problems inherent from the large sizes data mining algorithms are able to separate the effects of such irrelevant attributes in determining the actual. KDS 2005 Section 2: Data Mining and Knowledge Discovery Section 2. Data Mining and Knowledge Discovery 2.1. Actual Problems of Data Mining. Data Quality Problems in Process Mining and What To Do About Them — Part 7: Recorded Timestamps Do Not Reflect Actual Time of Activities Anne 7 Sep 2.
mining» mining.mst.edu» research» depexpmine enabling them to develop an understanding of some of the engineering problems that occur in actual mining. Deep Sea mining, like asteroid mining Actual mining for REEs has not been attempted because of environmental issues this problem is not be nearly as. problems inherent from the large sizes data mining algorithms are able to separate the effects of such irrelevant attributes in determining the actual. KDS 2005 Section 2: Data Mining and Knowledge Discovery Section 2. Data Mining and Knowledge Discovery 2.1. Actual Problems of Data Mining. Data Quality Problems in Process Mining and What To Do About Them — Part 7: Recorded Timestamps Do Not Reflect Actual Time of Activities Anne 7 Sep 2.
12350 Spencer Road
Rolla, MO 65401
With the assistance of the minerals industry, students are introduced to current equipment and mining practices, enabling them to develop an understanding of some of the engineering problems statistical data mining occur in actual mining situations, actual problems of mining. Students in the surveying class, for example, actual problems of mining, gain "hands-on" experience with a variety of equipment and techniques and encounter the actual problems of time limitation and weather. In addition, mining and geological engineering students are able to design, drill and blast drift openings; test their mental and physical skills; and obtain an understanding of the various situations involved in a working mine.
The Rock Mechanics and Explosives Research Center, a research facility of the School of Materials, Energy and Earth Resources, uses the Experimental Mine for many research projects. Projects sponsored by industry and government provide part-time employment opportunities for undergraduate and graduate students, as well as valuable engineering and research experience.
Our mine rescue teams use the mine to practice real life scenarios and compete against industry teams from across the nation. Our mucking teams also use the mine to train for competitions on an international level.
The mine also serves as an introduction to the mineral industry in Missouri for the public through guided tours and various informational programs. It is the filming site for the lab portions actual problems of mining the Discovery series "The Detonators". Each summer Explosives Camp is offered for rising 11th and 12th grade students. It is the first and only camp geared to students interested in explosives engineering.
History of the Mine
The initial purchase of land for the Experimental Mine was made in 1914 from Edwin Long, and an underground mine and quarry were subsequently developed on the property for use by Missouri S&T's department of mining engineering.
By 1921, a horizontal opening (adit) had been driven into bedrock, actual problems of mining is a dolomite limestone of the Jefferson City formation. Several structures also were completed by this time, including housing for a steam boiler, air compressor, blacksmith shop and mine hoist.
By 1945, a major part of the current room and pillar underground mine had been completed, one quarry had been developed and three vertical shafts had been installed. The original buildings were reconditioned during the next four years, and a new mine office-changehouse-warehouse building was constructed in 1949.
The expanded activity at the mien brought about the need for additional surface and underground space. Twelve acres of adjacent land were purchased from the Long estate in 1949, completing the 19 acres of the current site. About six acres of land was reserved as a right of way for the Frisco Railroad (Burlington-Northern).
By 1951 the west drift openings were completed. In 1956, a building was constructed to house the newly purchased ventilation fans and a second quarry was initiated, actual problems of mining. By this time, student and faculty research in rock mechanics, drilling, blasting, and explosives testing was under way. Research in these areas continued throughout the 60s and 70s and drift work was developed on the east side of the mine. Use of the mine increased through the 1970s and is used heavily today by students in geological and mining engineering. A classroom extension to the mine office building has been added along with a fourth shaft, a second underground mine for research purposes, two surface sites for blasting research and mining equipment donated by manufacturers.
Missouri S&T Experimental Mine today.
Future of the Mine
On April 20, 2010 ground was broken on a new mine building. The new facility will house three new laboratories, mine rescue and mucking stations, separate mine dry houses for men and women, three new classrooms, offices, warehouse space, and a historic center for the mining industry. The generous donations from industry partners will ensure we continue to have excellent equipment for educating our students.
Deep Sea MiningData Quality Problems in Process Mining and What To Do About Them — Part 7: Recorded Timestamps Do Not Reflect Actual Time of Activities Anne 7 Sep 2. 1 INTRODUCTION TO MINING 1.1 MINING’S CONTRIBUTION TO CIVILIZATION Mining may well have been the second of humankind’s earliest endeavors— granted that. The General Mining Act of 1872 is a United States federal law that authorizes and governs prospecting and and defer to the miners in actual possession of the. Mining: Mining, process of Water inflow was a very important problem in underground mining until James Watt invented the steam engine in the In an actual. Apr 08, 2013 · Mining bitcoins – a eventually cost more than the actual bitcoins are worth. Pooled mining of machines at the problem and gather. by using Analytic Services in general and the Analytic Services Data Mining using analytic services data mining framework for indicating the actual.
KDS 2005 Section 2: Data Mining and Knowledge Discovery Section 2. Data Mining and Knowledge Discovery 2.1. Actual Problems of Data Mining. Why SAP Process Mining by SAP Process Mining. The modular structure of SAP Process Mining allows you to processes based on actual transactional data to. If you could come up with a useful problem space that was really huge, you could use the hash of the block to select the problem, then solve it (or some number of problems to vary the difficulty). The problem space would have to be large enough that the chances of someone having already solved the problem selected by a block is negligible.
Mining, process of extracting useful minerals from the surface of the Earth, including the seas. A mineral, with a few exceptions, is an inorganic substance occurring in nature that has a definite chemical composition and distinctive physical properties or molecular structure. (One organic substance, coal, is often discussed as a mineral as well.) Ore is a metalliferous mineral, or an aggregate of metalliferous minerals and gangue (associated rock of no economic value), that can be mined at a profit. Mineral deposit designates a natural occurrence of a useful mineral, while ore deposit denotes a mineral deposit of sufficient extent and concentration to invite exploitation.
When evaluating mineral deposits, it is extremely important to keep profit in mind. The total quantity of mineral in a given deposit is referred to as the mineral inventory, but only that quantity which can be mined at a profit is termed the ore reserve. As the selling price of the mineral rises or the extraction costs fall, the proportion of the mineral inventory classified as ore increases. Obviously, the opposite is also true, and a mine may cease production because (1) the mineral is exhausted or (2) the prices have dropped or costs risen so much that what was once ore is now only mineral.
Archaeological discoveries indicate that mining was conducted in prehistoric times. Apparently, the first mineral used was flint, which, because of its conchoidal fracturing pattern, could be broken into sharp-edged pieces that were useful as scrapers, knives, and arrowheads. During the Neolithic Period, or New Stone Age (about 8000–2000 bce), shafts up to 100 metres (330 feet) deep were sunk in soft chalk deposits in France and Britain in order to extract the flint pebbles found there. Other minerals, such as red ochre and the copper mineral malachite, were used as pigments. The oldest known underground mine in the world was sunk more than 40,000 years ago at Bomvu Ridge in the Ngwenya mountains, Swaziland, to mine ochre used in burial ceremonies and as body colouring.
Gold was one of the first metals utilized, being mined from streambeds of sand and gravel where it occurred as a pure metal because of its chemical stability. Although chemically less stable, copper occurs in native form and was probably the second metal discovered and used. Silver was also found in a pure state and at one time was valued more highly than gold.
According to historians, the Egyptians were mining copper on the Sinai Peninsula as long ago as 3000 bce, although some bronze (copper alloyed with tin) is dated as early as 3700 bce. Iron is dated as early as 2800 bce; Egyptian records of iron ore smelting date from 1300 bce. Found in the ancient ruins of Troy, lead was produced as early as 2500 bce.
One of the earliest evidences of building with quarried stone was the construction (2600 bce) of the great pyramids in Egypt, the largest of which (Khufu) is 236 metres (775 feet) along the base sides and contains approximately 2.3 million blocks of two types of limestone and red granite. The limestone is believed to have been quarried from across the Nile. Blocks weighing as much as 15,000 kg (33,000 pounds) were transported long distances and elevated into place, and they show precise cutting that resulted in fine-fitting masonry.
One of the most complete early treatments of mining methods in Europe is by the German scholar Georgius Agricola in his De re metallica (1556). He describes detailed methods of driving shafts and tunnels. Soft ore and rock were laboriously mined with a pick and harder ore with a pick and hammer, wedges, or heat (fire setting). Fire setting involved piling a heap of logs at the rock face and burning them. The heat weakened or fractured the rock because of thermal expansion or other processes, depending on the type of rock and ore. Crude ventilation and pumping systems were utilized where necessary. Hoisting up shafts and inclines was done with a windlass; haulage was in “trucks” and wheelbarrows. Timber support systems were employed in tunnels.
Great progress in mining was made when the secret of black powder reached the West, probably from China in the late Middle Ages. This was replaced as an explosive in the mid-19th century with dynamite, and since 1956 both ammonium nitrate fuel-blasting agents and slurries (mixtures of water, fuels, and oxidizers) have come into extensive use. A steel drill with a wedge point and a hammer were first used to drill holes for placement of explosives, which were then loaded into the holes and detonated to break the rock. Experience showed that proper placement of holes and firing order are important in obtaining maximum rock breakage in mines.
The invention of mechanical drills powered by compressed air (pneumatic hammers) increased markedly the capability to mine hard rock, decreasing the cost and time for excavation severalfold. It is reported that the Englishman Richard Trevithick invented a rotary steam-driven drill in 1813. Mechanical piston drills utilizing attached bits on drill rods and moving up and down like a piston in a cylinder date from 1843. In Germany in 1853 a drill that resembled modern air drills was invented. Piston drills were superseded by hammer drills run by compressed air, and their performance improved with better design and the availability of quality steel.
Developments in drilling were accompanied by improvements in loading methods, from handloading with shovels to various types of mechanical loaders. Haulage likewise evolved from human and animal portage to mine cars drawn by electric locomotives and conveyers and to rubber-tired vehicles of large capacity. Similar developments took place in surface mining, increasing the volume of production and lowering the cost of metallic and nonmetallic products drastically. Large stripping machines with excavating wheels used in surface coal mining are employed in other types of open-pit mines.
Water inflow was a very important problem in underground mining until James Watt invented the steam engine in the 18th century. After that, steam-driven pumps could be used to remove water from the deep mines of the day. Early lighting systems were of the open-flame type, consisting of candles or oil-wick lamps. In the latter type, coal oil, whale oil, or kerosene was burned. Beginning in the 1890s, flammable acetylene gas was generated by adding water to calcium carbide in the base of a lamp and then released through a jet in the centre of a bright metal reflector. A flint sparker made these so-called carbide lamps easy to light. In the 1930s battery-powered cap lamps began entering mines, and since then various improvements have been made in light intensity, battery life, and weight.
Although a great deal of mythic lore and romance has accumulated around miners and mining, in modern mining it is machines that provide the strength and trained miners who provide the brains needed to prevail in this highly competitive industry. Technology has developed to the point where gold is now mined underground at depths of 4,000 metres (about 13,100 feet), and the deepest surface mines have been excavated to more than 700 metres (about 2,300 feet).George B. ClarkWilliam Andrew Hustrulid
Prospecting and exploration
Various techniques are used in the search for a mineral deposit, an activity called prospecting. Once a discovery has been made, the property containing a deposit, called the prospect, is explored to determine some of the more important characteristics of the deposit. Among these are its size, shape, orientation in space, and location with respect to the surface, as well as the mineral quality and quality distribution and the quantities of these different qualities.
In searching for valuable minerals, the traditional prospector relied primarily on the direct observation of mineralization in outcrops, sediments, and soil. Although direct observation is still widely practiced, the modern prospector also employs a combination of geologic, geophysical, and geochemical tools to provide indirect indications for reducing the search radius. The object of modern techniques is to find anomalies—i.e., differences between what is observed at a particular location and what would normally be expected. Aerial and satellite imagery provides one means of quickly examining large land areas and of identifying mineralizations that may be indicated by differences in geologic structure or in rock, soil, and vegetation type. In geophysical prospecting gravity, magnetic, electrical, seismic, and radiometric methods are used to distinguish such rock properties as density, magnetic susceptibility, natural remanent magnetization, electrical conductivity, dielectric permittivity, magnetic permeability, seismic wave velocity, and radioactive decay. In geochemical prospecting the search for anomalies is based on the systematic measurement of trace elements or chemically influenced properties. Samples of soils, lake sediments and water, glacial deposits, rocks, vegetation and humus, animal tissues, microorganisms, gases and air, and particulates are collected and tested so that unusual concentrations can be identified.
On the basis of such studies, a number of prospects are identified. The most promising of these becomes the focus of a field exploration program. Several exploration techniques are used, depending on the type of deposit and its proximity to the surface. When the top of a deposit intersects the surface, or outcrops, shallow trenches may be excavated with a bulldozer or backhoe. Trenching provides accurate near-surface data and the possibility of collecting samples of large volume for testing. The technique is obviously limited to the cutting depth of the equipment involved. Sometimes special drifts are driven in order to explore a deposit, but this is a very expensive and time-consuming practice. In general, the purpose of driving such drifts is to provide drilling sites from which a large volume can be explored and a three-dimensional model of the potential ore body developed. Old shafts and drifts often provide a valuable and convenient way of sampling existing reserves and exploring extensions.
The most widely used exploration technique is the drilling of probe holes. In this practice a drill with a diamond-tipped bit cuts a narrow kerf of rock, extracting intact a cylindrical core of rock in the centre (seecore sampling). These core holes may be hundreds or even thousands of metres in length; the most common diameter is about 50 mm (2 inches). The cores are placed in special core boxes in the order in which they were removed from the hole. Geologists then carefully describe, or log, the core in order to determine the location and kinds of rock and mineral present; the different structural features such as joints, faults, and bedding planes; and the strength of the rock material. Cores are often split lengthwise, with one half being sent to a laboratory so that the grade, or content, of mineralization can be determined.
Normally, core holes are drilled in a more or less regular pattern, and the locations of the holes are plotted on plan maps. In order to visualize how the deposit appears at depth, holes are also plotted along a series of vertical planes called sections. The geologist then examines each section and, on the basis of information collected from the maps and core logs as well as his knowledge of the structures present, fills in the regions lying between holes and between planes. This method of constructing an ore body is widely used where the boundaries between ore and waste are sharp and where medium to small deposits are mined by underground techniques, but, in the case of large deposits mined by open-pit methods, it has largely been replaced by the use of block models. These will be discussed in more detail below (seeSurface mining).
Mineral deposits have different shapes, depending on how they were deposited. The most common shape is tabular, with the mineral deposit lying as a filling between more or less parallel layers of rock. The orientation of such an ore body can be described by its dip (the angle that it makes with the horizontal) and its strike (the position it takes with respect to the four points of the compass). Rock lying above the ore body is called the hanging wall, and rock located below the ore body is called the footwall.
The concentration of a valuable mineral within an ore is often referred to as its grade. Grade may exhibit considerable variation throughout a deposit. Moreover, there is a certain grade below which it is not profitable to mine a mineral even though it is still present in the ore. This is called the mine cutoff grade. And, if the material has already been mined, there is a certain grade below which it is not profitable to process it; this is the mill cutoff grade. The grade at which the costs associated with mining and mineral processing just equal the revenues is called the break-even grade. Material having a higher grade than this would be considered ore, and anything below that would be waste.
Therefore, in determining which portion of a mineral can be considered an exploitable ore reserve, it is necessary to estimate extraction costs and the price that can be expected for the commodity. Extraction costs depend on the type of mining system selected, the level of mechanization, mine life, and many other factors. This makes selecting the best system for a given deposit a complex process. For example, deposits outcropping at the surface may initially be mined as open pits, but at a certain depth the decision to switch to underground mining may have to be made. Even then, the overall cost per ton of ore delivered to the processing plant would be significantly higher than from the open pit; to pay for these extra costs, the grade of the underground ore would have to be correspondingly higher.
It has been estimated that more than two-thirds of the world’s yearly mineral production is extracted by surface mining. There are several types of surface mining, but the three most common are open-pit mining, strip mining, and quarrying. These differ from one another in the mine geometries created, the techniques used, and the minerals produced.
Open-pit mining often (but not always) results in a large hole, or pit, being formed in the process of extracting a mineral. It can also result in a portion of a hilltop being removed. In strip mining a long, narrow strip of mineral is uncovered by a dragline, large shovel, or similar type of excavator. After the mineral has been removed, an adjacent strip is uncovered and its overlying waste material deposited in the excavation of the first strip. Since strip mining is primarily applied to thin, flat deposits of coal, it is not discussed here (seecoal mining).
There are two types of quarrying. There is the extraction of ornamental stone blocks of specific colour, size, shape, and quality—an operation requiring special and expensive production procedures. In addition, the term quarrying has been applied to the recovery of sand, gravel, and crushed stone for the production of road base, cement, concrete, and macadam. However, since the practices followed in these operations are similar to those of open-pit mines, the discussion of quarrying here is limited to the excavation of ornamental stone.
Deposits mined by open-pit techniques are generally divided into horizontal layers called benches. The thickness (that is, the height) of the benches depends on the type of deposit, the mineral being mined, and the equipment being used; for large mines it is on the order of 12 to 15 metres (about 40 to 50 feet). Mining is generally conducted on a number of benches at any one time. The top of each bench is equivalent to a working level, and access to different levels is gained through a system of ramps. The width of a ramp depends on the equipment being used, but typical widths are from 20 to 40 metres (65 to 130 feet). Mining on a new level is begun by extending a ramp downward. This initial, or drop, cut is then progressively widened to form the new pit bottom.
The walls of a pit have a certain slope determined by the strength of the rock mass and other factors. The stability of these walls, and even of individual benches and groups of benches, is very important—particularly as the pit gets deeper. Increasing the pit slope angle by only a few degrees can decrease stripping costs tremendously or increase revenues through increased ore recovery, but it can also result in a number of slope failures on a small or large scale. Millions of tons of material may be involved in such slides. For this reason, mines have ongoing slope-stability programs involving the collection and analysis of structural data, hydrogeologic information, and operational practices (blasting, in particular), so that the best slope designs may be achieved. It is not unusual for five or more different slope angles to be involved in one large pit.
As a pit is deepened, more and more waste rock must be stripped away in order to uncover the ore. Eventually there comes a point where the revenue from the exposed ore is less than the costs involved in its recovery. Mining then ceases. The ratio of the amount of waste rock stripped to ore removed is called the overall stripping ratio. The break-even stripping ratio is a function of ore value and the costs involved.
The first step in the evaluation and design of an open-pit mine is the determination of reserves. As was explained above, information regarding the deposit is collected through the drilling of probe holes. The locations of the holes are plotted on a plan map, and sections taken through the holes give a good idea of the ore body’s vertical extent. From these vertical sections the tentative locations of the benches are selected. However, since the deposit is to be mined in horizontal benches, it is also convenient to calculate the ore reserve in horizontal sections, with the thickness of each section equal to the height of a bench. These horizontal sections are divided along coordinate lines into a series of blocks, with the plan dimensions (i.e., the length and width) of each block generally being one to three times the bench height. After the grade of each block has been determined, the blocks are assembled into a block model representation of the ore body. (This model must be significantly larger than the actual ore reserve in order to include the eventual pit that must be dug to expose the ore body.)
Economic factors such as costs and expected revenues, which vary with grade and block location, are then applied; the result is an economic block model. Some of the blocks in the model will eventually fall within the pit, but others will lie outside. Of the several techniques for determining which of the blocks should be included in the final pit, the most common is the floating cone technique. In two dimensions the removal of a given ore block would require the removal of a set of overlying blocks as well. All of these would be included in an inverted triangle with its sides corresponding to the slope angle, its base lying on the surface, and its apex located in the ore block under consideration. In an actual three-dimensional case, this triangle would be a cone. The economic value of the ore block at the apex of the cone would be compared with the total cost of removing all of the blocks included in the cone. If the net value proved positive, then the cone would be mined. This technique would be applied to all of the blocks making up the block model, and at the end of this process a final pit outline would result.
The largest open-pit operations can move almost one million tons of material (both ore and waste) per day. In smaller operations the rate may be only a couple of thousand tons per day. In most of these mines there are four unit operations: drilling, blasting, loading, and hauling.
In large mines rotary drills are used to drill holes with diameters ranging from 150 to 450 mm (about 6 to 18 inches). The drill bit, made up of three cones containing either steel or tungsten carbide cutting edges, is rotated against the hole bottom under a heavy load, breaking the rock by compression and shear. An air compressor on the drilling machine forces air down the centre of the drill string so that the cuttings are removed. In smaller pits holes are often drilled by pneumatic or hydraulic percussion machines. These rigs may be truck- or crawler-mounted. Hole diameters are often in the range of 75 to 120 mm (about 3 to 5 inches).
Holes are drilled in special patterns so that blasting produces the types of fragmentation desired for the subsequent loading, hauling, and crushing operations. These patterns are defined by the burden (the shortest distance between the hole and the exposed bench face) and the spacing between the holes. Generally, the burden is 25 to 35 times the diameter of the blasthole, depending on the type of rock and explosive being used, and the spacing is equal to the burden.
There are a number of explosives used, but most are based on a slurry of ammonium nitrate and fuel oil (ANFO), which is transported by tanker truck and pumped into the holes. When filled with ANFO, a blasthole 400 mm (about 16 inches) in diameter and 7.5 metres (about 25 feet) deep can develop about one billion horsepower. It is incumbent upon those involved in the drilling and blasting to turn this power into useful fragmentation work. To achieve the proper fragmentation, a series of blastholes is generally shot in a carefully controlled sequence.
The object of blasting is to fragment the rock and then displace it into a pile that will facilitate its loading and transport. In large open pits the main implements for loading are electric, diesel-electric, or hydraulic shovels, while electric or mechanical-drive trucks are used for transport. The size of the shovels is generally specified by dipper, or bucket, size; those in common use have dipper capacities ranging from 15 to 50 cubic metres (20 to 65 cubic yards). This means that 30 to 100 tons can be dug in a single “bite” of the shovel. The size of the trucks is matched to that of the shovel, a common rule of thumb being that the truck should be filled in four to six swings of the shovel. Thus, for a shovel of 15-cubic-metre capacity, a truck having a capacity of 120 to 180 tons (four to six swings) should be assigned. The largest trucks have capacities of more than 350 tons (about 12 swings) and are equipped with engines that produce more than 3,500 horsepower; their tire diameters are often more than 3 metres (10 feet). Because of their high mobility, very large-capacity wheel loaders (front-end loaders) are also used in open-pit mines.
As pits became deeper—the deepest pits in the world exceed 800 metres (2,600 feet)—alternate modes of transporting broken ore and waste rock became more common. One of these is the belt conveyor, but in general this method requires in-pit crushing of the run-of-mine material prior to transport. For most materials a maximum angle of 18° is possible. To transport directly up the sides of pit walls, special conveying techniques are under development.
After loading, waste rock is transported to special dumps, while ore is generally hauled to a mineral-processing plant for further treatment. (In some cases ore is of sufficiently high quality for direct shipment without intermediate processing.) In some operations separate dumps are created for the various grades of sub-ore material, and these dumps may be re-mined later and processed in the mill. Certain dumps can be treated by various solutions to extract the contained metals (a process known as heap leaching or dump leaching).
Although seldom used to form entire structures, stone is greatly valued for its aesthetic appeal, durability, and ease of maintenance. The most popular types include granite, limestone, sandstone, marble, slate, gneiss, and serpentine. All natural stone used for structural support, curtain walls, veneer, floor tile, roofing, or strictly ornamental purposes is called building stone, and building stone that has been cut and finished for predetermined uses in building construction and monuments is known as dimension stone. The characteristics required of good dimension stone are uniformity of texture and colour, freedom from flaws, suitability for polishing and carving, and resistance to weathering. This section describes the quarrying of dimension stone.
Although quarrying is also done underground, using room-and-pillar techniques, most quarries involve the removal of blocks from hillsides or from an open-pit type of geometry. The first step in developing such a quarry is the removal of the vegetative cover of trees and underbrush. Next, the overburden of topsoil and subsoil is removed and stockpiled for future reclamation. The rock is quarried in a series of benches or slices corresponding to the thickness of the desired blocks. This is often on the order of 4.5 to 6 metres (about 15 to 20 feet), but, since it is actual quarry practice to take advantage of any natural horizontal seams, block thickness may vary.
The quarrying process consists of separating large blocks, sometimes called loafs, from the surrounding rock. These blocks may be 6 metres high by 6 metres deep and 12 to 18 metres (about 40 to 60 feet) long, and they may weigh in the range of 1,200 to 2,000 tons. (Such large blocks are subsequently divided into mill blocks weighing 15 to 70 tons.) The removal of blocks from the quarry has traditionally been done by one or more fixed derricks. As a result, the plan area of a quarry has been determined not only by the geometry of the deposit and the amount of overburden but also by the reach of the derrick boom. However, derricks are gradually being replaced by highly mobile front-end loaders of sufficient capacity to move, lift, and carry 30-ton mill blocks, and the layout, design, and operating procedures of quarries are being modified accordingly.
There is a very high waste factor in the quarrying of dimension stone. For some quarries the amount of usable stone is only 15 to 20 percent of that quarried. For this reason an important aspect of quarry planning is the location of the waste or “grout” pile.
There are a number of techniques for separating a mass of stone from the parent mass. For many years the primary technique was the wire saw, which consists of a single-, double-, or triple-stranded helicoidal steel wire about 6 mm (0.2 inch) in diameter into which sand, aluminum oxide, silicon carbide, or other abrasive is fed in a water slurry. As the wire is pulled across the surface, a groove or channel is worn in the stone. Although the wire does not do the cutting itself (this is done by the abrasive), it does wear in the process so that the width of the cut continuously decreases. If the wire breaks prior to the completion of a cut, there will be great difficulty in beginning again; hence, the wire must be sufficiently long to complete the cut. In granite quarrying, a rule of thumb is that about 27 metres (about 89 feet) of wire are used for each square metre of stone that is cut (8 feet of wire per square foot). Completing a 6-metre-high by 9-metre- (30-foot-) long cut thus requires approximately 1,450 metres (about 4,800 feet) of wire; indeed, a typical wire saw setup may require 3 to 5 km (2 to 3 miles) of wire driven by an electric motor or diesel engine and directed around the quarry by a system of sheave wheels. A single wire may make several cuts at one time by suitable sheave direction.
The advantage of wire sawing is that it produces a smooth cut that minimizes later processing and does not damage adjacent rock. The technique has largely been superseded by others, however. In hard rocks such as granite that have a significant quartz content, channels may be cut by handheld or automated jet burners. A pressurized mixture of fuel oil and air or of fuel oil and oxygen is burned in a combustion chamber similar to a miniature rocket engine, producing a high-temperature, high-velocity flame. A channel 75 to 150 mm (3 to 6 inches) wide and up to 6 metres deep can be formed.
Another technique for cutting slots involves drilling a series of long parallel holes, using pneumatically or hydraulically powered percussion drills. In line drilling, closely spaced pilot holes may be drilled first and the intervening material then removed by reaming with a larger-diameter bit. Other arrangements using special guides are also available. For softer, less-abrasive rocks, the remaining rock web between holes may simply be chipped or broached out.
Rock between less closely spaced holes (125 to 250 mm [about 5 to 10 inches] apart) can be broken rather than removed. One technique for doing this involves the use of special explosives to exert a high gas pressure against the hole walls and thereby produce a crack along the firing line. A mechanical technique for accomplishing this is the use of feathers and wedges. Feathers are two half-round pieces of steel that are inserted into all of the holes forming a side of the block. The quarry worker works down the row, inserting a wedge between each pair of feathers and then tapping the wedges with a sledgehammer. This forces pressure from the wedge to the feathers so that eventually a crack line forms. This procedure is commonly followed to form the bottom of a block and for dividing large blocks into smaller blocks. In the latter case a line of small-diameter holes only a few centimetres deep is required. In addition, special cement grouts that expand during curing, as well as special hydraulic pressurization techniques, have also been used.
A relatively new development is the diamond wire saw. This consists of a 6-mm steel carrier cable on which diamond-impregnated beads and injection-molded plastic spacers are alternately fixed. The plastic spacers protect the cable against the abrasiveness of the rock and also maintain the diamond segments on the cable. Relatively clean water serves both as the flushing medium and to cool the wire. The initiation of a cut requires two boreholes 40 to 90 mm (1.6 to 3.5 inches) in diameter. One hole is drilled down from the upper corner of the block, and the other is drilled horizontally along the bottom to intersect the vertical hole. The wire is strung through the holes, and a driving mechanism supplies the power to move the wire and apply the proper tension. The diamond wire cut is very narrow (thus reducing waste), and it does not produce cracks or fissures in the stone. Moreover, once the saw is set up, an operator is not required.
Large chain saws, similar to those used for cutting trees but equipped with tungsten carbide or diamond-tipped cutters, are applicable to marbles, limestones, travertines, shales such as slate, and some types of sandstone. The chain, made up of removable links that carry the tool holders, rides in a channel with replaceable walls and bottom. The machine is self-propelled through a rack-and-pinion mechanism along modular track sections.
Channels may be cut in the stone by high-pressure jets of water with or without the addition of an abrasive substance. Water is forced through a small-diameter nozzle at extremely high velocity, creating new cracks and penetrating small natural cracks. In the process, thin layers of rock are sliced away. The advantages of water-jet channeling are that it cuts narrow, straight channels with very little noise and that it does not damage the wall surface.
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