Improving the efficiency of blasting operations in mines with the help of emulsion explosives

Purpose. To improve the efficiency of blasting operations in mines taking into consideration the upgrading of equipment used to charge blastholes as well as application of high-productive mining equipment of new generation. Methods. The activities used mine experimental pressure-charged blasts to break oversize material as well as mine experimental analysis of blasthole charging to estimate the improvement of efficiency of the emulsion explosives (EEs). Findings. It has сbeen determined that both sticked and bulk emulsion explosives of Ukrainit-PP-2 type as well as new options of charging facilities have following technological characteristics: availability of unique space-saving designs of two-component piston dosing pumps of double-action EE components; sufficiently high efficiency of blasthole charging being up to 60 kg of EE/min; ease of service and maintenance; rather long overhaul period of EE components as for the dosing pump as well as cheapness of attachable equipment; availability of both electronic and visual means to control EE preparation and charging. Originality. It has been proved that the improvement of blasting operations in mines results from the intensified technological processes of blasthole charging characterized by the use of such high-productive self-propelled and space-saving facilities of new generation as machines of ZEVS-1 model and portable charges of ZEP-15 type as well as the use of such environmentally friendly bulk trinitrotoluene-free emulsion explosives as Ukrainit-PP-2. Practical implications. Use of EEs in the process of mine blasting operations provides safety, high-quality rock breakage and fragmentation in the context of minimum toxicity of rock, breakage of rocks having any hardness and water content. Moreover, their use is economically efficient.Мета. Підвищення ефективності виконання вибухових робіт за допомогою емульсійних вибухових речовин на шахтах з урахуванням вдосконалення обладнання для заряджання вибухових свердловин, а також застосування високопродуктивної гірничої техніки нового покоління. Методика. В роботі для оцінки підвищення ефективності виробництва вибухових робіт за допомогою емульсійних вибухових речовин на шахтах використані шахтні експериментальні вибухи накладного заряду при руйнуванні негабариту й шахтні експериментальні дослідження процесу заряджання шпурів. Результати. Встановлено, що патроновані та наливні емульсійні вибухові речовини (ЕВР) типу Україніт-ПП-2 і нові варіанти зарядних машин мають наступні технологічні особливості: наявність у своєму складі оригінальних малогабаритних конструкцій двокомпонентних поршневих насосів-дозаторів компонентів ЕВР подвійної дії; досить високу продуктивність заряджання свердловин – до 60 кг ЕВР/хв; простоту в обслуговуванні та ремонтах; досить високе напрацювання до капремонту насосу-дозатора компонентів ЕВР, а також значно меншу вартість навісного обладнання; наявність як електронних, так і візуальних засобів контролю за приготуванням і заряджанням ЕВР. Наукова новизна. Доведено, що підвищення ефективності виробництва вибухових робіт на шахтах досягається інтенсифікацією технологічних процесів заряджання вибухових свердловин, що відрізняються застосуванням високопродуктивної самохідної та малогабаритної техніки нового покоління, таких як машини моделі ЗЕВС-1 і переносні зарядники моделі ЗЕП-15 та використанням наливних, екологічно чистих, безтротилових ЕВР Україніт-ПП-2. Практична значимість. Застосування ЕВР на шахтах при веденні вибухових робіт забезпечує без-небезпечне ведення робіт, високу якість відбійки і дроблення гірських порід при мінімальній токсичності, руйнування гірської породи будь-якої міцності й обводненості та економічну ефективність.Цель. Повышение эффективности производства взрывных работ с помощью эмульсионных взрывчатых веществ на шахтах с учетом совершенствования оборудования для заряжания взрывных скважин, а также применения высокопроизводительной горной техники нового поколения. Методика. В работе для оценки повышения эффективности производства взрывных работ с помощью эмульсионных взрывчатых веществ на шахтах использовались шахтные экспериментальные взрывы накладного заряда при разрушении негабарита и шахтные экспериментальные исследования процесса заряжания шпуров. Результаты. Установлено, что патронированные и наливные эмульсионных взрывчатых веществ (ЭВВ) типа Украинит-ПП-2 и новые варианты зарядных машин имеют следующие технологические особенности: наличие в своем составе оригинальных малогабаритных конструкций двухкомпонентных поршневых насосов-дозаторов компонентов ЭВВ двойного действия; достаточно высокую производительность заряжания скважин – до 60 кг ЭВВ/мин; простоту в обслуживании и ремонтах, достаточно высокую наработку до капремонта по насосу-дозатору компонентов ЭВВ, а также значительно меньшую стоимость навесного оборудования; наличие как электронных, так и визуальных средств контроля за приготовлением и заряжанием ЭВВ. Научная новизна. Доказано, что повышение эффективности производства взрывных работ на шахтах достигается интенсификацией технологических процессов заряжания взрывных скважин, отличающихся применением высокопроизводительной самоходной и малогабаритной техники нового поколения, таких как машины модели ЗЭВС-1 и переносные зарядчики модели ЗЭП-15 и использованием наливных, экологически чистых, бестротиловых ЭВВ Украинит-ПП-2. Практическая значимость. Применение ЭВВ на шахтах при ведении взрывных работ обеспечивает безопасное ведение работ, высокое качество отбойки и дробления горных пород при минимальной токсичности, разрушение горной породы любой степени крепости и обводненности и экономическую эффективность.The studies have been carried out according to the materials of the report with the participation of the authors in 15th International Conference Resource-generative, low-waste, and nature-protective technologies of mineral development (Vorob’yev, Lyashenko, & Nebogin, 2015) in association with such experts as P.A. Kysly, N.N. Shvets, V.S. Cherevyk, A.I. Lytvyn (A and M SIC), V.I. Boiko, A.S. Karaban, M.B. Kolesaiev, V.V. Shkaryn (LLC “NTO Tekhnotron”) and others

Development of natural underground ore mining technologies in energy distributed massifs

The object of research is the technology and facilities for underground mining of ores in the disrupted massifs. One of the most problematic places is the formation of man-made voids; which influence the occurrence and redistribution of stress-strain state (SSS) of the rock massif. Their existence in the earth's crust provokes the influence of geomechanical and seismic phenomena; up to the level of earthquakes. The study used: – data from literature sources and patent documentation in the field of technologies and facilities for underground mining of ores in the energy-disrupted massifs of substantiation of technological parameters of operating units; – laboratory and production experiments; – physical modeling and selection of compositions of solidifying mixtures. Analytical researches; comparative analysis of theoretical and practical results by standard and new methods with the participation of the authors were performed. The questions of seismogeodynamic monitoring of the SSS of the rock massif during the safe development of rock-type ore deposits are considered. The interaction of natural and man-made systems providing geomechanical balance of ore-bearing massifs is shown. Possibilities of controlling the geomechanics of a massif with filling of man-made voids with various solid mixtures and tails of underground leaching of metals from substandard ores are investigated. The typification of processes is given and the distinctive features of underground block leaching of metals from rock ores are formulated in the aspect of controlling the geodynamics of the massif. The principle estimation of the combined technologies with rationalization of use of the SSS of the rock massif for regulation of the sign and magnitude of stresses in natural and artificial conditions is shown. The conclusions about the effectiveness of the controlled interaction of natural and man-made systems; ensuring the geomechanical balance of massifs and the earth's surface in the area of subsoil development over a long period of time. The research results can be used in the underground development of ore deposits of complex structure of Ukraine; the Russian Federation; the Republic of Kazakhstan and other developed mining countries of the world

Improvement of filling systems for deep ore mine depth

Purpose of study – improvement of filling systems for deep ore mine depth.The studies have been undertaken for improvement of filling systems for deep ore mine depth and with purpose to increase the safety level of subsoil mining activities. A general method of determination of parameters for retention of drill drift stability, installed in the vicinity of a stope area down dip as well as along the strike of ore deposit

Development of principles of opening strength during underground mining

There have been analyzed fundament a land applied research work saimed at development, testing and manufacturing application of efficient technological plans for developing, supporting and maintaining underground workings. There has been found the evolution of scientific and production principles which underlie the technologies of supporting and maintaining underground workings. The analyzed ones have been evaluated. There have been found trends of principle development ranging from counteraction and counterbalance to contribution, removal and transfer of the high pressure energy concentrated aroundworkings

Development of the geoenergetic monitoring methodology during underground development of the ore deposits

The scientific and practical results of the investigations in the domain of the geoenergetic monitoring methodology have been provided. The method of investigation of the zonal destruction processes of the massif surrounding the underground excavations has been described. There sults of the shaft, laboratory and experimental investigations, mathematical and physical simulation as well as the theoretic analysis and their summarizing based on the standard methodologies have been provided. The stable form of destruction of the development and breakage headings has been defined and change dependency of deformation depth of the development and breakage headings containing massif has been identified

Development of high-gain gaseous photomultipliers for the visible spectral range

We summarize the development of visible-sensitive gaseous photomultipliers, combining a semitransparent bi-alkali photocathode with a state-of-the-art cascaded electron multiplier. The latter has high photoelectron collection efficiency and a record ion blocking capability. We describe in details the system and methods of photocathode production and characterization, their coupling with the electron multiplier and the gaseous-photomultiplier operation and characterization in a continuous mode. We present results on the properties of laboratory-produced K$_2$CsSb, Cs$_3$Sb and Na$_2$KSb photocathodes and report on their stability and QE in gas; K$_2$CsSb photocathodes yielded QE values in Ar/CH$_4$(95/5) above 30% at wavelengths of 360-400 nm. The novel gaseous photomultiplier yielded stable operation at gains of 10$^5$, in continuous operation mode, in 700 Torr of this gas; its sensitivity to single photons was demonstrated. Other properties are described. The successful detection of visible light with this gas-photomultiplier pave ways towards further development of large-area sealed imaging detectors, of flat geometry, insensitive to magnetic fields, which might have significant impact on light detection in numerous fields.Comment: 22 pages, 12 figures, for submission to JINS

Rational use and protection of subsurface resources in the underground mining of ore deposits in conditions of technogenesis

The basic scientific and practical results of rational use and protection of subsoil under underground mining of ore deposits in the conditions of technogenesis are based on reliable geological and surveying and geomechanical support, taking into account the stability of rock masses and the dimensions of the contour energy zone. It is recommended to build ore contours based on the data of advanced exploration (drilling of explorers through 25 m, test wells – after 5-6 m and explosive wells – through 1,2-1,5 m)