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WASTE CONTAINMENT TECHNOLOGY

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Title: WASTE CONTAINMENT TECHNOLOGY


1
WASTE CONTAINMENT TECHNOLOGY
  • Dr. Grace Hsuan
  • Civil Architectural Engineering

2
Outlines
  • Waste management methods
  • Landfill design and regulations
  • Function and usage of geosynthetics in landfill
    systems
  • Durability of geosynthetics
  • Future trend of landfill management

3
Waste Classification
  • Municipal waste
  • Construction demolition debris
  • Nonhazardous industrial waste
  • Incineration ash
  • Hazardous waste

4
Amount of Municipal Waste
5
Waste Management Methods
Method 1970 1980 1990 1992 (Goal)
Landfilling 72 81 67 55
Combustion 21 9 16 20
Recycling 7 10 17 25
 
6
Source Reduction
  • Source reduction involves reduction in the
  • quantity or toxicity of materials during the
  • manufacturing process via
  • Decrease the amount of unqualified products by
    improving quality control
  • Decrease the unit weight of the product by using
    high quality material.

7
Weight Reduction (unit of grams)
Container 1980 1992
2-liter PET bottle 65 51
Aluminum can 19 15
Glass soda bottle 255 177
Steel (tin) soup can 48 37
Half-pint milk carton 14 11
8
Recycling Materials in Percentage of Waste
Materials 1985 1990 Projected 1992
Corrugated boxes 4.4 5.9 6.7
Newspapers 2.1 2.8 3.3
Office paper 0.7 0.9 1.0
Glass containers 0.7 1.3 1.5
Steel cans 0.1 0.2 0.2
Aluminum cans 0.4 0.5 0.5
Plastics packaging 0.1 0.2 0.2
Yard waste 0 2.2 2.7
Others 1.5 3.0 3.8
Total 10 17.1 20.2
9
Combustion
  • Combustion can reduce the volume of the solid
    waste up to 90 at the same generate power.
  • There are 140 combustion plants the US.
  • Emission must meet the EPA Clean Air Act.
  • Residual ash is hazardous material and should be
    disposed accordingly.

10
Landfill
  • Landfill implies disposal of waste in the ground.
  • 70 of the waste is disposed in landfill and the
    percentage has been gradually decreasing.
  • The amount of waste actually increased due to
    population growth.

11
Landfilling
  • Approximately 6,500 landfills operate in the US
  • 57 belong to local governments
  • 14 belong to private companies,
  • 29 belong to federal agencies or solid waste
    authorities.

12
Landfill Capacity
  • The size and capacity vary greatly
  • 30 of the landfills receive less
  • than 30 tons per day
  • 5 receive more than 500 tons

13
The Largest Landfill
  • Fresh Kills,
  • Staten Island, NY
  • 3,000 acres
  • 2.4 billion cubic feet of waste
  • 25 times of the great pyramid

14
Nature of Waste Problem
  • Moisture within and flowing on the waste
    generates leachate
  • Leachate takes the characteristics of the waste
  • Thus leachate is very variable and is
    site-specific - there is no "typical" leachate
  • Flows gravitationally downward into the leachate
    collection system
  • Enters groundwater unless a suitable barrier
    layer or system is provided

15
Current Legislation
  • EPA for both non-hazardous and hazardous waste
  • Superfund via Corps of Engineers
  • DOE/NRC for radioactive wastes
  • Worldwide approx. 40 countries have
    legislation/regulations (survey in GRI Report 23)

16
Regulations
  • Solid waste is regulated under the Resource
    Conservation and Recovery Act (RCRA).
  • Classification of non-hazardous and hazardous
    waste depends on the chemical constituents of the
    leachate.

17
Hazardous Waste Definition
  • Waste is listed in Appendix VIII of Title 40,
    Code of Federal Regulations, Part 251.
  • Waste is mixed with or derived from hazardous
    waste.
  • Waste is not identified as municipal waste.
  • Waste possesses one of the following
    characteristics
  • ignitable corrosive reactive and toxic.

18
Minimum Technology Guidance(MTG)
  • Federal regulation on landfill design requirement
    is published by the EPA.
  • Dependent on the classification of the waste, MTG
    is recommended.
  • Each state must follows, or exceed, the MTG.

19
Non-hazardous Waste
  • Non-hazardous waste is regulated under Subtitle D
    of RCRA.
  • EPA regulations are published in Parts 257 and
    258, Title 40, Code of Federal Regulations (CFR).

20
Minimum Technology Guidance (MTG) for a Subtitle
D Landfill
21
Hazardous Waste
  • Hazardous waste is regulated under Subtitle C of
    RCRA.
  • EPA regulations are published in Part 264.221,
    Title 40, Code of Federal Regulations (CFR).

22
MTG for a Subtitle C Landfill
23
Landfill Closure Activities
  • Closure must begin within 30 days of final
    receipt of waste extensions may be granted by
    state approval.
  • Closure must be completed in accordance with
    closure plan within 180 days extensions may be
    granted by state approval.
  • A notation must be placed in the deed.

24
Landfill Covers(Non-hazardous landfill without
Geosynthetic on the bottom liner system)
Erosion Layer
150 mm
Infiltration Layer
450 mm
25
Cover Layers
  • Erosion Layer
  • Earthen material is capable of sustaining native
    plant growth
  • Infiltration Layer
  • Permeability of this layer of soil should be less
    than or equal to the permeability of any bottom
    liner system or natural subsoils present, or
    permeability less than 1x10-5 cm/sec whichever is
    less

26
Landfill Cover System(Subtitle C D, and Corp
of Eng.)
150 mm
Topsoil
Varies (frost depth)
Cover Soil
150 mm
Filter (or GT)
300 mm
Drain (or GN)
GM
600 to 900 mm
Clay _at_ 1x10-7 cm/sec
300 mm
Gas Vent (or GT)
Solid Waste
27
Landfill Site
  • Conforms with land use planning of the area
  • Easy access to vehicles during the operation of
    the landfill
  • Adequate quantity of earth cover material that is
    easily handled and compacted
  • Landfill operation will not detrimentally impact
    surrounding environment
  • Large enough to hold community waste for some time

28
Geosynthetics
  • geomembranes (GM)
  • geosynthetic clay liners (GCL)
  • geonets (GN)
  • geotextiles (GT)
  • geogrids (GG)
  • geopipe (GP)
  • geocomposites (GC)

29
Primary Functions
Type S R F D B
GM - - - - Y
GCL - - - - Y
GN - - - Y -
GT Y Y Y Y -
GG - Y - - -
GP - - - Y -
GC Y Y Y Y Y
S separation, R reinforcement, F
filtration D drainage, B barrier
30
Natural Soils vs. GSs
Function Natural Soil Geosynthetics
Barrier-Single CCL GM
Barrier- Composite GM/CCL GM/GCL GM/GCL/CCL
Drainage Layer Sand Gravel or sand GT GN
Filter Layer Sand GT
31
Liner System
GT
GN
GCL
Gravel w/ perforated pipe
GM
GG
CCL
32
Final Cover System
GG
Geosynthetic ECM
Cover Soil
GC or GN
GT
GM
GCL
GP or GC
33
Solid Waste
34
Possible Geosynthetic Layersin a Waste
Containment System
  • in Final Cover - 7
  • in Base Liner - 9
  • 16 Layers!

35
Liquid Barrier Systems
  • Single CCL
  • Single GM
  • Single composite liner
  • GM/CCL
  • Double composite liner
  • GM/CCL-GM/CCL
  • GM/GCL-GM/CCL

36
Composite Barriers(Intimate Contact Issue)
37
Composite Barriers(Theoretical Leakage)
GM alone (hole area a)
Composite liner (GM/CCL)
Leachate
ks

Q 0.21 a0.1 h0.9 ks0.74 (for good contact)
Q
C
a
gh
2
B
Q 1.15 a0.1 h0.9 ks0.74 (for poor contact)
Ref. Bonaparte, Giroud Gross, GS 89)
38
Generalized Leakage Rates Through Liners(ref.
Giroud and Bonaparte, Jour. G G, 1989)
assumes 3 holes/ha (i.e., 1.0 hole/acre)
39
Response Action Plans (RAP's)
  • Only applicable with double liner systems
  • Worldwide, 58 HSW (incl. USA) and 14 of MSW
    require double liner systems
  • Requires measurement of liquid quantity in leak
    detection system
  • If above the preset action leakage rate (ALR),
    different requirements are set in motion, e.g.,
  • continuous monitoring
  • characterize liquid
  • stop receiving waste
  • remove waste to locate leak(s)

40
Some Comments on RAP's
  • (a) "de minimum" leakage 10 lphd ( 1.0 gpad)
  • vapor diffusion through perfect geomembrane with
    no flaws 0.2 to 20 lphd
  • (b) typ. action leakage rate (ALR) 50 to 200
  • continuous monitoring
  • assess liquid characteristics
  • compare to primary leachate
  • (c) typ. intermediate leakage rate (ILR) 200 to
    1000
  • stop adding waste
  • continue monitoring and testing
  • (d) typ. rapid and large leak (RLL) gt 1000 lphd
  • remove waste
  • repair leak(s)

Note all of the above RAP values are for
illustration only -- they must be site
specifically determined -- note that EPA only
requires the establishment of an ALR value
41
Average Values of Leakage Quantities
Sand Leak Detection
GM
Leakage Rate (lphd)
GM/CCL
GM/GCL
3
2
1
Life Cycle Stage
42
Average Values of Leakage Quantities (contd)
Geonet Leak Detection
GM/CCL
Leakage Rate (lphad)
GM
GM/GCL
3
2
1
Life Cycle Stage
43
Geomembranes
Widely Used Geomembranes Limited Used Geomembranes
High density polyethylene (HDPE) Chlorosulfonated polyethylene (CSPE)
Linear low density polyethylene (LLDPE) Ethylene interpolymer alloy (EIA)
Flexible polypropylene (f-PP) Ethylene propylene trimonomer (EPDM)
Polyvinyl chloride-plasticized (PVC-p)
44
Comments
  • Name is associated with resin type
  • All have some amount of additives
  • Additives can vary from 2 to 60
  • Some additives are critical to performance

45
Compositions(approximate percentage)
Type Resin Carbon Black Plasticizer Anti-oxidant Filler
HDPE 95-97 2-3 0 1-0.5 0
LLDPE 95-97 2-3 0 1-0.5 0
PVC-p 50-70 1-2 25-35 1-0.5 5-10
fPP 95-97 2-3 0 1-0.5 0
CSPE 40-60 5-40 0 1-0.5 5-15
EPDM 25-30 20-40 0 1-0.5 20-40
46
Geomembrane Styles
  • smooth geomembranes
  • Textured geomembranes
  • Reinforced geomembranes

47
Manufacturing Processes
  • Flat extrusion
  • Blown sheet extrusion
  • Blown sheet co-extrusion
  • Calendaring

48
Material Properties
  • Mechanical property
  • Density
  • Melt flow
  • Carbon black
  • Plasticizers
  • Antioxidant

49
Tensile Behavior
  • Test method varies according to the resin type
    and style of the geomembrane.
  • Each test method consists of unique shape of
    specimen and strain rate.
  • Methods
  • HDPE, LLDPE and fPP ASTM D 638 Type IV
  • PVC-p ASTM D 882
  • All reinforced geomembranes ASTM D 751

50
Design Concept

(Test)

(Test)
Allowable
Property
Allowable
Property


FS
FS
Required
(Design)

Property
Required
(Design)

Property
  • Where
  • Test methods are from ASTM, ISO, or others
  • Design models from the literatures
  • Factor-of-Safety is site specific

51
Density Methods
  • ASTM D 752 (Specific gravity)
  • ASTM D 1505 (Density column)
  • ASTM D 4883 (Ultrasonic for PE only)

52
HDPE Geomembranes
  • Resin density is around 0.930 g/cc, which is in
    the medium density range according to ASTM D 833.
  • The 2.5 carbon black raise the density of the
    product to 0.941g/cc, which is the HDPE range.
  • ?product ?resin 0.0044C
  • Where C weight percentage of carbon
    black

53
Melt Flow (MI) Method
  • Test Method - ASTM D 1238
  • Only for thermoplastic materials
  • Test condition varies with resin type
  • It is essential for extrusion process, i.e., for
    product manufacturers
  • For the same type of polymer, MI can be
    correlated to the molecular weight

54
Function of Carbon Black
  • The primary function is as an ultraviolet light
    stabilizer to protect polymer being degraded.
  • Carbon black absorption coefficient increases
    with loading up to 3.
  • In elastomeric materials, carbon black also
    functions as an reinforcement, and loading can be
    as high as 30-40.

55
Addition of Carbon Black
  • The masterbatch technique is utilize to
    dispersing carbon black in plastic.
  • A masterbatch is a resin containing a high
    concentration of carbon black.
  • The masterbatch is blended with polymer resin to
    achieve the desire percentage.

56
Carbon Black
  • Carbon black content is measured according to
    ASTM D1603.
  • Carbon black dispersion is evaluated according to
    ASTM D 5596.

57
Plasticizers
  • Plasticizers is used in PVC to lower the glass
    transition temperature (Tg).
  • An addition of 30 plasticizer in PVC can lower
    the Tg from 80oC to 20oC.
  • The plasticized PVC behaves rubbery at normal
    ambient temperature.
  • However, plasticizer can slowly leach out with
    time.

58
Analysis Plasticizers
  • The amount of plasticizer in the polymer can be
    determine by extraction according to ASTM D 2124.
  • The type of plasticizer can be identified using
    Infrared (IR) spectroscopic.

59
Antioxidants
  • The function of antioxidants is to protect
    polymers from being oxidized during the extrusion
    process and service lifetime.
  • For polyolefines, antioxidants is vital to the
    longevity of the product.
  • Antioxidant will be the focus of the second part
    of this class.

60
Degradation of HDPE Geomembranes
  • Chemical Related
  • Thermal-oxidation
  • Photo-oxidation

61
Linear PE Structure
  • Linear PE is a graft copolymer
  • Each co-monomer creates one branch
  • Co-monomer can be butene, hexene, or octene

62
Density of Geomembranes
  • Density decreases as the amount of co-monomer
    increases
  • Density range of PE (ASTM D883)
  • gt 0.940 g/ml for HDPE
  • 0.926 - 0.940 g/ml for MDPE
  • 0.910 - 0.925 g/ml for LLDPE
  • lt0.909 g/ml for VLDPE or ULDPE

63
II. Oxidation Degradation
  • Polyolefins, such as HDPE, PP and PB are
    susceptible to oxidation.
  • Oxidation takes place via free radical reactions.
  • Free radicals form at the tertiary carbon atoms
    (i.e., at branches).
  • Oxidation leads to chain scission that results in
    decrease of Mw and subsequently on mechanical
    properties.

64
Forming Free Radicals
65
Different Degradation Stages
66
Various Stages of Oxidation
67
Reactions during Induction Period
68
Reactions during Acceleration Period
69
Functions of Antioxidants
  • Primary antioxidants react with free radical
    species
  • Secondary antioxidants decompose ROOH to prevent
    formation of free radicals

70
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71
Types of Antioxidants
Category Chemical Type Example
Primary Hindered phenol Irganox? 1076 or 1010 Santowhite crystals
Primary Hindered amines Various of Tinuvin?, Chemassorb? 944
Secondary Phosphites Irgafos? 168
Secondary Sulfur compound Dilauryl thiodipropionate Distearyl thiodipropionate
Secondary Hindered amines Various of Tinuvin?, Chemassorb? 944
72
Effective Temperature Range
Phosphites
Hindered Phenols
Thiosynergists
Hindered Amines
50
200
0
100
150
250
300
Temperature (oC)
73
Depletion of Antioxidants
  • Two mechanisms
  • Chemical reactions by reacting with free
    radicals and peroxides
  • Physical loss by extraction or volatilization

74
Arrhenius Model
  • Rate of reaction X Y Z
  • Where
  • X collision frequency (concentration or
    pressure)
  • Y energy factor
  • Z probability factor of colliding particles
    (temperature dependent)

75
Potential Energy
transition state
E
act
Potential Energy
Separate
Reactants
products of
reaction
D
H
Progress of Reaction
76
Distribution of Energy
-E
dN
act
Fraction is
exp( )
dE
RT
Energy
77
Arrhenius Equation
(9)
(10)
(11)
78
Arrhenius Plot
A
E
act
R
ln R
r
1
high temperature
low temperature
(lab tests)
(site temperature)
Inverse Temperature (1/T)
79
Experimental Design
  • Incubation environment should simulate the field
    (i.e., landfill environment)
  • Limited Oxygen
  • Some degree of liquid extraction
  • Utilize elevated temperatures to accelerate the
    reactions.
  • 55, 65, 75, and 85oC

80
Incubation Device
81
Tests Performed
  • Oxidative inductive time (OIT) for antioxidant
    content.
  • Melt index for qualitative molecular weight
    measurement.
  • Tensile test for mechanical property

82
OIT Tests
  • OIT is the time required for the polymer to be
    oxidized under a specific test condition.
  • OIT value indicates the total amount (not the
    type) of the antioxidant remaining in the polymer.

83
OIT Test for Evaluation of Antioxidant (AO)
  • OIT Tests
  • ASTM D3895-Standard OIT (Std-OIT), or
  • ASTM D 5885-High Pressure OIT (HP-OIT)
  • HP-OIT test is used for AOs which are sensitive
    to high temperature testing

84
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85
Thermal Curve of OIT Test
86
Test Results
Percent Retained
Incubation Time (month)
Changes in Eight Properties with Incubation Time
at 85C
87
Analysis of OIT Data
  1. Determine OIT depletion rate at each temperature.
  2. Utilize Arrhenius Equation to extrapolate the
    depletion rate to a lower temperature.
  3. Predict the time to consume all antioxidant in
    the polymer.

88
a) - OIT Depletion Rate
89
b) Arrhenius Plot
y 17.045 - 6798.2x R2 0.953
y 16.856 - 6991.3x R2 0.943
ln (OIT Depletion Rate)
1/T (K)
90
c) Lifetime of Antioxidant
  • Use the OIT depletion equation to find t
  • ln(OIT) ln(P) (S) (t)
  • The OIT value for unstabilized PE is 0.5 min.
  • For this particular stabilization package
  • t 200 years

91
Lifetime of Geomembrane
  • Induction time and degradation period (Stages B
    C) can be established by using unstabilized
    polymer in the experiment.
  • It was found by Gedde et al. (1994) that the
    duration of Stages B and C is significant shorter
    than that of Stage A.
  • Antioxidants are critical to the long-term
    performance of polyethylene and other
    polyolefines.

92
Future of Waste Containment
  • Current waste containment technique is defined as
    dry dome method by eliminating leachate from
    being generated after closure.
  • Waste will not degrade since moisture is a
    critical component of the biodegradation process.

93
Bioreactor Landfill
  • a sanitary landfill operated for the purpose
    of transforming and stabilizing the readily and
    moderately decomposable organic waste
    constituents within five to ten years following
    closure by purposeful control to enhance
    microbiological processes. The bioreactor
    landfill significantly increases the extent of
    waste decomposition, conversion rates and process
    effectiveness over what would otherwise occur
    within the landfill.

94
Why Operate a Landfill as a Bioreactor?
  • to increase potential for waste to energy
    conversion,
  • to store and/or treat leachate,
  • to recover air space, and
  • to ensure sustainability

95
Status
  • 1993 - less than 20 landfills recirculating
    leachate
  • 1997 - 130 landfills recirculating leachate
  • My estimate - 5 of landfills

96
Aerobic Bioreactor
  • Rapid stabilization of waste
  • Enhanced settlement
  • Evaporation of moisture
  • Degradation of organics which are recalcitrant
    under anaerobic conditions
  • Reduction of methane emissions

97
Research Issues - Aerobic Bioreactor
  • How much air is needed?
  • How can air be delivered?
  • What is the impact on the water balance?
  • How are landfill fires prevented?
  • What are the economic implications?
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