姓名刘xx指导教师张电吉指导教师职称教授学院名称环境与城市建设学院完成日期： 2013 年 6 月日Room and pillar Mining MethodsBullock(1982a),quoting previous data, showed that room and pillar mining together with stope and pillar mining accounted for most of the underground mining in the United States. He estimated that 60% of noncoal minerals (about 80 million tons or 70 Mt) and 90% of coal ( about 290 million tons or 260 Mt) were obtained by room and pillar methods, and it is unlikely that things are radically different today. The method is cheap, highly productive, easily mechanized, and relatively simple to design.The room and pillar mining method (Fig.5. 2) is a type of open stoping used in near horizontal deposits in reasonably competent rock, where the roof is supported primarily by pillars. Ore is extracted from rectangular shaped rooms or entries in the ore body, leaving parts of the ore between the entries as pillars to support the hanging wall or roof. The pillars are arranged in a regular pattern, or grid, to simplify planning and operation. They can be any shape but are usually square or rectangular. The dimensions of the rooms and pillars depend on many design factors. These include the stability of the hanging wall and the strength of the ore in the pillars, the thickness of the deposit, and the depth of mining. The objective of design is to extract the maximum amount of ore that is compatible with safe working conditions. The ore left in the pillars is usually regarded as irrecoverable or recoverable only with backfill in noncoal mines.applications of pillar mining have been discussed by Hamrin ( 1982) and Hittman( Anon. . 1976) among others. Suitable conditions include ore that are horizontal or have a dip of less than 30°. A major requirement is that the hanging wall is relatively competent over a short period of time, or is capable of support by rock bolts that are used extensively in room and pillar mining. The method：! is particularly suited to bedded deposits of moderate thickness (2 to 6 m) such as coal-the main application一salt, potash, and limestone.Figure.5.2Room and pillar mining method.1, Methods of Room and Pillar MiningRoom and pillar mining takes place in sections or panels, which are usually rectangular and regular in plan. In hard rock mining of horizontal ore bodies, the method is very similar to open stoping. In many cases, ore grade control may be the primary requirement in mine design, and ground control and ventilation secondary considerations. This may lead to an ad hoc room and pillar design with irregular- , nonrecoverable pillars of low-grade ore.Hard-rock room and pillar mining is a effectively method of open stoping (stope and pillar mining) at a low angle to the horizontal, excavating rooms and leaving supporting pillars.Where mineral values vary, the method is similar to the old “gophering" method of mining where random excavations followed highly mineralized zones. Where mineral values are consistent, the mine layout can be regular. The method differs from most hard-rock mining methods in that gravity flow is limited, and ore must be loaded in the excavation where it has been blasted and transported from that point. In large operations this involves trucks and loaders or load — haul — dumps ( LHDs).There are various methods of room and pillar stoping. The most common are full-face slicing breast stoping and multiple slicing or bench and breast stoping. In the former, the rooms are opened to their full vertical height with no mineral or economic value left in the roof or the floor. probably the reasonable safe limit for full-face slicing is 8 to 10 m depending on drilling and support equipment, and beyond this, multiple slicing is used.2. Production CycleFor hard-rock ore bodies ,the basic cycle is similar to hard-rock tunneling four main elements, (1)mark out and drill blast holes , usually in a wedge pattern , (2) ,and ventilate to remove blast fumes ,(3) introduce mucker and muck and load，and ④scale the face and walls and bolt the roof where necessary. There is considerable complexity in the interaction among these elements that make up a basic critical path. In order to estimate the cycle time, it is necessary to determine unit loading and drilling rates and task times for these elements and also to estimate how subsidiary elements and tasks such as haulage and ventilation takeup may impinge upon the critical path in a badly organized mine.3.Panel DevelopmentA panel layout for a typical room and pillar mine in a noncoal mine is illustrated as follows ：The excavation height is about 4.5m,and the normal sloping practice is to drive a single development drift about 10. 5 m wide a distance of about four or five rooms into the ore body. This will serve as the main haulage drift. Pillars are then marked out on the drift walls and rooms driven between them.To drill and blast the initial drive when the only exposed or free face is the drive face, some form of cut pattern is used. This is known as the “ face round or “ swing and in a 4. 5 by 10.5 m face will comprise 60 to 70 holes of about 8 mm to a depth at 3 to 3. 6 m. If more than one face is exposed,a group of holes may be drilled at a low angle to the free face in what is known as a " slab round or slabbing or “slashing”. This requires less explosive and less drilling than a single face. the most common form of face round is a wedge or V, cut although bum cuts can also beDrilling is carried out with jumbo-mounted hydraulic drills ；loading is usually by gathering arm loader, although in modern mines, trackless LHD vehicles are used to the load to a transfer raise where it is reloaded into trucks or conveyors.房柱法Bullock在1982年提出房柱法,它指在矿房与矿柱里回采矿物，在美国大多数地下开采应用柱式开采。

外文原文：Adopt the crest of the coal work noodles plank managementproblem studyCrest the plank management is the point that adopts a safe management of the coal work noodles.Statistics according to the data, crest the plank trouble has 60% of the coal mine trouble about, adopting the trouble of the coal work noodles and having a crest 70% of the plank trouble above.Therefore, we have to strengthen a plank management, reducing to adopt the coal work noodles crest the occurrence of the plank trouble.1,the definition of the crest,scaleboard and it categorizeEndow with the existence coal seam on of the close by rock strata be called a plank, endow with the existence coal seam under of the close by rock strata be called scaleboard.Crest the rock,strength of the scaleboard and absorb water sex and digging to work the management of the noodles contain direct relation, they is certain crest the plank protect a way and choose to adopt the empty area processing method of main basis.1.1 planks categorizeAccording to rock,thickness and return to adopt process to fall in the 垮of difficult easy degree, crest the plank is divided into the false crest,direct crest and old crest.According to direct crest sport to adopt a field to the influence for press, the direct crest is divided into broken up,unsteady,medium etc. stability,stability,strong and tough crest plank etc. is five.According to old crest the sport Be work mineral inside the noodles press to present degree and to work safe threat of noodles of size, the old crest is is divided in to press very and severely, press mightiness, press to compare obviously, don't obviously press etc. is four.1.2 scaleboards categorizeAccording to the opposite position relation of the rock strata and the coal seam, the scaleboard is divided into direct bottom with the old bottom.Locate coal seam directly under of the rock strata be called direct bottom;locate the direct bottom or coal seam under of the rock strata be called old bottom.The coal seam crest the scaleboard type expects the influence of the geology structure sport after be subjected to the deposition environment and, its growth in different region degree dissimilarity, the coal seam possibility for have isn't whole.2,crest that need to be control plank classification and adopt the processing way of the empty areaAccording to different crest the plank type and property, choose to pay to protect a way and adopt the empty area processing method differently, is a plank management of basic principle.2.1 crest needed to pull to make plank classificationPress a knothole rock strata strength, the crest plank that needs to be control can is divided into: general crest the plank,slowness descend to sink a plank and is whole fall the crest of the cave in the danger plank etc..2.2 work noodles adopt the processing method of the empty areaThe processing method that adopts empty area mainly has: all 垮s fall a method,partial full to fill a method,the coal pillar to prop up a method to alleviate to descend to sink a method slowly etc..3,crest the plank pressure present a characteristic3.1 top the cover rock strata of the sport regulation and the work in front pay to accept pressure to distribute behindDuring the period of mine, adopt empty area above of the rock strata will take place ambulation, according to crest the plank change mind condition, taking the cranny rock strata in up the cover rock strata follow the work noodles to push forward the direction demarcation as three areas: the coal wall prop up the influence area,leave layer area and re- press solid area.The noodles opens to slice an eye to go to push forward forward in the process from the work, break original should the equilibrium of the dint field, cause should the dint re- distribute.Be adopting the coal work noodles to become to pay to accept pressure in front and back, it concretely distributes shape to have something to do with adopting the empty area processing method.3.2 first times to press to press a main manifestation with the periodFirst time to press a main manifestation:BE a plank"by oneself the vield song" range enlargement;the coal wall transform and fall to fall(the slice help);pay to protect to drill bottom etc..First time to press to want to keep on more and suddenly and generally for 2-3 days.Period to press a main manifestation:Main manifestation BE:crest the plank descend to sink nasty play increment of speed, crest the plank descend to sink quantity to become big;pay what pillar be subjected to load widespread increment;adopt empty area to hang a crest;pay pillar to make a noise;cause the coal wall slice to help,pay pillar to damage,crest plank occurrence the step descend to sink etc..If pay the pillar parameter choice to be unsuited to a proper or single body to pay the pillar stability worse, may cause the partial crest or crest plank follow the work noodles to slice to fall etc..4,crest the plank choice for protectThe work noodles the function for protect decelerate a plank to descend to sink, supporting to control a crest to be apart from the knothole integrity inside the crest, assurance work space safety.4.1 choices that protect material and formPay to protect material to mainly there are the metals support and the wood support.Pay to protect a form to mainly have a little the pillar to protect,the cote type protect to press a support with liquid.4.2s protect a specification choiceWhile choosing to pay to protect specification, mainly control the following 2:00:1.Control the work noodles adopt high and its variety.Generally can according to drill a holethe pillar form or have already dug the tunnel data of to make sure to adopt high.From last the movable regulation of the cover rock strata, can the initial assurance crest plank at biggest control a crest to be apart from place of average biggest descend to sink quantity, select to pay a pillar model number suitablely2 control the crest plank of the normal appearance to descend to sink the quantity and support can the draw back pute the biggest and high Hmax and minimum and high Hmin that pays pillar, select specification of pay the prehensive the pillar model number and specification, check related anticipate, assurance the model number of the pillar.5,the work noodles manages everyday of pointEveryday crest the point of plank management is the with accuracy certain protects density and control a method, right arrangement and organize to adopt coal and control a crest to relate to in fixed time, strengthen to pay to protect the quality management before press, the assistance that chooses to use a good necessity protect etc., attain to expel to emit a trouble, assurance the purpose of[with] efficiency.1 choice that protects density and controls a methodAccording to the work noodles crest plank rock,adopt a periodic to press obvious degree, press strength and to press in front and back a crest knothole variety a circumstance etc., the certain protect density and control a method.It adopt coal in 2 production lines with control of the crest to relate to in fixed timePeriod to don't obviously press to adopt a field, emphasize to pay to protect,adopt coal, control a parallel homework, possibly contract to adopt coal,return to pillar to put distance between an operations with speed the work noodles propulsion degree;period to press more and obviously adopt a field, at to press in front and back adopt different of,control the relation organization project, before press should not adopt coal,put a crest in the meantime homework, press after should adopt to adopt coal,put a crest to keep minimum wrong be apart from parallel homework.Field to strengthen to pay to protect the quality management assurance to pay pillar to have to prop up dint,prevent°from paying pillar to drill bottom enough before press,right adoption the assistance protect.Adopt the coal work noodles crest, the plank manages everyday of the key lie in raising the spot management,the operation level, paying to protect and adapt to adopt a field to press and crest the scaleboard variety circumstance, adopt right of the assistance protect measure, well exertivecontrol a result.译文：采煤工作面的顶板管理问题探讨顶板管理是采煤工作面安全管理的重点。

绪论☐☐mine n. 矿山，矿井。

v. 采矿☐mining n.采矿，采矿业，采掘行业☐mineral n. 矿物☐mine development 矿井开拓☐mine planning 矿井设计☐mine operation 矿井作业☐mine closure 矿井关闭☐mine reclamation 矿区恢复治理☐ore n. 矿石☐gangue n. [ɡæŋ] 夹石，夹矸 n. 脉石☐waste n. 废石☐mineral deposit 矿床☐metallic ore 金属矿石☐nonmetallic mineral 非金属矿物☐coal 煤☐petroleum 石油☐natural gas 天然气☐ground control 岩层控制☐ventilation 通风☐haulage 运输☐hoisting 提升☐rock breakage 破岩☐surrounding rock mass 围岩，周围岩层☐Dynamite 炸药☐Dark Ages 黑暗时代(欧洲史上约公元476-1000年)，欧洲中世纪☐prospecting 勘探，探矿☐exploration 勘探，探测☐development 开拓☐exploitation 开采☐reclamation [﹑reklə′meɪʃən] 恢复治理，复垦☐colliery [′kɔljəri] n. 矿井，煤矿☐surface mining 露天开采☐shaft 井筒，立井☐slope 斜井☐adit 平硐☐open pit mining 基坑式露天开采井，煤矿☐open cast mining (strip mining) 倒堆式露天开采☐stripe 条带☐stripe mining 条带开采☐aqueous mining method [′eikwiəs] 水采方法☐underground mining 地下开采☐unsupported mining 空场法/无支护法☐supported mining 有支护法☐caving mining 垮落法/崩落法☐unit operations 单元作业；工序☐production operation 生产工序，主要工序☐materials handling 物料搬运☐drill 钻眼☐blast 爆破☐load 装载☐unload，dump，卸载☐haul 运输☐auxiliary operation 辅助工序☐roof support 顶板支护☐ventilation and air-conditioning 通风和空气调节☐power supply 供电☐pumping；drainage 排水☐maintenance 设备维护☐communication 通讯☐lighting 照明☐delivery of compressed air, water 供水和压缩空气☐supplies to the working sections 其它材料供应☐provide slope stability 保持边坡稳定☐waste disposal 废物处理☐supply of material 材料供应1.1 Earth crust and strata☐heavenly body 天体☐atmosphere 大气层☐hydrosphere 水圈☐lithosphere岩石圈☐earth core地核☐earth mantle地幔☐crust地壳☐geologic function; geologic process地质作用☐geologic process from the external force外力地质作用☐geologic process from the internal force内力地质作用☐metamorphic process变质作用☐weathering风化作用☐mechanical weathering物理风化☐chemical weathering化学风化☐disintegration剥蚀，剥蚀作用☐decay 侵蚀、腐蚀☐侵蚀 erosion☐搬运作用 transportation☐沉积作用 deposition, sedimentation ☐成岩作用lithogenesis☐岩石 rock☐土 soil☐矿物 mineral☐火成岩igneous rock☐沉积岩sedimentary rock☐变质岩metamorphic rock☐喷出岩 extruded rock☐侵入岩intrusive rock☐花岗岩 granite☐玄武岩basalt☐斑岩porphyry☐石英 quartz☐长石feldspar☐云母 mica☐砂岩 sandstone☐粉砂岩 siltstone☐细砂岩 packsand☐粗砂岩 gritrock☐砂质泥岩 sandy mudstone☐页岩 shale☐石灰岩limestone☐泥 mudstone☐地层、岩层 stratum (pl) Strata☐大理marble☐板岩 slate☐石英岩quartzite☐gneiss1.2 Origin of Coal☐fossil n. 化石。

Underground MiningMost present-day mining in Europe occurs under 2000 to 4000 ft of overburden, as more easily mined coal deposits have been depleted. At this depth most mines are developed as shaft mines. All personnel, material, and coal have to be hoisted trough these shaft. Considering the two factors of hoisting capacity and required length of shaft, a considerable investment is necessary to reach the coal-bearing strata. The requires huge investments. Openings at this depth have to be equipped with costly supports, and periodic reworking and repair is necessary.Mines not only extend horizontally but also vertically through the development of new levels. The life of the mines is thus extend considerably, and surface installations can be amortize over a longer period.The more limited reserves have forced companies into mining less favorable deposits, and European government require that all possible deposits be mined to conserve the nation’s energy resources. These factor and the large percentage of inclined seams and faults make mining very difficult and costly. The population density and the heavy surface buildup cause additional expense in the form of payments for subsidence damage to surface structures. Therefore, backfilling is frequently practiced to reduce subsidence. The close spacing of faults often severely limits the size of a mining section, forcing frequent moves and excessive development work.The thickness of the overburden results in very high ground pressure. This would require extremely large pillars if the room and pillar method was applied. Additionally, support is required for any opening, adding prohibitive costs to a multiple-entry room and pillar operation.As a result, single-entry longwall operations requiring the minimum number of entries and allowing maximum recovery of resources is the mining method almost exclusively practiced.Shaft mines dominate the European coal mining industry. Shafts 20 to 30 ft in diameter, with circular cross section, lined with masonry, concrete, or steel are the dominant meansof gaining access to the coal-bearing strata. They are often extended beyond the last mining level to provide for future expansion. As in the Unite States, shafts are developed by drilling, blasting, and excavating or by large-diameter shaft-boring equipment. Shaft boring is more frequently used, particularly on the smaller and shorter subshaft, which connect the different levels but do not extend to the surface.Haulage in the shaft is usually accomplished by hoisting of the filled mine cars on multistage cages or by skips. Pumping of coal slurry is also done in special cases.The complex system of forces and the resulting rock mechanical problems developed by mining activities at different levels result in significant differences between European and US underground development. The rock mechanical interaction of the extraction operations at the various levels require that all deposits be mined as completely as possible. Pillars left after mining create zones of extreme and often unmanageable ground control problem, as well as a high probability of roof bounce.Since the number of entries is kept to a minimum because of cost, no bleeder systems are provided. If retreat mining is practiced, only two entries are advanced in to a new mining area.Panels are laid out as large as possible. The large-panel layout is used as another means of reducing the number ofentries. Minded–out panels are sealed off to prevent spontaneous combustion through the removal of oxygen.The main levels, with extensive entry systems, are used for coal, supply, and personnel haulage and for ventilation. They are often spaced with little regard to the position of the coal seams, because the deposits are reached selectively through other means. In the past, 165-or330-ft intervals were selected while increasing ground pressures and development and maintenance increase substantially, requiring large volumes of air for cooling. As a result, entry cross sections at these levels have to be increase.Fig.9.1 German multilevel, multiseam shaft-type coal mine.Underground facilities：(1) main shaft with skip hoisting;(2) exhaust ventilation shaft with multistage cage;(3) third-level station;(4) blind shaft with cylindrical storage bin;(5) blind shaft with car-hoisting facilities;(6) main entry;(7) main entry;(8) section or panel entry;(9) road heading machine(10) longwall section with plow;(11) longwall section with shearer;(12) longwall section in a steeply pitching seam mined manually with air picks;(13) longwall section in steeply pitching seam with plow;(14) minded-out gob area;(15) ventilation lock;(16) belt conveyor as main haulage;(17) main car haulage;(18) storage bin and skip-loading facilities;(19) supply haulage with a mono-rail;(20) supply haulage with mine cars;(21) monorail system as personnel carrier;(22) worker-trip cars;(23) pump station. Surface facilities:(a) hoisting tower with overhead hoist;(b) shaft building;(c) head frame;(d) main exhaust fan and diffuser;(e) coal preparation plant with loading facilities;(f) coking coal silo;(g) container vehicle for filling of coke ovens;(h) coke oven battery;(i) coke watering car;(k) coke quenching tower;(l) gas tank;(m) water-treatment plant;(n) refuse pile;(o) power plant;(p) cooling tower;(q) water tower;(r) supply storage area;(s) sawmill;(t) training and teaching center.地下采煤目前，大部分欧洲的煤矿开采都已经达到了2000到4000英尺，主要是因为浅部容易开采的煤层都已经采完。

英文原文：Analytical model and application of stressdistribution on mining coal floorAbstract：Given the analysis of underground pressure，a stress calculation model of cola floor stress has been established based on a theory of elasticity．The model presents the law of stress distribution on the relatively fixed position of the mining coal floor：the extent of stress variation in a fixed floor position decreases gradually along with depth．The decreasing rate of the vertical stress is clearly larger than that of the horizontal stress at a specific depth．The direction of the maximum principal stress changes gradually from a vertical direction to a horizontal direction with the advance of the working face．The deformation and permeability of the rock mass of the coal floor are obtained by contrasting the difference of the principal stress established from theoretical calculations with curves of stress-strain and permeability-strain from tests．Which is an important mechanical basis for preventing water inrush from confined aquifers．Key words：model；coal floor；stress distribution；analysis1 IntroductionWith the development of coal seam mining，The stress field of rock strata of coal seam floors will change and continue to be redistributed because of the effect of mining．The results will bring on floor deformation，displacement and possible destruction to attain a new balance[1]．A study of the law of stress distribution of floors has important，practical implications in understanding deformation and destructive characteristics and predicting water inrush from floors and for designing suitable locations for tunnels and selecting maintenance methods when depth increased．At present，the study of the law of stress distribution of floors mostly proceeds from a number of calculations based on finite element analyses and similar material tests[2-6]．In this paper，the study of stress distribution of floors in relatively fixed positions is discussed analytically with a theory of elasticity and we present an application combined with actual data of a particular site．2 Fundamental principleThe formulas of stress distribution are derived from the superposition principle，given the theory of elasticity on distributed loads on a semi-infinite plane[7-8]．The vertical distribution load of AB on a semi-infinite plane is assumed to be q(x)，as illustrated in Fig.1.We want to solve the state of stress at a specific point inside a semi-infinite plane，such as point M ．Supposing the coordinate of point is (x，z)，the micro-1ength dζfrom the origin of coordinate is ζon the AB segment，the micro-concentration force d p=q dζis regarded as its force and the state of stress of the micro-concentration force at point is defined as follows．In order to calculate the stress at point M from all distributed loads，the stress which is caused by every micro-concentration force is superposed．We need to integrate Eq.(1) from ζ= -a to ζ= b and Eq.(1) then becomes：3 Stress calculation of coal seam floor3.1Foundation of the mechanical modelBased on the theory of underground pressure，the mechanical model of supporting pressure in front of the working face can be simplified，as shown in Fig.2[9-11]．Where the OA segment is the plastic area，with a length of x0；the AB segment is the elastic area，with a length of L0x0．In order to calculate easily the supporting pressure of both areas p z(1)，p z(2)，without losing its rational，we can assume the following two linear functions：Where is the supporting pressure of the plastic area(kPa)，the supporting pressure of the elastic area(kPa)，the maximum stress concentration coefficient，the width of the plastic area(m)，H the buried depth of the coal floor(m)，the width of the area affected by the supporting pressure(m) and is the average weight of the volume of the over-lying strata (kN/m3) ．3.2Stress calculation processAccording to the theory of elasticity on distributed loads on a semi-infinite plane，we can use Eq.(2) to calculate the vertical stresses σz(1) and σz(2) and the horizontal stresses σx(1)and σx(2)which are affected by the supporting pressures and ．The stress equations at point M(x, z) can then be obtained correspondingly by superposition (this calculation neglects the effect of the transferred load from the goaf and the overlying strata movement as well as the effect of the initial ground stress because it does not produce subsidiary stress at point M；largely we considered the action of the supporting pressure in front of the working face). The calculations are as follows：Therefore，σz = σz(1)+σz(2)(4) and σx = σx(1)+σx(2)(5). By coordinate transformation(x = x(n = 0，1，2，…))，x is regarded as x0 in Eqs.(4) and (5) and the stress values of each section can be calculated，where the variable expresses the relative distance from the pushing position of the working face to the origin of the coordinate system. Given the related parameters of supporting pressures，the stress values，located at the relatively fixed floor section，(x =) at different depths，can be calculated by computer when the working faces advance.When x = x，Eqs.(4) and (5) can be represented as follows：3.3Example analysisGiven the actual geological conditions and mining technology at the 2702 working face of the Yangcun Colliery of the Yanzhou Mining Group Limited Company，the following related parameters are determined：=3，=5 m，=50 m，=25 kN/m3 and H=500 ing Eqs.(6) and (7)，the stress distribution curves are obtained on the relatively fixed floor section x=at different depths with the working face advancing by calculation. The results are shown means of computer in Figs. 3 and 4.Fig. 3 shows that vertical stress maintains its maximum at the interface between the coal seam and floor on the section x=from the original coordinates and then quickly decreases with the increasing depth and slowly decreases at a specific depth. A similar situation is obtained when the working face advances，i.e.，the range of the vertical stress decreases with an increase in depth. From the results it can be seen that the range of depth, given the variation of vertical stress, is relatively large, i.e., within 40 m. The range of the vertical stress is clearly smaller after the working face advances 30 m.According to the relationship of the variation between vertical and horizontal stress, the multiplication of the variation of vertical stress and its corresponding coefficient of horizontal pressure (λ) is equal to the increment of horizontal stress at the point M[1]. Then the increment of horizontal stress and the horizontal stress at the point M continues to be superposed, which is inversed analysis when the working face advances 30 m. The results of the variation in stress show that the vertical stress is larger than the horizontal stress when the working face is at its original position: the maximum principal stress is the vertical stress; the minimum principal stress is horizontal stress. Because the rate of decrease of the vertical stress is faster than the horizontal stress, the horizontal stress is larger than the vertical stress within 42 m when the working face advances 30 m (for details, see Fig. 4). Considering the effect of the variation in vertical stress, the horizontal stress is much larger than the vertical stress. The maximum principal stress is the horizontal stress and the minimum principal stress is the vertical stress. It agrees with the partial reasons of the mechanical principle of floor heave[12-14].Fig. 3 also shows that the variation is almost steady on the section x=when the working face advances 30 m. Therefore, the relationship of variation in stress with depth is calculated when the working face advances from 0 to 30 m. The details are shown in Table 1.Table 1 Data of rock characteristics and correlative stress of the floor on 2702 working face in Yangcun colliery (MPa)岩层深度(m)ΔλλΔx=0 m x=30 m x=30 m x=30 mλΔ泥岩0 37.50 0.00 0.00 0.00 37.500.4316.13 16.13 5 27.25 0.04 2.12 2.08 27.21 11.70 13.78砂岩10 22.53 0.28 3.83 3.55 22.250.327.12 10.67 15 19.95 0.77 4.91 4.14 19.18 6.14 10.28 21 18.17 1.46 5.40 3.94 16.71 5.35 9.29石灰岩25 16.75 2.21 5.46 3.25 14.540.284.07 7.32 28 15.55 2.94 5.24 2.30 12.61 3.53 5.83From the analysis of the related data, the stresses + λΔin Table 1 can be regarded as the stress values，obtained from mechanical rock tests. So the variations of the principal stress from theoretical calculations and the results from the servo-controlled tests can be contrasted. Given these contrasts it is seen that, the largest stress value of mudstone is 16.13 MPa and the largest stress value of sandstone10.67 MPa. When combining Fig. 5 with Table 1 it is seen that, the largest calculated principal stress is less than the peak value of the principal stress in Fig. 5, and the calculated section is at an elastic deformation section of Fig. 5, where permeability is relatively weak. So there is still a certain ability of water resistance. It can be shown that the obvious destruction is not produced in the mudstone and sandstone when the working face advances 30 m. This is essentially consistent with the conclusions of the survey report.4 Conclusions1) Based on the mechanical model of the floor, the analysis of stress distribution is obtained on the relatively fixed floor position with an advancing of working face. Owing to heterogeneity and discontinuity of the rock mass of the coal floor, there is a certain divergence between the ideal model and actual conditions. But from analyses and calculations, the basic variation law of stress distribution is discovered on the relatively fixed floor position with an advancing of working face when specific parameters are given for the working face.2) The decreasing rate of the vertical stress is faster than that of the horizontal stress up to a certain depth and the direction of the maximum principal stress is changed from vertical at the original position to horizontal with an advancing of the working face. The horizontal stress is larger than vertical stress within 42 m when the working face advances 30 m.3) The difference between the theoretically calculated principal stress and the results of the servo-controlled penetrability test can be contrasted. Deformation and penetrability can be obtained from the floor rock mass. From an example, it is seen that the mudstone and sandstone of coal floor are at an elastic deformation stage. There is no extreme destruction on the relatively fixed floor section with an advancing of working face and there still is a certain ability of water resistanceAcknowledgementsHere we express our sincere appreciation to director for Zhao Zhenzhong, minister Song Shun of Zhengzhou Coal Industry Group for their help during the course of the sampling. Appreciating Dr. Xi Yantao of China University of Mining and Technology for his help for modification.References：[1] Zhang J C, Zhang Y Z, Liu T Q. Rock Mass Permeability and Coal Mine Water Inrush.Beijing:Geological Publishing House, 1997. (In Chinese)[2] Miao X X, Lu A H, Mao X B, et al. Numerical simulation for roadways in swelling rock undercoupling function of water and ground pressure. Journal of China University ofMining and Technology, 2002, 12(2): 120-125.[3] Gong P L, Hu Y Q, Zhao Y S, et al. Three-dimensional simulation study on law of deformationand breakage of coal floor on mining above aquifer. Chinese Journal of Rock Mechanics and Engineering, 2005, 24(23): 4396-4402. (In Chinese)[4] Shi L Q, Han J. Floor Water-Inrush Mechanism and Prediction. Xuzhou: China University ofMining and Technology Press, 2004. (In Chinese)[5] Jing H W, Xu G A, Ma S Z. Numerical analysis on displacement law of discontinuous rockmass in broken rock zone for deep roadway. Journal of China University of Mining and Technology, 2001, 11(2): 132-137.[6] Liu Y D, Zhang D S, Wang Ii S, et al. Simulation analysis of coal mining with top-coal cavingunder hard-and-thick strata. Journal of China University of Mining and Technology,2006, 16(2): 110-114.[7] Dun Z L, Gao J M. Mechanics of Elasticity and Its Application in Geotechnical Engineering.Beijing: China Coal Industry Publishing House, 2003. (In Chinese)[8] Xu Z L. A Concise Course in Elasticity. Beijing: Higher Education Press, 2002. (In Chinese)[9] Liu W Q, Miao X X. Numerical analysis of finite deformation of overbroken rock mass in gobarea based on Euler model of control volume. Journal of China University of Mining and Technology, 2006, 16(3): 245-248.[10] Jiang F X. Rock Pressure and Stress Control. Beijing: China Coal Industry Publishing House,2004. (In Chinese)[11] Qian M G, Shi P W. Rock Pressure and Stress Control. Xuzhou: China University of Miningand Technology Press, 2003. (In Chinese)[12] Xu N Z, Tu M. The mechanism and control of floor heave of road driving along next goaf ofhigh seam. Journal of Anhui University of Science and Technology (Natural Science), 2004, 24(2): 1-4. (In Chinese)[I3] Wang W J, Hou C J. Study of mechanical principle of floor heave of roadway driving along next goaf in fully mechanized sub-level caving face. Journal of Coal Science and Engineering, 2001, 7(1): 13-17.[14] Zhai X X, Li D Q, Shao Q, et al. Control over surrounding rocks deformation of soft floorand whole-coal gateways with trapezoidal supports. Journal of China University of Mining and Technology, 2005, 15(2): 118-123.中文译文：采场底板岩层应力的分析模型及应用摘要：在分析矿山压力的基础上，运用弹性理论建立了煤层底板应力分析计算模型。

采矿工程专业英语总结coalfield 煤田take 井田horizon 阶段mining district/area 采区sublevel 区段coalface 采煤工作面boundary 边界fault 断层normal fault 正断层reverse fault 逆断层fold 褶曲fracture 断裂structure 构造fissure 裂隙cract 裂缝geological structure 地质构造coal seam 煤层sedimentary rock 沉积岩igneous rock 火成岩strata(单数) stratum(复数) 岩层limestone 石灰岩sandstone 砂岩shalyrock 页岩coal bearing strata 煤系地层water bearing strata 含水层water resisting strata 隔水层coal seam 煤层false roof 伪顶floor 底板immediate roof 直接顶main roof 老顶rock property 岩性portal 井口shaft 井筒bottom 井底main shaft 主井subsidiary shaft 副井skip 箕斗cage 罐笼pumping room 泵房substation 变电所drain sump 水仓coal bunker 煤仓electric locomotive room 电机车库first-aid room 急救室explosive room 爆破器材库crosscut 石门horizon haulage lateral阶段运输大巷horizon ventilation lateral阶段回风大巷track/haulage/ventilation incline 轨道/运输/回风上山hoistor room 绞车房haulage/ventilation entry 运输/回风平巷head gate 进风巷tail gate 回风巷openoff cut 开切眼intake air 进风outtake air 回风power supply system 供电系统drainage system 排水系统grouting system 注浆系统material supply system 运料系统bolt 锚杆shearer 采煤机double ranging drum shearer 双滚筒可调高采煤机fixing drum 固定滚筒chain and flat conveyor 刮板输送机stage loader 装载机self-advancing powered support 自移式液压支架chock 支撑式shield 掩护式canopy 顶梁base 底座single hydraulic prop 单体液压支柱ventilating shaft 风井junction 马头门bottom station 井底车场inclined shaft 斜井adit 平硐roadway 巷道room/large opening 硐室steel rope 钢丝绳fresh/stale air 新/乏风gob/goaf 采空区hoisting system 提升系统hoistor 提升机（绞车）roadway layout 巷道布置mine design 矿井设计continuous miner 连续性采煤机Armored Face Conveyor 重型可弯曲刮板输送机top coal caving/sublevel caving 放顶煤。

采矿工程专业英语专业：矿业工程姓名：常晓贇学号：1370845Page1:Evidence of early copper mining exists in many parts of the world . For example , a recent archeometallurgical expedition has uncovered a prehistoric mining complex at PhuLon(“Bald Mountain”)on the Mekong River in Thailand , that ma y be dated as early as 2000BC.Workers at this complex used massive river cobble mauls to break the friable skarn matrix that held squatz veins rich in malachite (Pigott, 1988). The world's oldest known copper smelting furnace,dating to 3500BC, has been found near the modern Timna copper mine in Israel (Raymond , 1986).在世界上许多地方都有早期铜开采存在的证据。

例如，最近一个冶金考古探险队发现了一个史前采矿综合体在在泰国湄公河的PhuLon（“秃山”）上，这可能要追溯到公元前2000年。

工人们用大量鹅卵石撞击易碎的富含孔雀石的矽卡岩脉石（Pigott，1988）。

世界上已知的最古老的铜矿石冶炼炉可以追溯到公元前3500年，它被发现是在以色列的现在亭纳铜矿（Raymond，1986）。

The link between native copper and malachite might well have been suggested to Neolithic man by the common association of these two forms of the metal in outcrops.But the process by which he then learned how to extract copper from the malachite remains an historic mystery . One suggested answer is that both metal smelting and pottery making appeared to have evolved about the same time . The potter , the first technician in the management of heat , had under his control all the materials and conditions necessary for smelting copper(Raymond, 1986).自然铜矿和孔雀石之间的联系更可能被新石器时代的人建议为这两种金属露头形式之间常见的关联。

外文文献翻译英文原文High Productivity —A Question of Shearer Loader CuttingSequences1 AbstractRecently, the focus in underground longwall coal mining has been on increasing the installed motor power of shearer loaders and armoured face conveyors (AFC), more sophisticated support control systems and longer face length, in order to reduce costs and achieve higher productivity. These efforts have resulted in higher output and previously unseen face advance rates. The trend towards “bigger and better” equipment and layout schemes, however, is rapidly nearing the limitations of technical and economical feasibility. To realise further productivity increases, organisational changes of longwall mining procedures looks like the only reasonable answer. The benefits of opti-mised shearer loader cutting sequences, leading to better performance, are discussed in this paper.2 IntroductionsTraditionally, in underground longwall mining operations, shearer loaders produce coal using either one of the following cutting sequences: uni-directional or bi-directional cycles. Besides these pre-dominant methods, alternative mining cycles have also been developed and successfully applied in underground hard coal mines all over the world. The half-web cutting cycle as e.g. utilized in RA G Coal International’s Twentymile Mine in Colorado, USA, and the “Opti-Cycle” of Matla’s South African shortwall operation must be mentioned in this context. Other mines have also tested similar but modified cutting cycles resulting in improved output, e.g. improvements in terms of productiv-ity increases of up to 40 % are thought possible。

附录外文翻译APPLICATION OF BLASTING IN DRIVING TUNNEL1 FRAGMENTATIONFragmentation is the breaking of coal, ore,or rock by blasting so that the bulk of the material is small enough to load, handle and transport.Fragmentation would be at its best when the debris is not smaller than necessary for handling and not so large as to require hand breaking or secondary blasting .Energy must be supplied to rock by direct or indirect means to fragment that rock and the type of loading system.Fragmentation energy is consumed by the main mechanisms: (1) creation of new surface area (fracture energy), (2)friction (plasticity) and (3)elastic wave enegy dispersion.The loading method determines the relative proportions and the amount of energy consumed in fragmenting a given rock type. Unonfined tensile failure consumes the least energy with an increasing a,mount of energy required as the rock is more highly confined within a compressive stress field during fragmentation The way energy is applied by tools to cause rock or mineral fragmentation is important in determining fragmentation efficiency. To best design fragmentation tools and optimize fragmentation systems it would be desirable to know how rock properties influence breakage.The strength of rock is influenced by the environmental conditions imposed on the rock.Those of most importance in rock are (1)confining pressure ,(2)pore fluid pressure, (3)temperature and (4)rate of load application .Increase in confining pressure, as with increasing depth beneath th earth's surface or under the action of a fragmentation tool, causes an increase in rock strength .Apparent rock strength decreases as porc fluid pressure increases, since it decreases the effect of confining pressure. Although chemical effects of pore fluids influence rock strength, they generally are small compared to the confining pressure effect, except for a small minority of rock types .Increase in rock temperature causes a decrease in rock strength.This effect is very small because of the small ambient temperature changesfound during mining. An increase in rate of load application causes an apparent increase in rock strength.Rock exhibits directional properties that in fluence the way it breaks. These are embodied in the concept of rock fabric ,which connotes the structure or configuration of the aggregate components as well as the physical or mechanical property manifestations. Rock fabric ont only relates to the preferred orientation of mineral constituents and their planes of weakness, but also to the configuration of discontinuities, microcracks and pores.Joints and bedding planes have great influence on fragmentation at field scale.Physical properties of rock (density,indentation,hardness,abrasivehardness and porosity ,)are frequently used in conjunction with mechanical properties to develop better empirical esti mations of rock fragmentation.2 BLASTHOLE CHARGING METHODSDrill hole charging can be carried out in different ways depending on whether the explosive used is in cartridges or in the form of loose material. The oldest charging method implies the use of a tamping rod and this system is still used to a very great extent .During the last 20years, compressed air chargers have been used and these machines provide both good capacity and also an improved level of charge concentration so that the drill holes are utilized to a higher degree. During the last few years semi-automatic chargers have been taken into use, primarily in underground work. Compressed air chargers for blasting powder in the form of loose material have also come into use on a large scale. As far as slurry blasting is concerned, special pumping methods have been developed through which charging capacity in the case of large diameter drill holes is practically good.A tamping rod must be made of wood or plastic. It must not be too thick in relation to the drill hole diameter since this can crush and damage fuse or electric detonator cables during charging work. If a good degree of packing is to be obtained during charging with a tamping rod then only one cartridge at a time should be charged and tamped. The detonator must be correctly fed into the drill hole during charging work.Compressed air chargers have been in use is Sweden for about 20 years. The first type consisted of aluminum pipes connected together and the cartridges were blown into the hole with an air pressure of 42 pounds per square inch .since that time the charging tube has been replaced by anti-static treated plastic hose of a special design.A charger includes a foot-operated valve, reduction vavle with air hose, breech, connecting tube and charging hose.The semi-automatic charger permits the continuous insertion of explosive cartridge at the same rate as they are charged in the hole by the hose .Instead of a valve being used ,the cartridges pass through an air lock between two flaps. The air pressure in the charging hose is retained while cartridges are pressure in the charging hose is retained while cartridges are beins inserted .The semi-automatic charger permits considerably higher charging capacity than the normal type of charger.Explosives in the form of the form of loose material, usually ammonium nitrate explosives(ANFO), require special chargers. Two types can be differentiated: pressrure vessel machines and ejector units. Pressure vessel machines are particularly suitable for crystalline An explosives with good charging capacity. Ejector units are operate by an ejector sucking up explosive from a container through a charging hose. The explosive is then blown through the charging hose into the drill hole .There are, also combined pressure ejector machines. The charging hose used for ANFO charging operations must conduct electricity and have a resistance of at least 1KΏ/m and max.30KΏ/M.Nitro Nobel has developed a special pumping procedure which consists of a tanker vehicle which is used to pump explosive directly the drill holes. The charging capacity is very high in the case of large diameter drill holes.3 CONTROLLED BLASTING TECHNIQUTESControlled blasting is used to reduce overbreak and minimize fracturing of the rock at the boundary of an excavation. The four basic controlled blasting techniques are: line drilling, presplitting, cushion blasting and smooth blasting.Line drilling, the earliest controlled blasting technique, involves drilling a row of closely spaced holes along the final excavation line, providing a plane of weakness towhich to break. Line drill holes, 2or 4 diameters apart and contain no explosive. The blastholes adjacent to the line drillholes normally are loaded lighter and are on closer spacing than the other blastholes. The maximum depth for line drilling is about 30 ft .Line drilling involves no blasting in the final row of holes, and thus minimizes damage to the final wall.Presplitting, sometimes called preshearing ,involves a single row of boreholes ,usually 2 to 4 in .in diameter ,drilled along the final excavation at a spacing of 6 to 12 borehole diameters .Dynamite cartridges 1to 1.5 in . in size on 1 to 2 ft .centers usually are string-loadde on detonating cord ,although special small-diameter cartridges with special couplers are available for total column loading .In unconsolidated formations ,closer spacings with lighter powder loads are required .The bottom 2 to 3 ft .of borehole usually is loaded somewhat heavier than the remainder .Stemming between and around the individual charges is optional .The top 2 to 3 ft . of borehole is not loaded ,but is stemmed. The depth that can bu presplit is limited by hole alignment ,with 50 ft .being about maximum .The presplit holes are fired before before the adjacent primary holes to provide a fracture plane to which the primary blast can break .In presplitting it is difficult to determine the results until the adjacent primary blast is shot .For this reason ,presplitting too far in advance is not recommended .Presplitting seldom is done underground.Cushion blasting involves drilling a row of 2 – to 6-in .diameter boreholes along the final excavation line ,loading with a light well-distributed charge ,completely stemmed and firing after the main excavation is removed rather than before ,as in presplitting. The burden on the holes is slightly larger than the spacing .Wedges may be used to abut the charges to the excavation side of the borehole and minimize damage to the final wall .Eeplosive loading is similar to that in presplitting .Cushion blasting has been done to depths near 100 ft .in a single lift with the larger-diameter boreholes because alignment is more easily retained .Cushion blasting seldom is done underground.Smooth blasting is the underground counterpart of cushion blasting .At the perimeter of the tunnel or drift ,closely spaced holes with a burden-to-spacing rationear 1.5:1 are loaded with light well-distributed charges .Smooth blasting differs from cushion blasting in that (1) except at the collar ,the charges are not stemmed and (2) the perimeter holes are fired on the last delay in the same round as the primary blast .Total column loading is most common ,although spacers may be used .The holes are stemmed to prevent the charges from being pulled out by the detonation of the previous delayed holes .Smooth blasting reduces overbreak in a drift and also provides a more competent back requiring less support .It involves more perimeter holes than does normal blasting.Combinations of controlled blasting techniques are used .In unconsolidated rock,line drilling sometimes is desirable between presplit or cushion boreholes . Corners sometimes are presplit when cushion blasting is used.4 TUNNEL BLASTINGThe most common methed of driving a mining tunnel is a cyclic operation in three sequences:(1)Drilling shot holes ;charging them with explosives and blasting.(2)Removing the resulting muck pile.(3)Inserting the tunnel linings into the newly excaved area; and advancing the ralls. ventilation arrangements, and power supplies ready for the next cycle of operations.The basic principle of tunnel blasting ,in its simplest term, is to loosen a volume of the virgin rock in such a way that when it is removed the line of the tunnel has advance in the correct direction with as nearly as possible the correct cross-section.The dilling pattern in which the holes to receive the explosives are drilled into the working face is designed so that :the holes are easy to drill; the minimurd total quantity of explosive is required ;and the periphery of the space left after the blast conforms as nearly as possible to the required tunnel section.A blast round consists of cut ,relief, breast and trim holes . The cut portion is the most important . The objective of the cut is to provide a free face to which the remainder of the round may break.The two general types of cuts are the angled cut and the burn .These can be usedin combinations to form various other cuts .Angled cuts are more advantageous than burn in wide headings ,due to the fewer boles and less explosive required per foot .A disadvangtage is the possibility of large pieces of rock being thrown from the “V”.The wedge or V-cut consists of two holes angled to meet or nearly meet at the bottom . The cut can consist of one or several Vs, either verticao or horizontal .For deeper rounds or hard-breaking rock ,double Vs can be used .The smaller is called the baby cut . It is useful in small rge-diameter burn holes provide excellent relief in big headings .Burn cuts permit deeper rounds than angled cuts and , due to the increased advance per round ,may prove more economical .In burn cuts ,the holes must be drilled parallel , with proper spacing ,and 0.5 : 1 ft deeper than the remainder of the round .Usually ,one or more holes (large-diameter) are left unloaded to provide relief for the loaded holes . Various combinations of spacing ,alignment and holes loaded are possible.Innumerable typesofblastingrounds are used in underground headings .Even in the same heading the round may have to be altered as different rock charateristics develop.An important factor in any round is the firing sequence .In general ,the holes are fired so that each hole or series of holes is blasted to the free face provided by the preceding holes .The depth of drift rounds depends on the complete drifting cycle and drift size.A general rule is that a round will not break much deeper than the least cross-sectional dimension of the drift . Rounds can be arranged that provide certain muck-pile shapes and positions for more efficient loading and cycles . In drifts requiring close support , rounds can be arranged to prevent damage.爆破在岩巷掘进中的应用1 破岩理论破岩是用爆破的方式把煤、矿石或岩石破碎，以便于大部分物料的块度小到便于装载、处理和运输。

名词矿井 mine立井开拓 vertical shaft development可采储量 recoverable reserves集中大巷 gathering main roadway煤层 coal seam综合机械化 full-mechanized工作面 working face服务年限 length of service采煤工艺 coal winning technology斜井开拓 inclined shaft development走向长壁采煤法 longwall coal mining method肥煤 fat coal气煤 gas coal底卸式矿车 drop-bottom mine car固定车箱式矿车solid mine car矿车 mine car倾斜长壁采煤法 inclined longwall coal mining method走向 strike倾向 dip开拓方式 development way of mine采区 district盘区 panel带区 strip district矿井设计 mine design开采水平 mining level井田 shaft area采煤工艺 mining technology井底车场 shaft bottom石门 cross-cut主石门 main cross-cut采区石门 district cross-cut名词矿井 mine立井开拓 vertical shaft development可采储量 recoverable reserves集中大巷 gathering main roadway煤层 coal seam综合机械化 full-mechanized工作面 working face服务年限 length of service采煤工艺 coal winning technology斜井开拓 inclined shaft development走向长壁采煤法 longwall coal mining method肥煤 fat coal气煤 gas coal底卸式矿车 drop-bottom mine car固定车箱式矿车solid mine car矿车 mine car倾斜长壁采煤法 inclined longwall coal mining method走向 strike倾向 dip开拓方式 development way of mine采区 district盘区 panel带区 strip district矿井设计 mine design开采水平 mining level井田 shaft area采煤工艺 mining technology名词矿井 mine立井开拓 vertical shaft development可采储量 recoverable reserves集中大巷 gathering main roadway煤层 coal seam综合机械化 full-mechanized工作面 working face服务年限 length of service采煤工艺 coal winning technology斜井开拓 inclined shaft development走向长壁采煤法 longwall coal mining method肥煤 fat coal气煤 gas coal底卸式矿车 drop-bottom mine car固定车箱式矿车solid mine car矿车 mine car倾斜长壁采煤法 inclined longwall coal mining method走向 strike倾向 dip开拓方式 development way of mine采区 district盘区 panel带区 strip district矿井设计 mine design开采水平 mining level井田 shaft area采煤工艺 mining technology名词矿井 mine立井开拓 vertical shaft development可采储量 recoverable reserves集中大巷 gathering main roadway煤层 coal seam综合机械化 full-mechanized工作面 working face服务年限 length of service采煤工艺 coal winning technology斜井开拓 inclined shaft development走向长壁采煤法 longwall coal mining method肥煤 fat coal气煤 gas coal底卸式矿车 drop-bottom mine car固定车箱式矿车solid mine car矿车 mine car倾斜长壁采煤法 inclined longwall coal mining method走向 strike倾向 dip开拓方式 development way of mine采区 district盘区 panel带区 strip district矿井设计 mine design开采水平 mining level井田 shaft area采煤工艺 mining technology。

Introduction （绪论）mine n. 矿山，矿井。

v. 米矿colliery n. 矿井coal mining 采煤underground mining 地下开采surface mining 露天开采reserve n. 储量coal-bearing adj. 含煤的high production and high efficiency 高产高效development n. 开拓preparation n. 准备mining method 采煤方法subside v. 下沉，沉陷subsidence n. 沉降，沉陷mining subsidence n. 开采沉陷mechanize v. 使… 机械化mechanization n. 机械化blind shaft 暗立井drawn shaft 溜井chute n. 溜煤眼adit n. 平硐drift n. 平硐crosscut n. 联络巷；石门coal crosscut 煤门entry n. 平巷haulage n. 运输main haulage roadway 主要运输平巷main return-air roadway 主要回风平巷head entry 区段运输平巷tail entry 区段回风平巷slope n. 斜井rise n. 上山dip n. 下山rock rise 岩石上山coal rise 煤层上山coal haulage rise 运煤上山Chapter 1 Basic Concepts of Mine （矿井基本概念）coalfield n. 煤田mining area n. 矿区mine field n. 井田divide v. 戈Ll 分division n. 戈Ll 分material transporting rise 运料上山return-air rise 回风上山men-walking rise 行人上山inclined roadway of a strip 分带斜巷inclined coal haulage roadway of a strip运煤斜巷分带mine production capacity 能力(MPC) 矿井生产inclined material haulage roadway of a strip分带运料斜巷mine service life 矿井服务年限production scale of mine 井型small mine 小型矿井middle mine 中型矿井large mine 大型矿井huge mine 特大型矿井strike n. 走向dip n. 倾向dip angle 倾角workable adj. 可采的workable reserve n. 可采储量opening n. 通道，开口mine opening n. 矿山井巷passageway n. 通道shaft n. 立井roadway n. 巷道chamber n. 硐室main shaft 主立井auxiliary shaft 畐廿立井air shaft 风井development roadway 开拓巷道preparation roadway 准备巷道gateway 回采巷道pit bottom 井底车场shaft bottom 井底车场station n. 车场，车站mining district station 采区车场horizon n. 阶段level n. 水平haulage level 运输水平return-air level 回风水平mining level 开采水平interval between levels 阶段垂高mining district 采区panel n. 盘区sublevel n. 分段strip district n. 带区inclined length 斜长strike length 走向长度district sublevel 区段Open-off cut n. 切眼coalface n. 采煤面working face 工作面production n. 生产；产量production system 生产系统coal haulage system 运煤系统ventilation n. 通风ventilation system 通风系统fresh air 新鲜风dirty air 乏风，污风refuse n. 矸石material and refuse transportation system 运料排矸系统drain v. 排水drainage system 排水系统power supply system （electric power, compressedair）动力供应（电、压风）communication and monitoring system 通讯、监测系统drive v. 掘进excavate v. 开挖，开掘hoist v. 提升winch n. 绞车Chapter 2 Coal Mining methods 采煤方法）stope 采场mining works/units 回采工作basic operation 基本工序break v. 破碎load v. 装载haul v. 运输auxiliary operations 辅助工序roof support 顶板支护gob treatment 采空区处理auxiliary transportation 辅助运输ventilation 通风drainage 排水power supply 供电,emulsion supply 供液（乳化液）等winning/mining technique 采煤工艺mining system 采煤系统mining roadway layout 回采巷道布置classify v. 分类dry mining 旱采wall mining system 壁式开采full-seam mining 整层single longwall mining methodlongwall mining on strike 走向长壁开采longwall mining on inclineii 倾向长壁开采sublevel caving 放顶煤shield 掩护支架slicing method 分层inclined slicing 倾斜分层horizontal slicing 水平分层oblique slicing 斜切分层top-slicing system of sublevel caving 水平分段放顶煤pillar mining system 柱式开采room and pillar mining method 房柱式room method 房式hydraulic mining 水采underground liquefaction 地下液化和气化underground gasification 地下液化和气化roof caving 垮落法（自然垮落、强制放顶）packing 充填法pillar support 刀柱式nearly horizontal coal seam 近水平煤层gently inclined coal seam 缓斜煤层inclined coal seam 倾斜煤层steeply inclined〜急倾斜厚煤层：thin coal seam 薄煤层middle thick coal seam 中厚煤层thick coal seam 厚煤层steeply inclined coal seam with an hugethickness 急倾斜特厚煤层blasting mining technology 炮采conventionally mechanized mining technology 普通机械化采煤工艺fully mechanized mining technology 综合机械化采煤工艺fully mechanized mining with top coal cavingtechnology 综采放顶煤工艺continuous miner 连续采煤机shuttle car n. 梭车universal extensible conveyor 万向接长机bolt v. 打锚杆；n. 锚杆mining method 采矿方法；mining operation 采矿作业；单一长壁采煤法ground control 顶板管理；recovery 回采率；subsidence control 地表沉陷控制cover 覆盖层；overburden 上覆地层；immediate roof 直接顶；floor 底板；hardness 硬度；strength 强度cleavage 解理gas , methane 瓦斯daily operation 日常工作single operation 单一工序unit operation 单元作业auxiliary operation 辅助作业cutting n. 切割，掏槽；lighting n. 照明outcrop 露头，露出地面的岩层development stage 开拓阶段production stage 生产阶段haulage capacity 运输能力main entry 主巷barrier pillar 隔离煤柱butt entry 区段平巷shearer 滚筒采煤机planer ，Plow 刨煤机auger mining 螺旋钻开采rapid excavation 快速掘进ocean mining 海洋采矿Chapter3 Concepts of Mine Development 田开拓的概念)mine boundary 井田边界terrain n. 地形geological structure 地质构造fault n. 断层fold n. 褶皱down fold n. 背斜upfold n. 向斜coal quality 煤质occurrence 赋存mine geological reserve usable reserves ( A 储量temprary useless resrves 暂不能利用储量mine industrial reserveZg=(A +B + C) 矿井工业储量future reserve ( D) 远景储量workable reserve 开采储量designed lost reserve 设计煤炭损失recovery rate 回采率Mine Production Capacity (MPC) coalface output 采煤工作面产量mining district production capacity能力cost per ton coal product 吨煤成本mine service life 矿井使用年限mine field development 井田开拓development roadway 开拓巷道development way 开拓方式development system 开拓系统portal type 井筒类型shaft development 立井开拓combined development 综合开拓development roadway layout 开拓巷道布置main roadway for single seam 分层大巷gathering main roadway 集中大巷gatering main roadway for each coal seam group分组集中大巷single level 单水平mutiple level 多水平preparation type 准备方式rise type 上山式rise and dip Type 上下山式combined rises and dip 上山、上下山混合式industrial area 工业场地mining level 开采水平pit bottom 井底车场development deepening 开拓延深replacement of mining level 水平接替transportation facility 运输设备electromechanical mine operation 矿井机电作业capital investment 基本建设投资。