112 September 200612 September 2006

Designing Dredging EquipmentOE4671/WB3408

Prof.ir. W.J.Vlasblm

Section Dredging engineering

September 12, 2006 2

Purpose of the lecture

• To design a particular type of dredger on basis of (simple) dredging processes.

• Such a method can be used for many design problems!

September 12, 2006 3

Course development

• Introduction lecture in the 5th quarter

• Assignment for one or two persons can be done the whole year around.

• Total 4 credits (ECT)

September 12, 2006 4

Assignments for hydraulic dredgers

• Trailing Suction Hopper Dredger (TSHD) for large reclamation works

• Multi Purpose TSHD for maintenance and beach nourishments

• Gravel Trailing Suction Hopper Dredgers• Cutter Suction Dredger• Environmental Dredger• Plain Suction Dredger• Dustpan Dredger

September 12, 2006 5

Assignments for mechanical dredgers

• The backhoe dredger• The grab dredger• Bucket ladder dredger

September 12, 2006 6

Trailing Suction Hopper Dredger

September 12, 2006 7

Cutter Dredger

September 12, 2006 8

Plain Suction Dredger

September 12, 2006 9

Plain Suction Dredger

September 12, 2006 10

Dustpan Dredger

September 12, 2006 11

The Environmental Dredger

September 12, 2006 12

The Backhoe Dredger

September 12, 2006 13

The Grab orClamshell Dredger

September 12, 2006 14

Bucket Ladder Dredger

September 12, 2006 15

Work Load

The assignment for• the TSHD, CSD are for 2 students• The other ones are for 1 student

September 12, 2006 16

Designing DredgingEquipment

Dredging installation

Propulsion (optional)

General layout

Productions

Prime movers (main engines)

September 12, 2006 17

Design productions

Working hours

Delays

Effficeincy

Yearly production

Excavating production

Soil type

Losses

Transport production

Losses

Deposing

Situ production

September 12, 2006 18

Design basis = yearly output in m3

(production)

• To be translated to the significant design parameters. • Depends on the scale (or cycle) of the process.• Large scales

• Hopper dredger ⇒ volume and load per trip• Barge unloader dredger ⇒ Barge volume• Backhoe dredger ⇒ the volume per cycle

• Continuous operating dredgers or equipment m3/week or m3/month

September 12, 2006 19

Design Basis (2)

• Small scale:• “Wall” speed of a breach mm/s• Pump output in m3/s• Cutter head Excavated output in

m3/s• Bucket ladder dredger Buckets/min• Backhoe dredger Bucket volume/cycle• Grab dredger Grab volume/cycle

September 12, 2006 20

Problems during translation

• Change of volumes • In many cases the contractor is paid in volumes

removed, but many processes are based on mass.• Working hours per week (168 or 84 or 40)• Down time• Overhaul & Maintenance • Bunkering, crew changes, etc• Delays due to weather conditions

September 12, 2006 21

Concentration (1/3)

• By volume

• By weight

• Delivered

sv

m

UVolume sandCMixture volume U

= =

s s sw v

m m m

USand massC CMixture mass U

ρ ρρ ρ

= = =

//

s svd

m m

U time QCU time Q

= =

September 12, 2006 22

Concentrations (2/3)

• Ratio between Cvd & Cv follows from:

• Ratio between Cw & Cv

s s v vd svd

m m v m

Q v AC C vCQ v A C v

= = ⇒ =

s w sw v

m v m

CC CC

ρ ρρ ρ

= ⇒ =

September 12, 2006 23

Concentrations (2/3)

•In horizontal transport vs < vm → slip•In vertical transport vs ≈ vm the difference is the settling velocity

vd s

v m

C vC v

=

September 12, 2006 24

Mixture Volumetric Densities Concentration

• Massmixture=massliquid+masssolids

(1 )

"Note U is volume"

sm m f f s s v

m

m f v s v

m fv

s f

UU U U with CU

C C

C

ρ ρ ρ

ρ ρ ρ

ρ ρρ ρ

= + =

= − +

−=

−

⇔

September 12, 2006 25

Volume changes

• When removing soil the insitu density will change; mostly from a dense to a loose state⇒Increase in porosity; f.I. From 40 to 50%⇒Porosity n is ratio pore volume over total volume⇒Condition: V1(1-n1)=V2(1-n2)

Examples:⇒Sand; n1=0.4 and n2=.5 gives V2/ V1=0.6/0.5=1.2⇒Rock; n1=0 and n2=.4 gives V2/ V1=1/0.6=1.7

September 12, 2006 26

Losses

Every dredging process can have losses, called spillage• More excavated than picked up by the flow or bucket• Non removed loads in TSHD’s, particular when the

loads is pumped ashore or rainbowed.• Unstable slopes after dredging (plain suction dredgers)• In accurate placing of material• Losses due to current and waves

September 12, 2006 27

Excavating production

Mechanically Hydraulically

September 12, 2006 28

Mechanical excavation Specific Energy Concept (SPE)

Energy required to excavated 1m3 of soilDimension is Joule/m3

or per unit of time J/s/m3/s=W/m3/s,

That equals a power over production

powerSPE power SPE productionproduction

= ⇒ = ×

September 12, 2006 29

Mechanical Excavating

September 12, 2006 30

Mechanical Excavating

September 12, 2006 31

Mechanical Excavating

September 12, 2006 32

Hydraulic excavationMomentum of flow

A reasonable assumption is that the jet- production is linear with the total momentum flux of the jet system independent of the trail speed.

M I Qu Q p P

psand w ww

wpower

pressure

= ⋅ = ⋅ = ⋅ =α αρ αρρ

α ρ2 2

( )( )

1

1sand dredged

sand sand sand dredged sand

Q n Q

M Q n Qρ ρ

= −

= = −

September 12, 2006 33

Excavation by dragheads is hydraulically

September 12, 2006 34

Water injection dredger

September 12, 2006 35

Transport production

Mechanicallyship/barge conveyor

Hydraulicallypipeline

September 12, 2006 36

Mechanical transport

• Trailing suction hopper dredger• Barges

• Be aware of the effective load, because the unloading is not always 100%

September 12, 2006 37

Transport by barges

September 12, 2006 38

By Trailing Suction Hopper Dredgers

September 12, 2006 39

Hydraulic transportPump-pipeline system

mixture

water

mixture

water

1

2

3

4

Flow [m3/s]

Pressure [kPa]

September 12, 2006 40

Hydraulic transport

September 12, 2006 41

Methods of deposing (1/2)

September 12, 2006 42

Methods of deposing (2/2)

September 12, 2006 43

disposing

September 12, 2006 44

Rainbowing

September 12, 2006 45

Mechanical Assistance

September 12, 2006 46

Design examples

September 12, 2006 47

TSHD

September 12, 2006 48

Example 1

Design a Trailing Suction Hopper Dredger that can dredge yearly 5 Mm3 coarse sand & gravel at 75 nautical miles from a port.

The dredger works 5 days at 24 hoursBunkers will be taken in the weekendOverhaul 2 weeksWeather delays 3 weeksWorkability 95%Christmas 1 week

September 12, 2006 49

Designing TSHD

Main dimensions

Dredging installation

Propulsion

General layout

September 12, 2006 50

Main dimensions

Working hours

Delays

Effficeincy

Yearly production

Hopper capacity and Payload

Soil type

Dead weight

Displacement

Main dimensions ship LxBxT

Bock coefficient

Overflow losses

September 12, 2006 51

Cycle time

First estimate of dredge cycle:Sailing to the dredging area: 75/15=3.0 hrLoading =1.5Sailing to the unloading area: =3.0Unloading =1.5Total =9.0 hr

September 12, 2006 52

Required load/trip

Available hours: (52-6)x5x24=5520Effective hours: 0.95x 5520=5244Number of trips per year: 5244/9= 582Required volume per trip: 5,000,000/582=8591 m3

In coarse sand & gravel max.filling hopper is 90%Required hopper volume: 8591/.9=9546 10000 m3

Density of sand & gravel in hopper 2000 kg/m3

PayLoad is: 8600x2=17200 tonHopper density: load/volume=1.72 t/m3.

⇒

September 12, 2006 53

Deadweight & lightweight

Crew and their possessions, consumer goods, spare parts, and ballast water and payload.

Deadweight=1.05 x payload Light weight as function of deadweight

y = -3E-06x2 + 0.5586xR2 = 0.9607

0

5,000

10,000

15,000

20,000

25,000

0 10,000 20,000 30,000 40,000 50,000 60,000 70,000

Deadweight [t[

Ligh

t wei

ght [

t]

September 12, 2006 54

Displacement

y = 0.6827xR2 = 0.9929

y = 0.3173xR2 = 0.9622

0

10,000

20,000

30,000

40,000

50,000

60,000

70,000

0 20,000 40,000 60,000 80,000 100,000

Displacement [t]

Wei

ght [

t]

G Light weightDead weight

September 12, 2006 55

Block coefficient

CLBTb =∇

T

BL

Cb =

September 12, 2006 56

Ship Numbers

Ships Numbers

012345678

1965 1970 1975 1980 1985 1990 1995 2000

Year of Construction

L/B

, B/H

, B/T

L/BB/HB/T

September 12, 2006 57

Dredging installation

Cvd

Required pump capacity

Overflow losses

Overflowlosses equal as assumed?

Yes

Main DimensionsNo

Pumps and pipelines

September 12, 2006 58

Pump capacities

• 10000 m3 in 90 min=1.85 m3/s including pores or 1.85x0.6=1.11 m3/s excluding pores

• Assume Cvd=0.2 → capacity Q=1.11/0.25=5.55 m3/s or per suction tube 2.8 m3/s

• Critical velocity for course sand is 5 m/s, so pipe diameter is 0.85 m → 0.85 m

• In coarse sand and gravel there are no overflow losses to account for.

September 12, 2006 59

Excavation process

September 12, 2006 60

Calculated the required jet pressure

•Sand mass follows from production

•Momentum follows from:With α=0.1

2 2 powerw jet w w

w pressure

PpI Q u Qp

α αρ αρ α ρρ

⋅ = ⋅ = ⋅ =

( )( )

1

1sand dredged

sand sand sand dredged sand

Q n Q

M Q n Qρ ρ

= −

= = −

sandM Iα= ⋅

September 12, 2006 61

Relation between Qmix, Qjet and Qerosion

0

0.1

0.2

0.3

0.4

0.5

0.6

0.7

0.8

0.9

1

0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1

Qjet / Qmixture

Cvd/(1-n)=0Cvd/(1-n)=0.2Cvd/(1-n)=0.4Cvd/(1-n)=0.6Cvd/(1-n)=0.8

September 12, 2006 62

Pumps and pipelines

Submerged pump required?

Yes

No

Depth of submerged pump

Determine headlossesand power(s)

Choose pump(s)

Determine jet capacityand pressure

September 12, 2006 63

k

hs

Hρwater

ρmixture

Non cohesive material

Submerged pump required?

( )ρ ρ ξ ρ ρ ξ ρwater mixture z mixture mixture mixturegH Vac gh v g H k v+ = + = − +12

12

2 2

September 12, 2006 64

Hydraulic transport

• From seabed into the hopper• From hopper to the shore

• Mostly empirical relations (Matousek)

• For gravel dredgers this is mostly be mechanically

September 12, 2006 65

Pump characteristics

September 12, 2006 66

Propulsion

For dredging & sailing

Bow trust power

Total Installed

Power balance

General layout

September 12, 2006 67

Propulsion power

y = 0.4641x - 510.11R2 = 0.8741

0

5000

10000

15000

20000

25000

0 10000 20000 30000 40000 50000

Displacement [t]

Pp [k

W]

September 12, 2006 68

Bow trust power

Bow trust power

y = 0.1758x - 19.495R2 = 0.8036

0500

1,0001,5002,0002,5003,0003,500

0 2,000 4,000 6,000 8,000 10,000 12,000 14,000 16,000

Propulsion power during trailing [kW]

Bow

trus

t pow

er [k

September 12, 2006 69

General Arrangement

September 12, 2006 70

General Arrangement of gravel dredger

September 12, 2006 71

Simple general arrangment

Lhopper = 62 mLship= 165 m

Bship= 33

Bhopper= 25 m

Tship= 13,2

Hhopper= 13

Hship= 14,7

G H ICA KFB ED MJ L N

See figureB7.1

September 12, 2006 72

The Cutter Suction Dredger

September 12, 2006 73

Example 2

Design a cutter dredger that can dredge dredge yearly 5 Mm3 rock with a unconfined compressive strength of 5 MPa. The tensile strength is 1 Mpa

The dredgers have to work 168 hrs a week.Yearly overhaul 4 weeksChristmas leave 1 weekGeneral delays 10%Dredging delays 20SPE~qu

September 12, 2006 74

Required cut production

Available hours (52-5)x168=7896Non dredging hours:0.3x7896=2369Dredging hours 7896-2369=5527Estimated spillage 25%Required hourly output: 1.25x5000000/5527=±1130 m3.Qdredged=1130/3600=0.314 m3/sTime losses due to stepping, spud changes 15%Qcut=0.31/0.85=0.37 m3/sSPE=5MJ/m3. Required mean cutter power 0.37x5=1.85 MW

September 12, 2006 75

Cutter head productions c.q. Spillage

•The rotational speed of the cutter head causes spillage.

•The productivity c.q. spillage depends on the ratio:

•For sand the productivity is:

•For rock the productivity is much lower

32.5 pumpr

cutter

QP

Rω≈

September 12, 2006 76

Cutter head productions c.q. Spillage

RELATIVE PRODUCTION

01020304050607080

0.00 0.10 0.20 0.30 0.40 0.50 0.60 0.70 0.80

Flow number [-]

Pr [%

]

Gravel 10 mm Gravel 15 mm Ladder 25 deg. Sand

September 12, 2006 77

Cutter head production processin rock or gravel

September 12, 2006 78

Cutter head dimensions for rock with 25 % spillage

0

20

40

60

80

100

120

0.0 0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0Cutter diameter [m]

Cut

ter

head

spe

ed [r

pm]

0

2

4

6

8

10

12

Pum

p ca

paci

ty [m

3/s]

Vm=2.67 m/s Vm=3.5 m/s Vm=5 m/s

Capacities

cutter head speeds

September 12, 2006 79

Pump capacity and concentrations

Qdredged=0.314 m3/sQmixture=3.5 m3/s

( )1dredgedsandvd

mixture mixture

Q nQCQ Q

−= =

September 12, 2006 80

Pumping distances and installed pump power

• Knowledge of hydraulic losses can be found in the lecture notes of Matousek c.q. Talmon

• Knowledge of dredge pump can be found on our website and is downloadable.

September 12, 2006 81

Lightweight of pontoon

y = 0.3485xR2 = 0.925

0

2,000

4,000

6,000

8,000

10,000

0 5,000 10,000 15,000 20,000 25,000

Total installed power [kW]

Lig

ht w

eigh

t [t]

September 12, 2006 82

Pontoon dimensions (1/2)

0.00

2.00

4.00

6.00

8.00

10.00

12.00

0 1000 2000 3000 4000 5000 6000 7000 8000 9000

Light weight [t]

L/B

& B

/T

L/B B/T

September 12, 2006 83

Pontoon dimensions (2/2)

y = 0.4664xR2 = 0.9597

01,000

2,0003,000

4,0005,000

6,0007,000

8,0009,000

10,000

0 5,000 10,000 15,000 20,000 25,000

BLD [m3]

Lig

ht w

eigh

t [t]

September 12, 2006 84

Simple Plan

September 12, 2006 85

Backhoe dredger

September 12, 2006 86

Example 3

• A backhoe dredger have to dredge 500 m3/in fine sand with a SPE of .7MJ/m3.

• Calculated the Bucket size and cylinder forces

September 12, 2006 87

Fill Degree & Bulk factor

Soil type Filling degree Bulking factor Soft clay 1.5 1.1 Hard clay 1.1 1.3 Sand & Gravel 1 1.05 Rock; well blasted 0.7 1.5 Rock, unblasted 0.5 1.7

September 12, 2006 88

Dredge Cycle

• Cycle times of the bucket depends on the dredging depth and soil type, but are in the order between 20 and 40 seconds.

• The cycle consists of:• • Digging• • Lifting and swinging• • Dumping• • Swinging and lowering• • Positioning.

September 12, 2006 89

Crane weight versus bucket size for soft soil

y = -7E-06x2 + 0.0494x + 1.5486R2 = 0.9778

0

5

10

15

20

25

30

0 100 200 300 400 500 600

Crane weight [ton]

Buc

ket s

ize

[m3]

bucket2

September 12, 2006 90

Required power

Liebherr Excavators

y = 4.4679xR2 = 0.9936

0

500

1000

1500

2000

2500

0 100 200 300 400 500 600

Crane weight [tons]

Pow

er [k

W]

September 12, 2006 91

Relation for existing dredgers

0.00

200.00

400.00

600.00

800.00

1000.00

1200.00

0.00 5.00 10.00 15.00 20.00

Bucket size [m3]

Inst

alle

d po

wer

[kW

]

Rock buckets

September 12, 2006 92

Light weight pontoon

0

200

400

600

800

1000

1200

1400

1600

1800

0 250 500 750 1,000 1,250

Total installed power [kW]

Lig

ht w

eigh

t [t]

September 12, 2006 93

Pontoon volume

y = 0.4713xR2 = 0.6122

0200

400600

8001000

12001400

16001800

0 500 1000 1500 2000 2500 3000

LBD [m3]

Lig

ht w

eigh

t [t]

September 12, 2006 94

Ships numbers for BHD

0.001.002.003.004.005.006.007.008.009.00

0 200 400 600 800 1,000 1,200 1,400 1,600 1,800

Light weight [t]

L/B

& B

/t

L/B B/T

September 12, 2006 95

Simple Plan

September 12, 2006 96

Newer ideas can be discussed

September 12, 2006 97

The shallow draught TSHD