A new Burn-Cut blast pattern has been designed for drives, declines and ramps in underground metal mines, to replace a design (of Decked-Burn with more number of holes), which was giving number of blast failures, such as ‘Under_Blast’ - difficult to handle. The new Burn-cut design contains less number of blast-holes and Reamer than earlier Decked-Burn-cut. Decked system has been removed to make the charging operation easier. This enables to increase explosives energy in a hole and to reduce stemming length in order to eliminate above blast failures. Moreover, requirement of Detonators is reduced, as Decked system has been abolished. Total explosives quantity has been reduced marginally. Thus, drilling efficiency and cost effectiveness has been achieved. Entire process has been done by changing the original pattern / system in three phases.
Its a presentation about the design aspect of open cast mine. The author believes it will surely help the mining engineering students at the beginning level.
Its a presentation about the design aspect of open cast mine. The author believes it will surely help the mining engineering students at the beginning level.
Longwall; Longwall in coal; Longwall in Hard Rock; Sublevel Caving; Characteristics of the ore body and mining method; Development; Production; Equipments Used; Block Caving, Introduction, Historical evolution of the method, Condition deposit; Principles of the method; Methodology of block caving; Basic issues of geomechanical to the black caving method; Caveability;Mine design Block caving; Fragmentation and extraction control; Subsidence associated; Advantages and Disadvantages of Block Caving
Open pit mining is the process of mining a near surface deposit by means of a surface pit excavated using one or more horizontal benches.
The term open pit mining is usually used for metallic or non-metallic deposits and sparingly used for bedded deposits like coal.
pillar design in coal mines, different pillar design approaches, salmon versus sheorey formulae, panel stability, diffrent approaches, local mine stiffness
Longwall; Longwall in coal; Longwall in Hard Rock; Sublevel Caving; Characteristics of the ore body and mining method; Development; Production; Equipments Used; Block Caving, Introduction, Historical evolution of the method, Condition deposit; Principles of the method; Methodology of block caving; Basic issues of geomechanical to the black caving method; Caveability;Mine design Block caving; Fragmentation and extraction control; Subsidence associated; Advantages and Disadvantages of Block Caving
Open pit mining is the process of mining a near surface deposit by means of a surface pit excavated using one or more horizontal benches.
The term open pit mining is usually used for metallic or non-metallic deposits and sparingly used for bedded deposits like coal.
pillar design in coal mines, different pillar design approaches, salmon versus sheorey formulae, panel stability, diffrent approaches, local mine stiffness
The Drill Geometry Influence on PCB Drilling PerformanceIJRES Journal
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ANFO, Emulsion and Heavy ANFO blends - Useful explosive and blasting agent fo...partha sharma
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Rain Water Harvesting And Artificial Recharge Of Groundwaterpartha sharma
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Observation of Io’s Resurfacing via Plume Deposition Using Ground-based Adapt...Sérgio Sacani
Since volcanic activity was first discovered on Io from Voyager images in 1979, changes
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Binocular Telescope, show evidence of a major resurfacing event on Io’s trailing hemisphere. When compared to the most recent spacecraft images, the SHARK-VIS images
show that a plume deposit from a powerful eruption at Pillan Patera has covered part
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Toxic effects of heavy metals : Lead and Arsenicsanjana502982
Heavy metals are naturally occuring metallic chemical elements that have relatively high density, and are toxic at even low concentrations. All toxic metals are termed as heavy metals irrespective of their atomic mass and density, eg. arsenic, lead, mercury, cadmium, thallium, chromium, etc.
Comparing Evolved Extractive Text Summary Scores of Bidirectional Encoder Rep...University of Maribor
Slides from:
11th International Conference on Electrical, Electronics and Computer Engineering (IcETRAN), Niš, 3-6 June 2024
Track: Artificial Intelligence
https://www.etran.rs/2024/en/home-english/
Professional air quality monitoring systems provide immediate, on-site data for analysis, compliance, and decision-making.
Monitor common gases, weather parameters, particulates.
Nutraceutical market, scope and growth: Herbal drug technologyLokesh Patil
As consumer awareness of health and wellness rises, the nutraceutical market—which includes goods like functional meals, drinks, and dietary supplements that provide health advantages beyond basic nutrition—is growing significantly. As healthcare expenses rise, the population ages, and people want natural and preventative health solutions more and more, this industry is increasing quickly. Further driving market expansion are product formulation innovations and the use of cutting-edge technology for customized nutrition. With its worldwide reach, the nutraceutical industry is expected to keep growing and provide significant chances for research and investment in a number of categories, including vitamins, minerals, probiotics, and herbal supplements.
DERIVATION OF MODIFIED BERNOULLI EQUATION WITH VISCOUS EFFECTS AND TERMINAL V...Wasswaderrick3
In this book, we use conservation of energy techniques on a fluid element to derive the Modified Bernoulli equation of flow with viscous or friction effects. We derive the general equation of flow/ velocity and then from this we derive the Pouiselle flow equation, the transition flow equation and the turbulent flow equation. In the situations where there are no viscous effects , the equation reduces to the Bernoulli equation. From experimental results, we are able to include other terms in the Bernoulli equation. We also look at cases where pressure gradients exist. We use the Modified Bernoulli equation to derive equations of flow rate for pipes of different cross sectional areas connected together. We also extend our techniques of energy conservation to a sphere falling in a viscous medium under the effect of gravity. We demonstrate Stokes equation of terminal velocity and turbulent flow equation. We look at a way of calculating the time taken for a body to fall in a viscous medium. We also look at the general equation of terminal velocity.
Deep Behavioral Phenotyping in Systems Neuroscience for Functional Atlasing a...Ana Luísa Pinho
Functional Magnetic Resonance Imaging (fMRI) provides means to characterize brain activations in response to behavior. However, cognitive neuroscience has been limited to group-level effects referring to the performance of specific tasks. To obtain the functional profile of elementary cognitive mechanisms, the combination of brain responses to many tasks is required. Yet, to date, both structural atlases and parcellation-based activations do not fully account for cognitive function and still present several limitations. Further, they do not adapt overall to individual characteristics. In this talk, I will give an account of deep-behavioral phenotyping strategies, namely data-driven methods in large task-fMRI datasets, to optimize functional brain-data collection and improve inference of effects-of-interest related to mental processes. Key to this approach is the employment of fast multi-functional paradigms rich on features that can be well parametrized and, consequently, facilitate the creation of psycho-physiological constructs to be modelled with imaging data. Particular emphasis will be given to music stimuli when studying high-order cognitive mechanisms, due to their ecological nature and quality to enable complex behavior compounded by discrete entities. I will also discuss how deep-behavioral phenotyping and individualized models applied to neuroimaging data can better account for the subject-specific organization of domain-general cognitive systems in the human brain. Finally, the accumulation of functional brain signatures brings the possibility to clarify relationships among tasks and create a univocal link between brain systems and mental functions through: (1) the development of ontologies proposing an organization of cognitive processes; and (2) brain-network taxonomies describing functional specialization. To this end, tools to improve commensurability in cognitive science are necessary, such as public repositories, ontology-based platforms and automated meta-analysis tools. I will thus discuss some brain-atlasing resources currently under development, and their applicability in cognitive as well as clinical neuroscience.
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II Subalternation and Theology
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IV The Mixed Principles of Theology
V Virtual Revelation: The Unity of Theology
VI Theology as a Natural Science
VII Theology’s Certitude
VIII Conclusion
Notes
Bibliography
All the contents are fully attributable to the author, Doctor Victor Salas. Should you wish to get this text republished, get in touch with the author or the editorial committee of the Studia Poinsotiana. Insofar as possible, we will be happy to broker your contact.
New burn cut blast design in drives enhances drilling blasting efficiency with economy - a case study
1. NEW BURN CUT BLAST DESIGN IN DRIVES ENHANCES DRILLING &
BLASTING EFFICIENCY WITH ECONOMY - A CASE STUDY
CHANGING FROM ‘DECKED-BURN’ PATTERN TO ‘NON-DECKED’ BURN PATTERN FOR
DEVELOPMENT BLASTING OF DRIVAGE, DECLINES AND RAMPS IN AN
UNDERGROUND METAL MINES
Author: PARTHA DAS SHARMA, (B.Tech-Hons.) in Mining Engineering
(E.mail - sharmapd1@gmail.com)
Weblog: http://miningandblasting.wordpress.com/
Abstract:
A new Burn-Cut blast pattern has been designed for drives, declines and ramps in underground metal
mines, to replace a design (of Decked-Burn with more number of holes), which was giving number of
blast failures, such as ‘Under_Blast’ - difficult to handle. The new Burn-cut design contains less
number of blast-holes and Reamer than earlier Decked-Burn-cut. Decked system has been removed to
make the charging operation easier. This enables to increase explosives energy in a hole and to reduce
stemming length in order to eliminate above blast failures. Moreover, requirement of Detonators is
reduced, as Decked system has been abolished. Total explosives quantity has been reduced
marginally. Thus, drilling efficiency and cost effectiveness has been achieved. Entire process has been
done by changing the original pattern / system in three phases.
A. Introduction – Excavations of drifts and drives are common features in any metal mining. The specific
constrain in driving drivage is, unlike opencast bench blasting, absence of initial free faces. Therefore
solid blasting is carried out, for which, Blast Design is most important factor, in order to, create free-
faces for successive rows and column of holes.
The important factors on which generally progress of drifts and drives depends are:
1. Geology of strata and Rock mass condition
2. Appropriate blast design including drilling pattern, quantity and type of explosive, initiation
sequence
3. Types of drilling equipment used and length of drilling rod used
4. Dimension of Drives
5. Properties and VOD of Explosives used
The cost and time benefit of the excavation are mostly decided by the ‘Rate of Advance’. Therefore, it is
utmost important to have proper blast design with quality explosives used, in order to achieve
maximum rate of advance (Pull) per blast. ‘Burn’ cut (Parallel Holes with Reamers) blast design is
suitable for any dimension of Drift excavation and with proper Explosives, initiation sequences etc., it
can give considerable amount of Rate of Advance.
The said underground metal mines working for excavation of hard Dolomite based rock; only
development work is being carried out. Excavation for Development work such as Declines, Ore Drives
2. NEW BURN CUT BLAST DESIGN IN DRIVES ENHANCES DRILLING & BLASTING EFFICIENCY WITH
ECONOMY - A CASE STUDY
2 Author: Partha Das Sharma,
B.Tech(Hons.) in Mining Engg. (E.mail: sharmapd1@gmail.com)
Weblog: http://miningandblasting.wordpress.com/
at various levels, Ramps connecting Ore Drives etc., is being done. In underground mines development
headings provide; mine access for men & materials, ore & waste transportation, and ventilation paths.
Mechanism of creating additional free-faces for Drift blasting - In Drift blasting, explosives are required
to perform in a difficult condition, as single free face (in the form of drift face) is available in contrast to
bench blasting where at least two free faces exist. Hence, more drilling and explosives are required per
unit volume of rock to be fragmented in the case of Drift blasting. A second free face, called ‘cut’, is
created initially during the blasting process and the efficiency of the blast performance largely depends
on the proper development of the cut.
The Drift blasting mechanics can be conceptualized in two stages. Initially, a few holes called cut holes
are blasted to develop a free face or void or cut along the tunnel axis. This represents a solid blasting
condition where no initial free face is available. Once the cut is created, the remaining holes are blasted
towards the cut. This stage of blasting is similar to bench blasting but with larger confinement. The
results of Drift blasting depend primarily on the efficiency of the cut-hole blasting.
The specific constrain in driving drives is, unlike opencast bench blasting, absence of initial free faces.
Therefore solid blasting is carried out, for which, Blast Design is most important factor in order to
create free-faces for successive rows and column of holes.
The factors influencing the development of the cut and the overall blast results are dependent on a host
of factors involving rock mass type, blast pattern, Explosives used and the Drift configurations.
B. Development work at the Mines: Followings are the major excavation for development work being
done at the said underground mines:
* Declines with Dimension – 5m x 3m,
* Ore Drives for all the levels (Dimension -4.5m x 3m).
* For connecting the Ore Drives, ‘Ramps’ are driven (with Dimension – 4.5m x 3m) at an interval of 100
to 150m.
C. Drilling Equipment: As far as Drilling Equipment for Drifting is concerned, single-boomed Electro-
hydraulic jumbo drills are used for Drifting. Parallel holes and Reamer holes can be drilled very easily
and rate of penetration is also quite faster.
D. Blast Design and Drilling & Blasting for excavation of various development activities at the said UG
mines: For face blasting 40mm dia Cartridged Emulsion Explosives (each cartridge length 300mm,
contain 390gm explosives) with VOD of about 4000m/s, are used for 45mm dia holes. Drilling length
kept mostly 3.4m (or sometime 4.0m). Reamers of Dia 89mm are used. Long Delay Electric Detonators
are used for initiation.
Face blasting for Declines, Ramps, Ore-Drives and cross-cuts ‘Decked-Burn’ technique was used, using
Long Delay Electric Detonators (as given in Original pattern, Fig. 1). The salient features of the ‘Decked-
Burn’ system were:
* The collar portion of the hole was blasted prior to the bottom.
* Mid-column decking between the two charges in a hole was kept about 0.5m.
3. NEW BURN CUT BLAST DESIGN IN DRIVES ENHANCES DRILLING & BLASTING EFFICIENCY WITH
ECONOMY - A CASE STUDY
3 Author: Partha Das Sharma,
B.Tech(Hons.) in Mining Engg. (E.mail: sharmapd1@gmail.com)
Weblog: http://miningandblasting.wordpress.com/
Fig. – 1
Original pattern - With above pattern (shown in Fig-1), for 4.5m x 3m face size number of drilling hole
(with 3.4m) and Explosives requirements are given below:
Faces (with
Dimension)
Number of Hole
drilled
Number
Holes
charged
Explosives
used in a
round (Kg)
Detonator used
(No.)
Stemming
Length kept
(m)
4.5m X 3m face
(with 3.4m
Drilling Length)
* 46 with 45mm Dia
* 4 with Reamer
89mm dia (46+4)
42 120 50 (In burn
holes two
detonators
were used)
1.3 to 1.6m
Fig - 2
4. NEW BURN CUT BLAST DESIGN IN DRIVES ENHANCES DRILLING & BLASTING EFFICIENCY WITH
ECONOMY - A CASE STUDY
4 Author: Partha Das Sharma,
B.Tech(Hons.) in Mining Engg. (E.mail: sharmapd1@gmail.com)
Weblog: http://miningandblasting.wordpress.com/
E. Discussion on Decked-Burn Pattern (as shown in Fig – 1):
* As number of Holes were more, smaller quantity of explosives used per hole (6 to 8cartridges per
hole), resulting large stemming length (1.2 to 1.6m); causing a peculiar kind of failure – ‘UNDER-BLAST’
(as shown in Fig – 3), in which only inside is blasted and fragmented, whereas outside (Collar) rock
appears solid and intact.
* Difficult to handle the blasted rock with LHD loaders when there is ‘under_blast’.
* Difficult to deal with post blast sockets generated, sockets are hollow at the end (Fig – 3).
* To deal with above kind of failure re-drilling and re-blasting was common; affecting cycle time, cost
etc.
Fig-3
Fig – 4
5. NEW BURN CUT BLAST DESIGN IN DRIVES ENHANCES DRILLING & BLASTING EFFICIENCY WITH
ECONOMY - A CASE STUDY
5 Author: Partha Das Sharma,
B.Tech(Hons.) in Mining Engg. (E.mail: sharmapd1@gmail.com)
Weblog: http://miningandblasting.wordpress.com/
F. Searching for solutions:
* It was thought to modify the Decked-Burn Pattern by reducing number of Holes, in order to put more
quantity of Explosives (7 to 10 cartridges) in individual holes to reduce stemming length (0.6 to 0.8m), to
overcome above type of ‘Under-Blast’ failures.
* Also simplification of Explosive Charging procedure was thought of by doing away with the ‘Decked
Charging’ procedure.
* For this, New Design of ‘Rectangular Burn’ (with four Reamers) has been put forth, wherein ‘Deck
Charging’ is eliminated.
* Later, ‘Four-Reamers’ have been reduced to ‘Three-Reamer’ Burn.
G. Solving the problem - Three phased initiative for Re-designing the Drilling Pattern:
* In the first phase, one vertical line was reduced in order to reduce number of Holes in the Pattern and
the same ‘Decked-Burn’ was kept intact.
* By implementation of one reduced line, 5 Holes were reduced in the pattern, accommodating more
number of cartridges in a hole in order to reduce stemming length within 1m.
* In the second phase, full ‘Burn’ was re-designed (Non-Decked) and incorporated in the above reduced-
hole pattern.
* In this second phase another 4 number of Holes were reduced and also ‘Decked-Charging’ was
removed – providing simplification of Explosives charging process and further reducing stemming length
to about 0.6 to 0.8m.
* In the third phase one reamer was reduced. Instead of four, three reamers were used, without
affecting quality of blasts and pull.
Fig - 5
6. NEW BURN CUT BLAST DESIGN IN DRIVES ENHANCES DRILLING & BLASTING EFFICIENCY WITH
ECONOMY - A CASE STUDY
6 Author: Partha Das Sharma,
B.Tech(Hons.) in Mining Engg. (E.mail: sharmapd1@gmail.com)
Weblog: http://miningandblasting.wordpress.com/
Fig – 6
H. ‘DECKED-BURN’: Shortcomings (as experienced)
* For UG Drives Charging of Explosives is difficult and time-consuming.
* Interchanging Delays between inside and outside column of explosives takes place and because of
that blast failure occurs.
Idea of re-designing and to replace with ‘Non-Decked’ Burn came up in order to simplify the procedure
of charging of explosives and to prevent blast failure due to inadvertent interchange of Delay timings
between inside and outside explosives column.
I. Phase one - with above pattern (shown in Fig-5), for 4.5m x 3m face size number of drilling hole (with
3.4m) and Explosives requirements are given below:
Faces (with
Dimension)
Number of Hole
drilled
Number
Holes
charged
Explosives
used in a
round (Kg)
Detonator used
(No.)
Stemming
Length kept
(m)
4.5m X 3m face
(with 3.4m
Drilling Length)
* 41 with 45mm Dia
* 4 with Reamer
89mm dia (41+4)
37 118.5 45 (In burn
holes two
detonators
were used)
0.8 to 1m
7. NEW BURN CUT BLAST DESIGN IN DRIVES ENHANCES DRILLING & BLASTING EFFICIENCY WITH
ECONOMY - A CASE STUDY
7 Author: Partha Das Sharma,
B.Tech(Hons.) in Mining Engg. (E.mail: sharmapd1@gmail.com)
Weblog: http://miningandblasting.wordpress.com/
Fig – 7
J. Phase two - with above pattern (shown in Fig-7), for 4.5m x 3m face size number of drilling hole (with
3.4m) and Explosives requirements are given below:
Faces (with
Dimension)
Number of Hole
drilled
Number
Holes
charged
Explosives
used in a
round (Kg)
Detonator used
(No.)
Stemming
Length kept
(m)
4.5m X 3m face
(with 3.4m
Drilling Length)
* 37 with 45mm Dia
* 4 with Reamer
89mm dia (37+4)
33 117.5 33 (In burn
holes two
detonators
were used)
0.6 to 0.8m
8. NEW BURN CUT BLAST DESIGN IN DRIVES ENHANCES DRILLING & BLASTING EFFICIENCY WITH
ECONOMY - A CASE STUDY
8 Author: Partha Das Sharma,
B.Tech(Hons.) in Mining Engg. (E.mail: sharmapd1@gmail.com)
Weblog: http://miningandblasting.wordpress.com/
Fig – 8
K. Discussion on Trials and Performance of Blasts:
* Extensive trial-blast conducted at all the dimensions of drives, i.e., 4.5mx3m, 5mx3m and 5mx4m with
3.4m and 4.0m length of drilling.
* No failure as of ‘UNDER-BLAST’ observed.
* No re-blasting was also carried out.
* The performance of blasts (Average Pull obtained) is either same or better than the earlier pattern.
* It is observed that, with 4m length of drilling, at Ramp-Up pull is better than Ramp-Down.
* Side and Top corner sockets observed when there is deviation of Hole. Chances of Hole-deviation with
4m length are more than with 3.4m length.
L. Introduction of Third Phase: Reducing one Reamer hole (i.e., using only three reamers with 89mm
Dia.):
* Later, reduction of one Reamer hole was thought, keeping quantity of explosives and detonator timing
same.
* Number of trials was taken-up with this three reamer system (89mm Dia.) at both 4.5x3m and 5x3m
faces.
* All the trial blasts were successful; with similar performance as of four reamers.
* Drilling cost and time has been reduced further.
9. NEW BURN CUT BLAST DESIGN IN DRIVES ENHANCES DRILLING & BLASTING EFFICIENCY WITH
ECONOMY - A CASE STUDY
9 Author: Partha Das Sharma,
B.Tech(Hons.) in Mining Engg. (E.mail: sharmapd1@gmail.com)
Weblog: http://miningandblasting.wordpress.com/
Fig -9
Phase three - with above pattern (shown in Fig-9), for 4.5m x 3m face size number of drilling hole (with
3.4m) and Explosives requirements are given below:
Faces (with
Dimension)
Number of Hole
drilled
Number
Holes
charged
Explosives
used in a
round (Kg)
Detonator used
(No.)
Stemming
Length kept
(m)
4.5m X 3m face
(with 3.4m
Drilling Length)
* 36 with 45mm Dia
* 3 with Reamer
89mm dia (36+3)
33 117.5 33 (In burn
holes two
detonators
were used)
0.6 to 0.8m
M. Discussion on Advantages of New Pattern:
* With new Blast design, blast failure of ‘Under-blast’ kind and re-blasting is eliminated completely.
* As this new blast design does not use ‘Decked charge’ at the ‘Burn’, the number of Detonators
used are considerably less and also gives ease in charging (Charging time is reduced).
* As the number of drilled holes is considerably less, the Drilling (Percussion) Time is reduced.
* Thus, Cycle time of Drilling and Blasting is reduced considerably – Working Efficiency is enhanced.
* As drilling efficiency is enhanced (Number of Drilling is reduced) drilling cost also reduced.
* This is evident from the fact that, now two full faces are drilled and blasted in one shift, thereby
enhancing efficiency.
10. NEW BURN CUT BLAST DESIGN IN DRIVES ENHANCES DRILLING & BLASTING EFFICIENCY WITH
ECONOMY - A CASE STUDY
10 Author: Partha Das Sharma,
B.Tech(Hons.) in Mining Engg. (E.mail: sharmapd1@gmail.com)
Weblog: http://miningandblasting.wordpress.com/
* Number of Detonators reduced considerably per blast and also quantity of Explosives (Thus, powder
factor, Detonator factor have been improved).
* Now this three reamer system has been continued in both 4.5m x 3m and 5m x 3m faces, which
further reduced cost and enhanced drilling and blasting efficiency.
N. Summary and conclusions:
Below tables shows how numbers of holes have been reduced; thus, enhancement of drilling and
blasting efficiency and working cost:
For face dimension 4.5m X 3m (with 3.4m Drilling Length):
Design
Changes
Number of
Hole
drilled
(45mm +
89mm dia)
Number
Holes
charged
Explosives
used in a
round
(Kg)
Detonator
used (No.)
Reduction in Drilling
(no. of holes) from
previous phase
Reduction in
Explosives and
Detonators
quantity from
previous phase
Expl Det
Original (46+4) 42 120 50 Decked- Burn --- ---
Phase - I (41+4) 37 118.5 45 Decked-Burn, reduced
no. of holes by 5
(45mm)
1.5Kg 5 no.
Phase - II (37+4) 33 117.5 33 Non-Decked Burn,
further reduction in no.
of holes by 4 (45mm)
1.0 kg 12 no.
Phase - III (36+3) 33 117.5 33 Non-Decked Burn,
further reduction in no.
of holes by 2 (One
45mm and one 89mm
dia. Reaming hole)
--- ---
Final reductions from Original pattern 11 no. of holes (10 of
45mm and 1 of 89mm
dia)
2.5 kg 17 no.
Note: Average Time taken for drilling a hole of 3.4m length by Jumbo drill is 2.5min. Overall 20 to 22%
of drilling time and cost have been saved. Similarly, Charging time has also reduced as ‘Decked-Burn’
system eliminated.
As number of drilling holes have been reduced considerably, the percussion time and drilling meterage
has been saved. Cost of drill Bits also saved considerably. Moreover, total 2.5kg of explosives and 17
numbers of Electric Delay Detonators have been saved – thus, reducing costs. Similar advantages
obtained for 5m x 3m faces with 3.4m drilling and also with 4m drilling at 4.5m x 3m faces.
Upon obtaining satisfactory performance result, enhancement of efficienciy and eliminating blast
failure such as Under_Blast etc.; the new blast pattern has been fully incorporated for all the
development section of the said underground mine.
Disclaimer: Views expressed in the article are solely of the author’s own and do not necessarily belong to any of the Company
or institution.