/ Rapid Environmental Impact Assessment Study for the Proposed Capacity Expansion of Bauxite Mines from 3.0 MTPA to 8.5 MTPA at Baphlimali Plateau
Chapter-2
Proposed Mining and Sources of Pollution

2.0PROPOSED MINING AND SOURCES OF POLLUTION

2.1Introduction

This chapter deals with the geology of the mining lease area, exploration details, evaluation of the deposit, estimation of reserves, method of mining, machinery, phase wise mineral extraction details, details on infrastructure, various sources of pollution and the control measures.

2.2Description of the Mines

The general and technical details of the mining operations are given in
Table-2.1.

TABLE-2.1

DESCRIPTION OF MINES

Sr. No.

/

Parameter

/

Description

I

/

General Mine Features

1 / Latitude
Longitude / 19o18' N to 19o22' N
82o57’ E to 82o59' E in Toposheet 65 I/15
2 / Site and its surroundings / Site is a hillock with plateau top, ground slope varies between 1:40 and 1:5 and at few places slopes are steeper than 1:10.
3 / Pre mining landuse / Barren and waste land
4 / Distance from proposed refinery / 16.0-km (Aerial)
5 / Streams / Nallahs / Nil on plateau top, except a few rain-fed run-off channels
6 / Nearest stream / river / Khandabindha nallah, a major tributary of Indravati River (0.5-km, N of plateau bottom)
II /
Mine Technical Features
1 / Method of mining / Opencast mechanised mining
2 / Proposed Production from the mine lease / 3.0 MTPA (Before expansion);
8.5 MTPA (Total after proposed expansion)
3 / Expected total Overburden / 153.42 Million Tonnes
4 / Total ML area / 1388.74-ha
5 / Mineable Reserves / 194.5 Million Tonnes
6 / Extent of mechanization / 100%
7 / Type of Blasting / Deep hole blasting with delay detonators
8 / Type of drilling / Down the hole drilling
9 / Power requirement / 3000 kW
10 / Source of Power / From CPP of alumina plant
11 / Water requirement / 720 m3/d (Before expansion)
2000 m3/d (Total after expansion)
12 / Water source / San river water
13 / Waste water Generation
a / Domestic waste / 40 m3/d (Total after expansion)
b / Industrial waste / 220 m3/d (Total after expansion)
C / Mine water discharge / Nil
14 / Waste Water Treatment
A / Sanitary waste / The sanitary waste from the mine service yards is treated in Sewage Treatment Plant
b / Industrial waste / Vehicle wash water and workshop wastewater will be treated in oil water separator and sent to STP
15 / Noise Levels / Maintenance of HEMM to keep the noise levels <85 dB(A)
16 / Ground vibration / Within the safe limits
17 / Solid waste generation / Overburden – 6.2 MTPA
18 / Fire Fighting System / Adequate fire fighting systems will be provided on all HEMM
19 / Stripping ratio
(ore : overburden) / 1.4 : 1

2.3Geology and Hydrogeology

2.3.1Physiography

Baphlimali plateau forms a part of Eastern Ghat hills. The plateau top is generally flat and the elevation varies from 990-m to 1093-m. The plateau is devoid of vegetation in most part. The ground elevation in the plains is about 750-m.

2.3.2Existing Drainage

The Baphlimali plateau top has a relatively flat relief with slopes towards the fringes of the plateau.

The plateau top has no streams or nallahs, except the run-off of rainwater during monsoon. A number of springs originate from the foothills of the plateau at about 100-150m below the plateau top. The streams originating from the foothills of the Baphlimali Plateau have been assessed for its quality and quantity. These streams originating from Baphlimali either join Khandabinda nallah on north or San nallah on the south of the deposit.

River Indravati, the main water course in the region, flows in SW direction on the W side of the deposit at a distance of 7.5-km. The Khandabinda nallah, a major tributary of Indravati River, flows at about 0.5-km in N. San nallah is flowing at about 7.5-km in S direction from the plateau.

Surface water flow measurements indicate that the flow is gradually decreasing from December to April. Earlier, flow measurements indicate that the flow in these streams decreases further and the minimum flow is observed during first or second week of May. However, the streams are perennial in nature.

Quality of both surface water and groundwater is good without high concentration of pollutants. The pre mining surface drainage pattern of the mine lease area is shown in surface map under Figure-2.1.

2.3.3Geology

2.3.3.1 Regional Geology

The lateritisation of the east coast bauxite deposits was developed at the expense of gneisses and schists. The dominant rock assemblage in the region, comprise khondalites (quartz-garnet-potash-feldspar-sillimanite gneisses with or without graphite) and its variants. These are high grade metasediments of argillaceous, arenaceous and calcareous nature. The other group includes charnockites (hypersthene-diopside granulites) and its equivalents, porphyritic granite gneisses etc. of Precambrian age. The general stratigraphic succession is as follows:

Recent alluvium and soil / Recent
Ferruginous and aluminous laterite and bauxite (on hill tops) / Tertiary
------Unconformity------
Garnetiferous porphyritic granodiorite and gneiss with later leuco-granite (Charnockite suite) / Precambrian
Garnetiferous quartizite, graphite sillimanite - garnet B quartz gneiss (Khondalite suite)

2.3.3.2 Geology of the Deposit

The deposit occupies the crest of Baphlimali Parbat, a hill in the Eastern Ghats. The hill is essentially composed of khondalites with charnockites occurring in the south-eastern part of the hill. The formations have NE-SW trend and steep south-easterly dips of 50-80 degrees.

The important characteristics in the profile of Baphlimali deposit are summarised below:

  • Top soil is mostly lateritic in nature varying between 0-2m in thickness and covers almost 50% of the plateau area.
  • The laterite is more ferruginous and siliceous at the top where it is hard and has cloggy, cavernous look. It gradually becomes more soft with depth where it is aluminous in nature grading into bauxite. The clay bearing areas and clayey laterites, occurring on the surface, are marked by growth of dwarf - palms.
  • The bauxite shows gradational contact with overlying laterite and has a fairly sharp contact with the underlying partially leached parent rock.
  • Roof of bauxite, due to gradational contact with overlying laterite, is a chemical boundary and thus becomes a function of cut-off grades adopted by the user.
  • Floor of bauxite has a sharp contact with underlying partially lateritised Khondalite (PLK)/partially Kaolinised Khondalite (PKK). The undulations on bauxite floor are rapid and sharp as compared to those on the roof.
  • There are some occurrences of PLK/PKK mixed bauxite and also aluminous laterite patches within the bauxite column as inside waste.
  • The average thickness of overburden and bauxite globally for the deposit is estimated to be 9.84-m and 11.51-m respectively.
  • There is a gradual decrease in hardness and compactness of bauxite from top to bottom.

There are few small patches of no-ore zones (non mineralised areas) which have been confirmed by drilling. These no-ore zones are formed either due to exposures of Khondalite on the surface or due to non-enrichment of alumina in the entire lateritic/ bauxitic column.

  • Geomorphology - Surface Features

The laterite cover occupies the crest of the hill between 990-m and 1093-m RL with a relief of about 103-m, Baphlimali is characterised by a relatively flatter profile when compared to other bauxite plateau in the east coast region. The ground slope varies between 1:40 and 1:5. Slopes steeper than 1:10 are rare. Nearly half of the peripheral length of the plateau (29.5 km) is marked by scarps (2-17 m height) with an average of 8-m. The scarps are better developed in the eastern side where the maximum thickness of bauxite has been observed. The scarps are generally aligned sub-parallel to the strike of the formation. The ground slopes do not show any diagnostic relationships with ore characteristics. However, they may be broadly correlated as follows:

The surface of the plateau is largely covered with lateritic soil. There are, however, a few impersistent narrow exposures of pisolitic laterite (essentially ferruginous) dissecting the capping at places and a few weathered khondalite exposures restricted to the high topographical zone. Some partially lateritised khondalite patches (PLK) could be seen with laterite exposures. Most of the scarps expose only the partial thickness of the laterite/bauxite column and a few others do expose the PLK/weathered khondalite.

Bauxite is considered to have been derived by the in-situ chemical weathering of the khondalites. It occurs as a gently dipping or near horizontal blanket capping over partially lateritised or weathered khondalite. Both laterite and bauxite show relict foliation

The average thickness of ore body is arrived at by weighting the thickness of the bauxite zone indicated by exploration points spaced at regular grid intervals against their areas of influence. Narrow discrete partings of non-ore intervening with bauxite have been included in bauxite for practical considerations. Where thickness is so high as to convert the quality of material into non-ore if combined with bauxite, only one subzone, generally the top one, has been accepted as bauxite. The reserves of zone below the non-ore partings have been estimated separately. The various lithounits adopted for the current exercise are as follows:

DETAILS OF LITHOTYPES

Litho Unit Number / Lithology / Thickness Range (m) / Average Thickness (m)
1 / Soil and soil mixed laterite / 0-2 / 0.5
2 / Hard Laterite with very high slilica / 2-5 / 3
3 / High silica aluminous laterite / 2-3 / 2
4 / Low silica aluminous laterite / 1-2 / 1
5 / Bauxite / 6-41 / 13
6 / PLK/PKK mixed with bauxite / Deeper / -
7 / PLK/PKK and Khondalite / Deeper / -

The detailed description of different lithotypes is as follows:

Lithounits 1 and 2 essentially form a part of overburden at the top. Lithounit 3 is predominantly occurring as overburden below the lithounit 2. However, there are few occurrences of lithounit 3 within the ore column as inside waste. Lithounit 4 occurs equally as inside waste within ore column and as bottommost layer of overburden just above the ore-roof. Lithounit 5 is typical bauxite and forms more than 90% of the ore column. Lithounit 6 invariably occurs just below the ore column within one to two meter horizon. However, there are few instances of lithounit 6 occurring as inside waste within the ore column. Lithounit 7 is essentially a bottom waste below the lithounit 6 and thus is not significant from point of view of mining/ wining the ore.

From the above it is obvious that litho units 1, 2 & 7 are not expected to mix with ore during mining. Thus litho units 3, 4, 5 and 6 are important for defining ore column and mineable column in individual drill holes.

2.4Exploration and Exploitation

Drilling is the most important exploration activity undertaken during this exploration, especially since most of the deposit is covered under capping of soil. The pattern and type of drilling for proving a given deposit depends on the topography, shape, size, extent, compositional variation, attitude of beds and structure of the deposit. Taking these parameters into consideration, scientific drilling was adopted.

The lease area has been extensively explored in detail by Geological Survey of India (GSI) (during 1976-77), Mineral Exploration Corporation Limited (MECL) (during 1978-81), INDAL (during 1992) and MECL (during 1998-99) to establish mineral reserves. Details of exploration carried in the lease area are described below:

TABLE 2.2

SUMMARY OF TOTAL EXPLORATION WORKS

Sr. No. / Agency / Year / Summary of Works
1 / GSI / 1976-77 / Drill holes: 52
Meterage : 1445.65
No. Of drill hole samples : 1240
2 / MECL / 1978-81 / Drill Holes : 530 (504 vertical + 26 inclined)
Meterage : 17843.55 (16758.15 vertical + 1085.40 inclined)
No. of Samples : 21837
Deep pits : 33
Meterage : 955.40
61 m3 of trenching
341 samples studied for petrology & minerology
Moisture and Density determinations
3 / INDAL / 1992 / Redrilling of 30 holes by vacuum suction located on MECL bore hole points, meterage 792
Resampling of 6 nos. of MECL pits
4 / MECL / 1998-99 / Drill holes : 45
Meterage : 1228
No. of samples : 1209

2.4.1Exploration as done by MECL

Based on the resource evaluation studies done by GSI, MECL planned and executed detailed exploration programme at the instance of Govt. of India. The methodology followed by MECL has been described in the following sections.

2.4.1.1 Method of Exploration done by MECL

a)Topographical Surveying

Triangulation and levelling survey was carried out over the entire bauxite plateau and a network of 26 Triangulation stations was laid down. All GSI bore holes were also connected to these stations.

A central axial line and cross-section lines at every 200 m interval (or less in selected areas) were laid from the nearest triangulation station. The survey grid was connected to Survey of India Triangulation Station T-10 at 1093.22 m (Topo Sheet No. 65 I/15). The base plan for geological mapping was developed on 1:2000 in three parts covering the entire plateau top.

b)Geological Mapping

The detailed geological mapping was done to demarcate:

  • Lithological boundaries;
  • Outcrops of laterite based on visual;
  • Bauxite estimation;
  • Clay estimation;
  • Khondalite (including Kaolinised and partially lateritised khondalites); and
  • Structural features, viz.
  • Attitudes of foliation in khondalites and relict foliation
  • Plunges of minor folds

Apart from visual examination, limited shallow pitting was also carried out to demarcate contact between bauxite and non-bauxite.

c) Drilling

Since the experience with wet drilling in other East-Coast Bauxite deposits did not yield acceptable core recovery, conventional rotary dry drilling techniques using tungsten-carbide tipped casing bits (NX in first 5m and BX in the rest) was adopted to ensure full recovery. Core by this method was obtained in the form of powder or chips. Air flush coring method was used in a few cases where hard laterite was encountered particularly in the top layers.

A total of 504 Vertical and 26 inclined holes were drilled covering 17,843.38-m drillage. 33 deep pits were also used. The depth of vertical holes ranged from 18.65-m to 55.10-m and depth of inclined holes ranged from 24.50-m to
57.67-m.

After studying the lithomaps of pit walls, it was concluded that the bauxite grade revealed in pits is inferior to the ones revealed in corresponding bore holes and this dilution is mainly caused by fluctuations in ore-floor and partly by fluctuation in ore-roof over the areal extent (2.5m x 2.5m) of the pit.

2.4.1.2 Resource Evaluation by MECL

Surface geological studies and voluminous sampling data obtained from bore holes, deep pits, trenches and scarps formed the basis for MECL to determine spatial characteristics of Baphlimali bauxite & overburden and chemistry of bauxite and associated rocks. These were used subsequently in estimating reserves and grades of bauxite.

2.4.1.3 Results of Reserve Estimation by MECL

The overall in-situ reserves and grades of Baphlimali bauxite deposit following the above procedure by MECL using chemical cut off at +40% Al2O3 and -5% SiO2 has been estimated as under:

Total surface Area explored: 9.466 km2

Overburden:Mean Thickness is 9.84-m and Total Quantity is 153.33 MT

Bauxite:Mean Thickness is 11.51-m and Total Quantity is 186.43 MT

Average Quality of Bauxite: Al2O3 -44.95%; SiO2 -1.9%; Fe2O3 -26.34%; TiO2 -2.07%; and LOI -24.19%

The surface plan for the mine lease is furnished as Figure-2.1. The geological plan for the lease area applied for renewal on 1:2000 scale is given as Figure-2.2.

2.4.2Geological Sections

A total of 41 vertical sections running at right angles to the general strike (N40030'E) of Khondalite were drawn interactively on the graphic screen where for each hole OB column, ore column and their respective grades were displayed. One longitudinal section trending N40030'E was additionally drawn for evaluating the mineral continuity. The geological sections drawn on 1:5000 are shown in Figure-2.3.

2.4.3Adequacy of Exploration Done

Based on the experience of a similar working mine now in operation, it may be concluded that the level of exploration done is adequate for an investment decision at Baphlimali Plateau. This is reflected from the fact that this working mine was drilled at 200-mx200-m to 200-mx400-m grids at the time of investment decision and the working experience has shown broad conformity with subsequent phases of global estimation without any surprises.

It is thus clear that the present level of exploration in Baphlimali deposit by MECL provides adequate confidence in taking an investment decision to develop mines for supplying bauxite to the alumina plant, with a consistent quality.

FIGURE-2.1

SURFACE PLAN OF MINE LEASE AREA

FIGURE-2.2

GEOLOGICAL PLAN OF MINE LEASE AREA

FIGURE-2.3(A)

GEOLOGICAL LONGITUDINAL SECTIONS OF MINE LEASE

FIGURE-2.3(B)

GEOLOGICAL TRANSVERSE SECTIONS OF MINE LEASE

2.4.4Future Exploration

At the first instance the deposit, as a whole, needs to be covered by 100m grid spacing to generate sufficient information necessary for basic engineering. This permits block-wise estimates for the deposit for blocks of 100-mx100-m with sufficient accuracy, and would help in drawing up an accurate enough mining programme adapted to the deposit characteristics.

This step should be followed by a closer grid of say 25-mx25-m in the immediate area of interest to generate short and medium term plans as the project progresses. Smaller grid spacing, can only study a restricted area of the deposit, but with greater accuracy. These should, therefore, be distributed in the areas at least one and a half years ahead of mining faces in order to have advance information before mining takes place in the area.

All the future drilling campaigns (Phases I, II & III) will need to be undertaken concurrently at varying paces. No of holes required annually for Phase I & II drilling is 123, based on a time frame of 2 years for Phase I and 5 years for Phase II drilling. Phase III drilling should however be at a much faster pace and should start one and a half years before start of overburden removal. This lead should continue throughout so that advance information is available on small dimension blocks. The annual meterage required to be drilled works out to 3,33,900 m.

2.5Reserves

2.5.1 Categorisation of Reserves

Under UNFC classsification, the total deposit reserves need to be reported under the following eight categories:

A Mineral Reserve

1.Proved Mineral reserve (111);

2.Probable Mineral Reserve (121 & 122).

B Remaining Resources

1.Feasibility Mineral Resource (211);

2.Prefeasibility Mineral Resource (221 & 222);

3.Measured Mineral Resource (331);

4.Indicated Mineral Resource (332);

5.Inferred Mineral Resource (333); and

6.Reconnaissance Mineral Resource (334).

2.5.2 Estimation of Reserves

  • Geological Reserves

Summary of global resources based on 2D kriging is given in Table-2.3. While estimating grades from their accumulation, the kriging variance of the estimated grade is computed as per standard method.