Adi Gold Mining Pvt. Ltd. is a South West Delhi, Delhi based company registered on 26-04-1996 . Get the detailed information of Adi Gold Mining Private Limited which has registered location is D-1, Commercial Complex-2, Third Floor, Paschimi Marg, Vasant Vihar, New Delhi South Delhi Dl In 110057 which carries out Mining & Quarrying. Adi Gold Mining has the CIN no of U13209DL1996PTC078512 and it is a Non-govt Company which is Company Limited By Shares. You can get further basic details about Adi Gold Mining company below..
Gold miners are expanding their focus in Africa to the northeast of the continent, a region that in the past, was largely bypassed by gold explorers. Northeast Africa already has a few gold deposits in the threshold size of one million troy ounces (the size limit the usually piques the attention of bigger miners.) Eritrea first gained mineral exploration interest due to other significant finds on the Arabian Nubian Shield. Eritrea is part of the Arabian Nubian Shield, a relatively underexplored area that is known to host valuable minerals including gold, copper, zinc and potash. It was the knowledge that the Arabian Nubian Shield, the home of other gold finds, extended through Eritrea that attracted exploration interest to the small country that borders the Red Sea, Djibouti and Sudan.
Eritrea is a small country with over 60 percent of its land mass is covered by the Arabian Nubian Shield. The size of deposits uncovered by the early explorers in this region is encouraging more exploration interest from mining companies around the world.
While Eritreas gold deposits are unlikely to rival the size of other African countries such as South Africa, and the Democratic Republic of Congo, Eritrean gold deposits will benefit from favourable mining economics due to the small amount of vegetation and overburden covering the mineral reserve. The deposits are also located close to well-developed infrastructure, including easy port access. Mining executives claim that the biggest challenge for mining in this region will be the countrys aridity. Gold mining requires large amounts of water, and with very little in the region, miners will be forced to pipe or truck in the much needed water. Water is a scarce resource in much of Africa, so a prolific, and stable source of water will have to be tapped upon before mining activities can commence.
Part of the past limitation in mineral exploration in Eritrea was due to border wars between Ethiopia and Eritrea. While these concerns still persist, they have lessened. Eritrea has established a new mining code, and with gold mining now occurring in the area, the country has extra incentive to promote political stability to attract more investment. Eritreas mining law sets the governments stake in any mining project at 10 percent with an option to buy a further 30 percent. The government earns their minimum 10 percent stake in any mine, without having to pay for the stake up-front or fund exploration costs. The government has the option to earn another 20-30 percent stake, but in order to do so must fund exploration costs.
Nevsuns Eritrean project is its Bisha Mine. Bisha is a large precious and base metal volcanogenic massive sulfide deposit that commenced gold and silver production in February 2011. The Bisha Mine is expected to produce more than 1.14 million ounces of gold, 11.9 million ounces of silver, 821 million pounds of copper, and over 1 billion pounds of zinc during its initially estimated 13 year mine life. The Eritrean government opted to purchase the 30 percent, in addition to the 10 percent carried interest in the project. In addition to the Eritrean governments involvement, the Bisha Project was equity financed with no debt or hedge.
Sunridge Gold Corp. is a Canadian junior development company that has successfully defined four independently estimated NI 43-101 mineral deposits on the Asmara Project in Eritrea. A feasibility study for the high grade Debarwa copper, gold and zinc deposit commenced in October 2010 and is scheduled for completion in November 2011. A pre-feasibility study commenced in late 2010 on the Asmara North Deposits, Emba Derho, Adi Nefas and Gupo Gold and is scheduled for completion in late 2011 or early 2012.The four deposits have total indicated NI 43-101-resources containing 1.28 billion pounds of copper, 2.5 billion pounds of zinc,1.05 million ounces of gold, and 31.2 million ounces of silver
Chalice controls a total of eight exploration licenses in northern Eritrea covering an area of 1,370 sq. km. These include the Zara North, Zara Central (comprising Zara 1, 2, 3 and 4) and Zara South exploration licenses, the Hurum exploration license and the Mogoraib exploration license. During the fiscal year ended June 30, 2010 Chalice had completed a feasibility study on the Koka Gold Deposit, part of its 100% owned Zara Project. In August 2009, Chalice merged with Sub-Sahara Resources NL, holder of a 69% interest in the Zara Project. At the time of the merger with Sub-Sahara, Chalice acquired a further 11.12% interest in the Zara Project.
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Mining industries need process improvements across all facets including mineral extraction, processing, transportation, and marketing to remain cost efficient and gain a firm foothold in the competitive market.
The mining industry is like any other manufacturing industry in that it utilizes sophisticated and productive machinery, along with digitization, so that it can prosper by increasing productivity while decreasing costs. Development in mining technology is ongoing throughout the world, notwithstanding India. Operational monitoring and control systems have enhanced the productivity, safety, and efficiency of mining. In addition, the mining industry is now using heavier and larger machinery. As things stand, the point of diminishing returns has been reached. The solution to this is IT-enabled automation. Increasing mechanization calls for more maintenance, repair work, operating supplies, and inventories. Advances in IT might be of benefit to all of these. Strategic directions are detailed in Figure4.14.
Mining industry site covering exploration through to mining, processing and transport of minerals are privately owned or PS activity in countries like: Osisko Mining, Argentina, Red Back Mining in Canada, Australia, Europe, United States, Latin America, Anglo American plc, Anglo Platinum, De Beers, Exxaro Resources Ltd, Gold Fields, Harmony Gold, Impala Platinum, JFPI Corporation, Kumba Resources, Rio Tinto and Wesizwe Platinum in South Africa and Equinox, Meteopex, Mopani Copper, Konkola Copper, Zambia Consolidated Copper Mines, First Quantum Minerals, Venturex Resources Ltd, and Vale, Zambia. The other international exploration companies are CSR Ltd, Forteseue Metals Group, Rio Tinto Group, Santos, Zinifex Ltd, Goldstream mining NL, IMX Resources Inc., Australia, Cameco Uranium, Goldcorp, Exeter resource Corporation (2002), Canada, Codelco Mining Corporation (1976), and Capstone Mining Corporation, Chile. The major Indian PS exploration and mining companies are: ACC Ltd, ADI Gold Mining Pty Ltd, Binani Zinc Ltd, Birla Corporation Ltd, BHP Billiton, De Beers India Pvt Ltd, ESSAR Mineral Resources Ltd, Ferro Alloys Corp Ltd, Rio Tinto India Pvt Ltd, Sesa Goa Ltd, Tata Steel Ltd and Vedanta Resources plc. The companies are permitted to explore and mine nonrestricted minerals. The PS are equipped with technical personnel and machineries to conduct exploration and evaluation of mineral deposits in on going mining as well as in virgin areas.
Mining industries need process improvements across all facets including mineral extraction, processing, transportation, and marketing to remain cost efficient and gain a firm foothold in the competitive market. Application of business process management (BPM) helps analyze and optimize mining organization's processes, promotes better collaboration as well as coordination among various departments to improve efficiencies and ensure best results (www.actgov.org/knowledgebank/whitepapers/Documents/Sponsor%20White%20Papers/IBMCloud.pdf). BPM can automate field reporting systems to improve operations and maintenance by up-to-date operational information. Cloud computing can provide a relatively inexpensive solution to ensure relevant and accurate information to sales and marketing personnel on production schedules, output and inventory across a wide variety of product specifications.
Mining companies can extract benefits in at least four areas by use of BPM technology. It can help improve operations and maintenance by providing managers with up-to-date operational information. It can establish better collaboration and coordination between production and sales. Mining companies are highly dependent on the reliability of the equipment and vehicles used for mining and transportation of their products. Cloud computing can play a key role in determining how successful a company's operation and management efforts are in maximizing the uptime of machinery and vehicles used in mining, handling, and storage. It can be used to automate the recordkeeping for each vehicle and piece of equipment, keep track of warranties, and maintain planned schedules. Breakdowns and unplanned repairs can be monitored and best practices can be established for operating each unit. BPM can be used to set up a cost-effective repository quickly and efficiently for operating manuals and engineering drawings. This would allow access for employees from any department in the company as well as outside parties who have been given permission.
There are now several firms that offer BPM software products. Each product has its own unique features and user interface, but what they have in common is the ability to automate almost any business process regardless of industry or functional area.
The mining industry has been a significant part of the economy for many decades. Continuous pollution of the environment with heavy metals has been caused by mineral resources exploration and exploitation activities, as well as by processing of ores in factories.
The gold mining industry is a continuous pollution trigger, representing the primary source of heavy metal contamination during the exploitation and for many decades after the mining activity is ceased if the mining area is not environmentally cleaned. Gold mine tailings contain high levels of toxic metals such as Cu, Pb, Zn, Cd, As, and Hg with a negative influence on the environment.
Phytoremediation technology can represent a low-cost option for the remediation of industrially contaminated areas, especially for abandoned mines. Various associations and interactions between plants, their microbial rhizosphere flora, and pollutants make the phytoremediation mechanisms practical for a variety of organic and inorganic contaminants. Various phytoremediation methods can be widely used for the treatment of various solid, liquid, and gaseous substrates, in the decontamination of macronutrients (phosphate and nitrate), several elements (Pb, Cu, Zn, Cd, Fe, As, Mn, Ni, Mo, Cr, Co, F, Hg, Se, V, and W), radioactive isotopes (238U, 137Cs, and 90Sr), petroleum hydrocarbons, organic solvents, and herbicides.
The mining industry may consider itself as a temporary user of land. Adopting this position requires that the industry returns the maximum amount of land to a sustainable and constructive post-mining use. While all mining operations are finite, the tailings storage facilities constructed during these operations will be expected to remain in place essentially in perpetuity after cessation of operations.
The closure design of any TSF therefore needs to address the long-term stability, safety, and esthetic aspects of the structure while assessing the potential post-operational land uses of the TSF. These matters require close consultation with the stakeholders (including government authorities and the local communities) so that the final closure design will meet the reasonable expectations of those stakeholders at a cost acceptable to the operating company.
The mining industry has been the major driver of the wood industry development in Zambia. Hardwood industry was developed first to support the mining needs for wood and also for railway sleepers. The first and second national forest inventories of 1952 and 1965 provided data for the planning of wood exploitation and forest protection at district and national levels in Zambia (MTENR, 2008). The Forest Act No. 39 of 1973, as a legal instrument, provided for a legal framework for developing wood processing industries (WPIs) in Zambia (GRZ, 1965, 1973, 1998). With the legal framework in place Zambia embarked on the country-wide establishment of exotic tree plantations based on the 1965 forest inventory (Chisanga, 2005).
With the establishment of forest plantations, the softwood products industry developed in the Copperbelt Province around the 1990s targeting the mining industry. The commercial forest growing stock from industrial plantations was about 600,000m3 per annum by 2002, with an additional 100,000m3 per annum from Local Supply Plantations established in provincial centers (Ngandwe et al., 2012). Processing units such as pole treatment plants; sawmilling and kiln-drying facilities; and plywood, veneer, and blockboard manufacturing factories were developed around the country between 1992 and 1995. These processing units were mainly government-owned companies, established as parastatals.
During 19801992, the timber industry was dominated by state-owned enterprises and by 1990s most of these parastatals were performing badly. In about 1993 the Zambian government commenced major economic reforms focusing on the privatization of state-owned enterprises and liberalizing the economy. Following this macro-economic shift, the largest government-owned timber processing plants of the Zambia Forestry and Forest Industries Corporation (ZAFFICO) and Zambia Steel and Building Supplies (ZSBS) were privatized. According to a government report (GRZ, 2006a) privatization and structural adjustment programs resulted in the deterioration of the productivity in the manufacturing sector. Many employed persons in the formal sector were retrenched.
The retrenched personnel, as a result of the Structural Adjustment Program of 19932000, started developing private small-scale forest-based sawmilling enterprises throughout the country as a means of livelihood (Njovu, 2011). Since 2001, there has been a modest small-scale private investment in sawmilling, particleboard, plywood, and pole treatment technologies. In the subsequent years, there has been a mushrooming of informal wood processing segments particularly in the Copperbelt and Lusaka Provinces providing additional employment. Since then, demand for industrial round-wood increased from 140,000m3 in 2001 to over 650,000m3 by 2010 (Ngandwe, 2011a; Ngandwe et al., 2011). On the other hand, technological development lagged behind as many sawmills continue to use obsolete machines characterized with low recoveries and low quality products. The lack of meaningful investment resulted in a policy development that would catalyze investment in the timber industry driven by the private sector.
In 2004 the Government of Zambia initiated the Forestry Department Credit Facility (FDCF) to address issues of lack of investment in the timber industry (Masinja, 2005). In most cases the lack of investment has been attributed to high interest rates, high collateral requirements and reluctance by Banks to lend money to entrepreneurs. The FDCF facility catalyzed the formation of over 500 enterprises engaged in sawmilling as a business in Zambia. The major downstream formal timber products processing units created by the fund were in sawmilling, wood furniture, and Woodcrafts. Today, sawmilling is by far the most dominant economic activity in Zambias wood industry with over 500 actors in the primary timber processing followed by the wood-based panels (WBPs) industry and wood furniture. The informal wood processing sector on the other hand, has over 1 million actors but has not benefited from the FDCF arrangement.
The mining industry has a considerable impact on the environment. Soil pollution by potentially harmful elements due to mining and smelting activities is a worldwide problem. The extraction of metals from sulfide minerals usually results in large amounts of tailings, which often contain elevated concentrations of potentially harmful elements. Tailings usually provide an unfavorable substrate for plant growth because of their extreme pH, low levels of organic matter and nutrients, high concentrations of potentially harmful elements, degraded soil structure and low water availability. These mine tailings become potential sources of pollution due to wind and water erosion.
Conventional techniques used for remediation of contaminated soils, such as current engineering technologies, mainly excavation, removal, transport and disposal to landfills and physicochemical treatments, are costly, disruptive, labor- intensive and expensive. Efforts to restore the vegetation cover can enhance stabilization and pollution control. Therefore, the use of plants to remediate hazardous mine soils is considered a recommendable approach for improving the environmental quality of tailings. The latest and most conservative technique of remediation is phytoremediation, based on the properties of metallophytes.
Cunningham et al. (1995) and Schnoor et al. (1995) are considered the first authors to use the term phytoremediation, the use of plants for xenobiont containment, degradation or extraction from water or soil substrates (USEPA, 2000). Actually, the use of plants for remediation of contaminated soils emerged in 1970. Yamada et al. (1975) researched soil purification by plants that absorb heavy metals. Smith and Bradshaw (1979) and Williamson and Johnson (1981) discussed the reclamation of metalliferous mine wastes with plants. Other key references are: Chaney (1983), McGrath (1990), Baker et al. (1991), Brown et al. (1994), Vangronsveld and Cunningham (1998), Van der Lelie et al. (2001), Barcel and Poschenrieder (2003) and Bech (2015), among other.
Several approaches are taken in phytoremediation. In the mining industry, however, it seems that two major options envisaged are phytoextraction and phytostabilization. The first is the use of plants to remove pollutants from soils by accumulation in easily harvestable plant parts, mainly shoots.
The criteria to define hyperaccumulation of As, Co, Cu, Cr, Ni, Pb and Se is a concentration of 1000mgkg1 or higher, on a dry leaf basis (Kabata-Pendias and Mukherjee, 2007; Yoon et al., 2006) whereas the threshold value for Zn and Mn hyperaccumulation is 10,000mgkg1 (Kabata-Pendias and Mukherjee, 2007). Additionally, hyperaccumulation for Cd is defined as values larger or equal to 100mgkg1. Hyperaccumulators are also characterized by a shoot-to-root metal concentration ratio (i.e., translocation factor [TF]) of more than 1, whereas nonhyperaccumulator plants usually have higher metal concentrations in roots than in shoots. Several authors, such as Baker (1981) and others, include the bioaccumulation factor (BF) or shoot accumulation factor (SAF) as an element for classification as a hyperaccumulator species. The BF or SAF refers to the plant metal concentration and the soil metal concentration ratio. This ratio should be greater than 1 for inclusion into the hyperaccumulator category.
The TF and SAF factors were determined to accurately assess the tolerance strategies developed by these metallophytes and to evaluate their potential for phytoremediation purposes, mainly for phytoextraction and phytostabilization. Phytostabilization (Yoon et al., 2006) is the use of plants to immobilize or inactivate soil pollutants in situ. The latter seems to be more suitable for natural land restoration of mine tailings. In this case, the abrupt topography of mine dumps or open cast mining often prevents the use of agronomic techniques, making phytoextraction impossible. Phytostabilization does not remove heavy metals from soils, but may help to minimize environmental and health risks, such as erosion and even landslides due to rain impact or wind, and limit site migration of contaminants. In phytostabilization, metallophytes with high growth rates, dense canopies and rooting systems, and high rates of propagation are recommended.
The mining industry applies software-based computerized extension functions for estimation of acceptable mine production block/subblock grades based on the principle of gradual change. Inverse power of distance or (1/Dn) interpolation is the preferred method. The technique uses straightforward mathematics for weighting the influence of samples around the block being estimated (Fig.8.12). It selects only those samples falling within the influence zone relevant to mineralogical affinity (continuity function) of the population. It also reflects the anisotropic character within the deposit, and varies the distance weighting function directionally with the help of a semivariogram function in various directions (refer to Chapter 9).
The mining block is divided into a series of regular 2D or 3D slices within the planned boundary equivalent to a blast hole of mine production. A 2D cross-section model or rock matrix is illustrated in Fig.8.13. The block dimensions and approach for an open pit mine are 12.5m along the strike (infill drill interval), 10m vertically (bench height), and 5m across the dip (face movement). Each cell is designated by a code number (say200, 17, 19) controlled by identification of section, bench, and cell; e.g.,200 is south 200 section, 17 is the bench between 330 and 340m level, and 19 is the cell position between 40 and 45 east.
The samples along the boreholes are converted to uniform composite length (5m). The selection of samples for computation of a panel is controlled by a search ellipse oriented with its major axis along the down-dip of the orebody (range=90m) and minor axis across (range= 30m). The intermediate axis is oriented along the strike direction (range=115m) in the case of 3D computation. The ranges in various directions are obtained from the semivariogram function (Chapter 9). The search ellipse moves on the plane of the cross-section, centering the next computational panel while performing interpolation. The strong anisotropic nature, if observed in the semivariogram, is further smoothened by differential weighting factors onsamples selected through search ellipse screening. Thesamples located down-dip are assigned a greater weighting factor than across the orebody. These factors are tested in various options near controlled cells. In this method the near sample points receive greater weighting than points further away. The power factor is often employed as d2.
The tonnage of each panel is estimated by block dimension and bulk Sp. Gr. The cell values (tonnage and grade) can be displayed as a series of bench plans for production scheduling. The inverse power of distance computation is performed by in-house or commercial software following:
The mining industry is a business full of risks, requiring substantial long-term investment. One of the risks is the technical risk associated with project evaluation, process development, plant design, mine planning, and performance of mineral processing/metallurgical unit operations, which is mainly caused by ore variability. To minimize and reduce the technical risk, mining companies have been using geometallurgy in the past two decades to measure and quantify the spatial variability of the deposits that are being developed. Geometallurgy is an interdisciplinary approach that links the geological, geochemical, and mineralogical characteristics to the metallurgical performance of an orebody. Combined with mine planning, it has been used in scoping, prefeasibility and feasibility studies, process design, and optimization of gold, coppergold, coppermolybdenum, nickel and iron projects, among others (Williams and Richardson, 2004; Dobby etal., 2004; Bulled, 2007; Bulled etal., 2009; Lotter etal., 2013; Kormos etal., 2013; Muinonen etal., 2013; Leichliter and Larson, 2013; Leichliter etal., 2013; Hatton and Hatfield, 2013; Baumgartner etal., 2011, 2013; Hoal etal., 2013; Zhou, 2013). The goal of a gold or coppergold geometallurgical program is to characterize and understand the metallurgical variability of an orebody, such as comminution, gravity, flotation, and cyanidation parameters and metal recoveries, and to build a geomet model that can be used to assist in mine planning and to predict plant performance. In any geometallurgical program, representative sampling is the key to ensure that the results of a geometallurgical study will reflect future performance once the plant is commissioned. Mineralogical characterization and metallurgical testing, which leads to an understanding of the orebody, lies at the core of a geometallurgical program. Geometallurgy complements, but does not replace, the traditional mineralogical and metallurgical approach during the development and operation of a gold or coppergold project. Geometallurgy is a methodology for test work design and a framework for mine planning. The first part of this chapter provides an overview of geometallurgy fundamentals and application in gold ore processing, with a focus being on ore characterization.
As a powerful tool in ore characterization, automated mineralogy has been used widely by the minerals industry and research institutes for more than two decades and is commercialized in the form of techniques such as mineral liberation analysis (MLA), QEMSCAN, and more recently Advanced Mineral Identification and Characterisation System (AMICS). It generally uses scanning electron microscopy (SEM) hardware as a platform, combined with electron-dispersive spectroscopy (EDS), and sophisticated software, to provide information on mineral speciation, composition, liberation, association, and size distribution, etc. This information is not only required for new flowsheet development and process selection but is also useful for plant optimization. The second part of this chapter will first provide an overview of the basic functions of an automated SEM/EDS system, from sample preparation, to measurement, data processing and reporting, introducing model analysis and liberation analysis as basic results. Then, methods especially related to automated gold mineralogy analysis, such as bright/rare phase search (BRPS) and sparse phase liberation (SPL), are discussed.
In the mining industry, cyanide is primarily used for leaching gold and silver from ores, but it is also used in low concentrations as a flotation reagent for the recovery of base metals such as copper, lead, and zinc. At many of these operations, cyanide treatment systems may be required to address potential toxicity issues in regard to the health of humans, wildlife, waterfowl, or aquatic life. This may include the removal of cyanide from one or more of the following:
Cyanide treatment is generally classified as either a destruction-based process or a recovery-based process. In a cyanide-destruction process, either chemical or biological reactions are used to convert cyanide into another less toxic compound, usually cyanate. Cyanide recovery processes, described in more detail in Chapter 36, represent a recycling approach in which cyanide is removed from the solution or slurry and then reused in a metallurgical circuit.
Selection of an appropriate cyanide-treatment process for a particular site involves the consideration of many factors, but normally the number of candidate processes for a particular application can be narrowed following review of the untreated solution or slurry chemistry, the desired effluent quality and the availability of reagents or suitable process waters. Common applications for cyanide treatment in the mining industry are described next.
Tailings slurry treatment is used when the cyanide level must be lowered prior to being discharged into a tailings storage facility. In this application, the initial tailings slurry weak acid dissociable (WAD) cyanide level typically ranges from about 100 to 500mg/L, and treatment to less than 50mg/L cyanide is commonly established as the goal for wildlife and waterfowl protection (Hagelstein and Mudder, 2001; ICMI, 2002).
Solution treatment is used when the cyanide level in decant or process solution must be lowered prior to being discharged into the environment. Treatment of WAD cyanide to low levels is normally required to ensure the protection of human health or aquatic ecosystems. Treatment technologies for solutions commonly employ chemical oxidation and polishing processes, which are applicable to relatively low concentrations of cyanide and generate high-quality effluent.
Adi Universal Group of Companies Consultants service coal and metalliferous mining customers at all stages of the mining lifecycle, specializing in both surface and underground mining. We operate across Afghanistan.
Save to read list Published by Jessica Casey, Editorial Assistant Global Mining Review, Thursday, 20 May 2021 12:15
Nicole Galloway Warland, Managing Director of Thor Mining, commented: "This is a fabulous result for Thor and its shareholders as it validates the high-quality Alford East Project. The successful grant is a strong endorsement of the technical merits of the project by the South Australian government.
The AUS$300 000 funding will significantly expedite our exploration and development programme for the Alford East ISR Project, with diamond drilling commencing shortly with the objective to increase the resource size and commence hydrometallurgical studies.
The ADI aims to encourage innovation and collaboration to advance exploration activities in South Australia. It provides a government contribution towards exploration activities, through supporting the potential discovery of new mineral and ground water resources, while delivering a number of other economic and social benefits to the State.
Successful applications for Round 2 of the initiative were announced by the Minister for Energy and Mining, Hon Dan van Holst Pellekaan MP on 20 May 2021. A total of almost AUS$4.5 million in new funding has been award to 22 companies, with Thor Mining granted AUS$300 000.
Potential to grow the Alford East copper-gold mineral resource estimate remains along strike and at depth. Historic air core and reverse circulation drilling within the project area stopped within the mineralised oxide copper-gold zones with only limited deeper diamond holes continuing through the oxide copper mineralisation. A 2000 m diamond drilling programme is scheduled to commence late May, designed to follow up on the depth extent of the oxide mineralisation, adjacent to these mineralised diamond holes. In addition, drill holes will be placed along strike of the eight identified mineralised zones to confirm strike extent and continuity of the mineralisation.
In this webinar, Chris Pearson, Group Business Development Director at MMD Group, will discuss in detail their Fully Mobile Surge Loader (FMSL), its key requirements, and implementation considerations.
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In this webinar, Chris Pearson, Group Business Development Director at MMD Group, will discuss in detail their Fully Mobile Surge Loader (FMSL), its key requirements, and implementation considerations.