Blasting Technology - Blast Design

Blasting Course

Designing Blasts

Two important aims in blasting.


To fragment the rock to a desirable size and
To displace the fragments a desirable distance

At the best overall cost 6

5

4 Cost/m3

Explosive Drilling

3

Load & Haul Crushing & M illing Overall Cost

2

1

0 0.5

0.7

0.9

1.1

Powder Factor (kg/m3)

Three things that affect outcome

Explosive Rock Blast Geometry

Rock


Rock Strength
Rock Density
Rock Structure

Rock Strength and elasticity
UCS and Tensile Strength
Has an influence on creation of cracks during blasting
Measured in MPa
Tensile strength about 1/10th UCS

Rock Density
Influences the displacement distance during a blast
Influences fragmentation
Higher density = higher energy for same end result

Rock Structure
Rock Structure has largest influence on fragmentation results.
Sometimes fragmentation completely controlled by structure

Rock Structure

Rock Structure

Rock Blastability Index
Rock UCS
Rock density
Joint Spacing
Joint Orientation

 UCS + 23.7  RBI = 0.5  + Rock Density + JPO + JPS + RMD 47.6  

Blast Geometry

Burden and Spacing

Effektiewe breeklas

Int

eri m

vry e

Spasiëring Breeklas

fr o nt

Breeklas Hoof vrye front

Equilateral Pattern

A = B =C or Base = 1.15 x height A

B

C

Spacing = 1.15 x Burden (in plan, energy distributed evenly.) Red circles represent contours of equal energy around each borehole. Spacing > 1.15 x Burden (in plan, energy not distributed evenly and more overlap can be seen in the energy contours in one direction.)

Staggered Pattern

Wherever possible use a staggered pattern. A square pattern is only suitable for narrow boxcut blasts

Deciding on Burden - Scaled Burden

Burden Scaled Burden = Mc

Burden = Scaled Burden × M c

Scaled Burden

For Reduced Heave or coarser fragmentation Shale/Mudstone Sandstone Limestone/Dolomite Granite Dolerite

RBI = 20 to 40

RBI = 40 to 60

RBI = 60 to 80

1.3 1.2 1.2 1.2 1.1

1.2 1.1 1 1 1

1.1 1 1 0.9 0.9

For increased heave or finer fragmentation Shale/Mudstone Sandstone Limestone/Dolomite Granite Dolerite

RBI = 20 to 40

RBI = 40 to 60

RBI = 60 to 80

1 1 0.9 0.9 0.8

0.8 0.8 0.75 0.7 0.7

0.7 0.7 0.65 0.6 0.6

Burden Stiffness

bench height Sb = ≥ 2.5 burden

Burden Stiffness - Matching bench height to hole diameter Poor explosive distribution. Only the bottom half of the bench contains explosive. Tendency to crater because the surface is closer than the vertical free face. This results in A tendency for uncontrolled fly rock Poor fragmentation in top half of bench Uneven floors Very little muckpile movement

Explosives Energy

kg per hole Design Powder Factor = Burden × Spacing × Bench Height

total kg Actual Powder Factor = block volume

Energy Factor = Powder Factor × RWS

Stemming
Stemming affects the following results in a blast: – Fly rock – Air blast – Fragmentation – Heave
All blasts require stemming

Ineffective Stemming

Excessive Fly Excessive Noise Poor Fragmentation Poor Heave

Effective Stemming

Fly rock control Air blast control Optimal fragmentation Optimal heave

Stemming Effectiveness:

Worst

Best

Air Water Drill cuttings in water Clay Drill cuttings in dry hole Crushed aggregate - ungraded Crushed aggregate - graded

Factors affecting stemming performance


Stemming material
Stemming length
Rock strength
Explosive energy
Stemming length = 15 to 30 x diameter

Scaled Depth of Burial

 M c • 8 •φ  S = Ds    1000  Scaled Depth of Burial

0.7

0.33

1

 4φ  −   1000  1.2

1.5

1.7

Hard rock

much fly

normal fly

little fly

no fly

no surface expression

Soft rock

much fly

much fly

normal fly

little fly

no fly

Crater tests to determine site specific values


Scale depth of burial
Maximum Burdens
Explosives performance and comparisons

Crater tests:

Surface Expression Fragmentation Crater Volume Vertical Displacement Velocity

Sub-drill

Insufficient Sub-drill =
Uneven floors with high bottoms
Difficult digging conditions at the bottom of the muckpile

Sub-drill

Usually set at 20 to 50% of burden

Q = 0.39M c B

Fragmentation 100% of muckpile is less than 1100 mm or largest boulder size is 1100 mm

100

% Passing

80

60 49% of muckpile is less than 300 mm

40

20 10% of muckpile is less than 60 mm

0 1

10

100

Fragment Size (mm)

1000

10000

Uniformity 100 uniformity = 1.4

80

% Passing

uniformity = 0.4 60

40

20 uniformity = 0.8 0 1

10

100

Fragment Size (mm)

1000

10000

The final fragmentation influences:
Diggability: Impacts loading rates and wear and tear on equipment
Coal exposure rates: Impacts mine profitability

Kuzram model
Explosive Energy
Explosive distribution (burden, spacing, hole diameter, sub-drill, stemming length)
Bench Geometry
Rock Blastability

Kuzram

 EF  x50 = R f ×    100  0.5

−0.8

× Mc

1/ 6

 115  ×   RWS 

0.633

s φh    0.1 1 + 1 − × b    L − Sub   L − Sub     b   c × c   n =  2.2 − 14   ×  b  ×  100 × − 0.1    b    H b   Lc   φc    2        