Olivier Rousseaux - Australian Oilseeds Federation

Transcription

GRINDING EFFICIENCY IN THE
AQUAFEED INDUSTRY
Olivier Rousseaux
[email protected]
ASIA SALES DIRECTOR
ISF – Sydney - 2009
GRINDING EFFICIENCY IN
THE AQUAFEED INDUSTRY
CONTENT
INTRODUCTION
A] Parameters affecting grinding in the aquafeed industry
Raw Materials / Grinding design
B] Main Mechanical parameters we can change for better
result
C] Global solution
CONCLUSION
INTRODUCTION
IMPORTANCE OF THE GRINDING
GRINDING
SIZE REDUCTION
GRINDING
SIZE REDUCTION
GRINDING
SIZE REDUCTION
GRINDING
SIZE REDUCTION
• Surface area
• Smoothen the process
– Dies blockage
– Uniformity of the powder
• Quality of finished
product
– Gelatinization
– Digestibility
– Palatability
A] PARAMETERS AFFECTING FINE GRINDING
A1] RAW MATERIALS
Which raw materials:
Corn, Soya, cassava…
Wheat bran, rice bran…
Fish meal, feather meal…
Grinding design
Either pre-grinding or post
grinding system
Either 1 or 2 step(s) grinding
Using pulverizer or
hammermill
A2] RAW MATERIALS
a) Physical aspects
Initial size of the particles
initial size,
capacity
b) Biological aspects
a) Moisture content
Moisture content,
b) Fat content
fat content,
c) Hardness
hardness,
capacity
capacity
capacity
BASICALLY , RAW MATERIALS have to be used as what they are
A3] GRINDING SOLUTION / DESIGN
• 2 Steps grinding
– Coarse grinding using hammermill (screen 3mm)
– Fine grinding using pulverizer
• 1 Step grinding
– Using hammermill (screen 0,7mm)
– and special sifter (sieves 300µm to 600µm)
• In both cases, the particles size of the ground
product matches the requirement… but at which
cost
A4] FACTS : HAMMERMIL vs. PULVERIZER
Pulverizer :
Needs a lot of aspiration
High aspiration means high moisture losses
High power consumption
Hammermill :
Need aspiration
Reasonable power consumption
Reasonable Moisture losses
Cost :
Electrical cost: easy to evaluate
Wearing parts cost: easy to evaluate
Moisture losses: difficult to evaluate
A5] GRINDING COST : HAMMERMIL vs. PULVERIZER
No.
1
2
3
Parameter
HM Stolz
Pulverizer
10
Actual Cap (T/H)
4
Electric Consumption
- in kWH/Ton
24
28
- Electric Cost (US$/Ton)
1,4
1,7
Spare Parts
- Hammer / Beater (US$/Pcs)
2,6
50
Number of Hammers
152
72
Total Hammer Cost/mch
401
3 564
Hammer Lifetime (Tons)
5 000
3 600
Hammer Cost (US$/Tons)
(assump. 5000 T/month)
0,1
1,0
- Screener / Liner (US$/Pcs)
133
285
2
2
Number of Screen/liners
Total Screener / Liner Cost / mch
Screener/Liner Lifetime (Tons)
266
570
2 500
3 600
HUGE
SAVING
Screener Cost (US$/Tons)
(assump. 5000 T/month)
4
0,1
-
- Counterbeater & Liner: in H26/Tons
0,06
-
- Turbo sifter Screener: in US$/Tons
0,09
-
TOTAL COST (IN US$/TON)
1.75
2.70
DIFFERENCE
US$ 0.95
SAVING / MONTH (IN US$/MONTH)
US$ 4 750
A6] COMPROMISE
In terms of fineness Still with
pulverizer we could get very fine
particle … something which is not
required
Finer are the particles, higher is
cost
Compromise: Hammermill +
Pneumatic System + TurboSifter
B] EQUIPMENT DESIGN AFFECTING EFFICIENCY
B1] HAMMERMILL : ROTOR SPEED
Generally :
1500 rpm hammermills rotors are of about 1
400 mm diameter
3000 rpm hammermills rotors are of 650 to
700 mm diameter
Disadvantages of a 1500 rpm
hammer mill vs. a 3000 rpm :
The size
Screen changing more difficult
Needs more important screen surface
Disadvantages of a 3000 rpm
hammer mill vs. a 1500 rpm :
Noise
Fan makes more noise than
hammermills, what ever its size
Speed
3000
2900
2800
2700
2600
2500
2400
2300
2200
2100
2000
1900
1800
1700
1600
1500
1400
1300
1200
1100
1000
Screen
2,0 mm 2,5 mm 3,0 mm 3,5 mm 4,0 mm 5,0 mm 6,0 mm
570
593
612
626
637
647
641
559
591
620
645
665
695
709
549
592
630
665
696
745
779
542
594
643
688
728
798
851
537
599
658
712
763
852
926
534
607
675
740
800
909
1003
534
616
694
769
839
968
1082
535
628
716
800
881
1030
1163
539
642
740
834
925
1094
1247
546
658
766
870
971
1159
1332
554
676
794
909
1019
1228
1420
565
697
825
949
1069
1298
1511
578
720
858
992
1122
1371
1603
593
745
893
1037
1177
1445
1698
610
772
930
1084
1234
1522
1795
630
802
970
1134
1294
1602
1894
652
833
1011
1185
1355
1683
1995
676
867
1055
1239
1419
1767
2099
702
904
1102
1295
1485
1853
2205
730
942
1150
1354
1554
1941
2313
761
983
1201
1414
1624
2032
2424
Table giving medium size of particles in
function of Screen size and rotor speed.
ROTOR SPEED,
PARTICLES SIZE
B2] HAMMERMILL : SCREEN – DIMENSION AND SPECIFICATION
Useful Screen Size , capacity
Screen perforation, Particles size
Screen Opening (%) , capacity
Screen Thickness , Particles size
Screen worn-out, capacity
New screen
t
uc
od
Pr
D
o
reb
un
WORN: while rebounding, the grain is
taken again by the hammers
Worn screen
g
din
od
Pr
Opening% = D² * 0.907 / EA²
NEW: while rebounding, the grain is returned outside
Screen wearing effect
t
uc
EA
re
u
bo
in g
nd
B3] HAMMERMILL : BEATER
Beaters : Steel treatment and Wearing
How can you control
the best quality?
A: no steel heat treatment or bad treatment
B: correct steel heat treatment + C Addition
1: new beater
2: one side worn
3: both sides worn
•concave wearing
B: correct steel heat treatment :
•convex wearing
•Round shape wear
B: correct steel heat treatment :
•Spoon shape wear
B4] AIR FLOW
Air flow is made 2 main parameters:
• Air flow : m3/h, …
• Pressure: WC, bar
For Coarse Grinding (Screens 2 mm and more):
• Air Flow of about 8500 m3/h for 1 m²
• Air Pressure is of about 300 to 500 mm water column on the screen
For Fine Grinding (screen 1.5 mm and less):
• Air Flow of about 5500 m3/h for 1 m²
• Air Pressure of about 700 to 1000 mm water column on the screen
B5] AIR FLOW THROUGH HAMMERMILL & AIR JET FILTER
AIR SPEED :
Air speeds:
22-23 m/s through the destoner
4-6 m/s through the grid
2.5 to 3 m/s through the filtering media
AIR FLOW ACTIONS:
Generally little effect on the particle size
Enables product passing through the screen
Depending of the hammermill feeder design: Better heavy materials removal.
Will help reducing the T°increase of the ground product, avoiding down stream condensation
AIR FLOW REGULATION :
Allows a constant flow rate, whatever may be the pressure loss
From where, a better de stoning
Avoids any overload of the filtering media
Allows a progressive air flow increase, avoiding inopportunely emptying of the stone box
B6] GRINDING LINE DESIGN
a) Mechanical handling
b) Pneumatical handling
C] GRINDING EFFICIENCY IN THE AQUAFEED
C1] HAMMERMILL : FEEDER + GRINDER
The Feeder
Dimension same as the grinding room
Pneumatic Magnet
Heavy particle remover
Unique
Very advanced System
The Grinder
Liner
Screen
Beaters
Counters beaters
But also for safety reasons
Temperature control
Auto greasing
Screen sliding
C2] HAMMERMILL : FEEDER DESIGN
Raw materials
Air flap
Layer thickness
adjustable
Feeder with
variable speed
Air inlet
Magnet
Air
Heavy particles separator
- Stainless steel
Material to be ground
–Stone
–Sand
–Any high density particle
C3] HAMMERMILL : BEATER & COUNTER BEATER
Counters beaters
Counters beaters increase Flow rate and fineness
C4] HAMMERMILL : SCREEN REPLACEMENT
Step 1: Stop of feeder
Step 2: Unlocking
Step 3: Pushing out
Step 4: Change of screen
Step 5: Pulling in
Step 6: Locking
Step 7: Start of feeder
Time =
Maximum 3 MINUTES
SAVE POWER AND TIME
C5] TURBOSIFTER
Main features
Rotor specially designed
High speed
Clock rotation
Sieving drum rotates
Low speed
Clock rotation
Sequenced rotation
Compressed air @ 7bars
When sieving drum could rotates
Sequenced air pulsing
Cross contamination less
C6] GLOBAL SOLUTION
Grinding line for shrimps feeds or fish feeds

Olivier Rousseaux - Australian Oilseeds Federation

Transcription

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