Research and development on explosion and prevention of explosions in mines

RESEARCH AND DEVELOPMENT ON
EXPLOSION AND PREVENTION OF
EXPLOSIONS IN MINES
MINE ENVIRONMENT ENGINEERING
MN331 ASSIGNMENT-1
Presented by
PATI JAYA CHANDRA
113MN0480
GROUP-1
1

Overview
• EXPLOSION
• Mechanism of Explosion
• Types of Explosions
• PREVENTION OF EXPLOSIONS
• Explosion Protection Plan
• Explosion Control Measures
• References
2

EXPLOSION
• In coal mines there are hazards that are inherent to the coal seam
and those that are introduced by the mining method.
• One of the most devastating events that can occur in a mine is an
explosion.
3

EXPLOSION
• An explosion is a rapid increase in volume and release of energy in
an extreme manner, usually with the generation of high
temperatures and the release of gases.
• Having an explosion underground can result in the loss of
personnel and the loss of the mine itself or a significant portion of
it
4

Mechanism of explosion
For an explosion to occur four main elements must coexist. These
are
• Fuel
• Oxygen
• Energy source
• Chemical chain reaction.
5

Fuel
• The most common fuel sources for explosions in underground
mines are flammable gases and explosive dust.
• In coal mining flammable gases can be present as a seam gas, or
produced as a result of oxidation or distillation of coal.
• The extraction process can generate fine coal dust that could
provide sufficient fuel for an explosion.
6

Oxygen
Ventilation air is supplied to the mine to support life, provide oxygen for
internal combustion engines, dilute and render gases harmless and to
provide comfortable working environments by removing heat, dust and
humidity.
An airflow between 7 and 20 m3 /s with an emission of 1000 l/s would
create an explosive mixture.
7

Energy source
The energy sources that are found in and around mines are numerous.
They are
• Diesel and Mechanical equipment
• Explosives
• Electrical infrastructure and equipment
• Frictional ignitions
8

Chemical Chain Reaction
The effects of changing pressure on the auto-ignition temperature and the
widening of the flammable range with elevated temperatures. These
relate to the continuance of a chemical chain reaction that transfers
energy throughout the mixture. If the amount of energy that is transferred
into the adjoining unreacted mixture is insufficient, then the reaction will
cease in that direction even though it may be within the flammable range.
9

The above fuels, ignition sources and airflows can, in the right
condition of coexistence, form a flammable or explosive
atmosphere. If undetected, the by-products of fire may be carried
throughout the mine or tunnel workings, creating the potential for a
deadly atmosphere – either not fit for respiration, or explosive, or
both.
10

Types of Explosions
Explosion in mines can be of three types:
• Methane explosion
• Coal dust explosion
• Water gas explosion (rare)
11

Methane Explosion
Methane forms in coal seams as the result of chemical reactions
taking place when the coal was buried at depth. Methane occurs in
much higher concentrations in coal than other rock types because of
the adsorption process, which enables methane molecules to be
packed into the coal interstices (gaps or spaces) to a density almost
resembling that of a liquid.
12

Methane Explosion
• Methane is flammable when mixed with oxygen in a wide range of
concentrations, but generally between 5-15% methane in air by
volume.
• The auto ignition temperature of methane is 537°C.
13

Methane Explosion
Methane explosions are characterized by two distinct operations:
• Direct blast
• In direct blast, a pressure wave of great force and speed travels
ahead of explosion flame.
• Back lash
• The back lash is caused by vacuum arising out of cooling of
explosion gases and condensation of water vapor and is of less
intensity than direct blast but traverses the same path backward.
14

Coal Dust Explosion
• Coal dust is finely divided matter smaller than 100 micrometer
(µm) and of low mass. It can remain suspended in air for a
relatively long time and is hazardous because it can be carried
through the ventilation system for hundreds of meters, gradually
falling out at various places along roadways and workings.
15

Coal Dust Explosion
• In a methane explosion, if enough wind pressure is created, the
coal dust is raised into the air and re-distributed, potentially
igniting a more deadly secondary coal dust explosion.
• For a coal dust explosion to take place in mines, two conditions
must be fulfilled.
16

Coal Dust Explosion
The dust is present as dense cloud and a source of ignition in the
form of flame must be present. The maximum flame temperature at
stoichiometric composition is about 2500 0K. In practice it varies
from 800-1000 0C. Maximum explosion pressure upto 7 bars
possible.
17

Conditions for Coal Dust explosion
• A combustible dust
• The dust is suspended in the air at a proper concentration
• oxidant
• The dust should be confined
• Ignition source
• If any of these five conditions is missing there can be no dust
explosion
18

Ignition Criteria for Coal Dust Explosion
• Burning Embers and Agglomerates
• Self-Heating
• Impact/Friction
• Electrical Equipment
• Firedamp explosions
19

Factors affecting coal dust explosion
• Particle size
• Dustiness of Mine Working
• Volatile matter
• Percentage of ash, moisture, fire damp
• Oxygen concentration
• Nature and intensity of ignition source
20

Prevention of Explosions
EXPLOSION PROTECTION PLAN
The fire and explosion risk assessment process will have identified
the potential fire and explosion hazards present, the risks they give
rise to, and the measures neces.sary to avoid and control those risks
21

The explosion protection plan required by regulation 4 of The Mines
Miscellaneous Health and Safety Provisions Regulations 1995 will
need to set out those measures to be taken:
• To prevent an explosive atmosphere occurring
• To exclude, or control, potential sources of ignition;
22

• In the event of an explosive atmosphere of any type occurring or
where the concentrations of flammable gas in the mine air exceed
legal limits
• To mitigate the consequences if an explosion occurs.
23

• The measures which will need to be set out in the plan may include:
• Firedamp drainage arrangements to control emissions of firedamp from
the strata and waste areas
• Ventilation arrangements (both main and auxiliary) to control the level
of firedamp in the atmosphere and prevent explosive atmospheres
occurring
24

• Arrangements for monitoring and detection of dangerous levels of
firedamp by the use of portable automatic firedamp detectors at
suitable places
• Arrangements for automatically cutting off power supplies to
equipment in singleentries should the auxiliary ventilation system
fail
25

EXPLOSION CONTROL MEASURES
• These fall into six broad categories:
• Zoning of the workplace
• Selection of suitable equipment
• The prevention of explosive atmospheres
26

• De-energizing equipment in explosive or potentially explosive
atmospheres
• The control of other ignition sources
• Degassing operations
27

Zoning
zoning is the only basis from which they can identify equipment
appropriate for use in particular circumstances. The zones where
different types of explosive atmospheres (gas, dust, vapor or mist)
could occur may not be the same and may not even overlap, so it
will be necessary to zone for each type of potential explosive
atmosphere.
28

The selection of suitable equipment
• The categories of the explosion protected equipment
• The way these categories are to be used in ‘explosive’ and ‘potentially
explosive’ atmospheres
• The explosive atmosphere being formed by either gas, mist, vapor
and/or flammable dust under normal atmospheric conditions
• The type of explosion protected equipment
29

Equipment for use in explosive atmospheres below ground
When an explosive atmosphere of any kind exists, only Category M1
equipment, or equipment previously approved to remain energized, is
permitted because of its very high level of protection.
While cap lamps are categorized as category M2, a mines rescue team
could be allowed to wear them in an explosive atmosphere for a short
period of time to save life
30

Equipment for use in potentially explosive atmospheres below
ground
Where a potentially explosive atmosphere exists, both M1 and M2
equipment and their equivalents may be used.
31

Preventing an explosive atmosphere occurring
The principal measures to prevent the build-up of an explosive
atmosphere are:
• Ventilation systems (including local exhaust ventilation systems)
for explosive gas, mist and vapor atmospheres
• Firedamp drainage for explosive gas atmospheres
32

• Removing flammable dust from the mine, or consolidating it so
that it cannot be raised into the air
• Where flammable dust is likely to settle, maintaining a sufficient
proportion of incombustible dust in mine roadways such that an
explosive dust atmosphere will not occur if it is raised into the air.
33

De-energizing equipment used in potentially explosive atmospheres in
mines
If the concentration of firedamp in the general body of mine air exceeds
1.25% the only electrical equipment that should remain energized is that
which is both safe for use in an explosive atmosphere and is necessary to
secure the safety of people in the mine, including their escape and
rescue.
34

The Equipment and Protective Systems Intended for Use in
Potentially Explosive Atmospheres Regulations 1996 require all
category M2 equipment, both electrical and nonelectrical, to be
deenergized when the atmosphere changes from being potentially
explosive to explosive.
35

Control of other ignition sources
Naked lights
Section 62 of The Mines and Quarries Act 1954 prohibits the use of lights
other than permitted lights in all mines where there is a risk of an
explosive atmosphere occurring, and section 67 prohibits the use in such
mines of equipment designed or adapted to produce an unprotected flame
or spark.
36

Where there are frictional ignition risks owners and managers will need to
take appropriate preventative and protective measures including:
• Adequate ventilation
• Water ignition suppression systems, such as pick-back-flushing
• Equipment design - certain types of picks and pick configurations are
less likely to produce incentive sparks than others.
37

Degassing operations
Mine owners and managers should design the mine layout, drivage
sequence and mining systems to minimize the opportunity for dangerous
concentrations of flammable gas to accumulate and avoid the need to
degas. Managers should in particular avoid unventilated single entries
and, in seams where an explosive atmosphere will form quickly, to have
standby systems, such as venturi, that operate if the auxiliary fan(s) stop
38

References
• https://www.business.govt.nz/worksafe/information-
guidance/all-guidance-items/fire-orexplosion-in-underground-
mines-and-tunnels/acop-fire-explosion-mines-tunnels-pdf
• http://www.mineaccidents.com.au/uploads/explosion-case-
study.pdf
• http://www.hse.gov.uk/mining/feguidance.pdf
39

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