Soil and Waste Treatment - Waste Treatment PDF

Summary

These lecture notes cover soil and waste treatment, focusing on waste treatment, management, and disposal methods. The document includes topics like waste minimization and recovery, and how different types of waste are handled in different approaches.

Full Transcript

Jordi Garrigó Reixach

Subject:

Soil and waste treatment
Section:

Waste treatment

FIRST SEMESTER
THIRD YEAR

ENVIROMENTAL SCIENCE DEGREE

SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
GENERAL TOPICS

UNIT 1:

Sources and types of waste.

Problem of waste.
2.1. Introduction

UNIT 2: 2.2. Waste management

Waste minimization.
2.3. Waste treatment. Thermal conversion
Treatment of waste.

UNIT 3: 2.4. Waste landfill

Recovery of waste.
Plans and waste management.

SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
2.1. Introduction
Unfortunately, even today, wastes are deposited without any treatment in many
parts of the world.

This has dangerous consequences for the environment …
Groundwater pollution
Air pollution
Biodiversity loss
… and should be avoided.
Sanitary risk
Evolution of landfills
numbers in U.E.S.

SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
2.1. Introduction

TREAT THE WASTE! Energy Loss (Radiation)

Final phase of
Fuel
treatment

Waste sub
products (recycled
and recovered) Mass Loss
(unburned C in ash
and other waste)

SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
 2.2. Waste management
20 – 30 Gallon containers
Solid waste generation Paper and plastic bags
Bulk bins
Other
Storage (US gallon = 3.785 L)
Home separation for recycling
Point service
Level of service
Citizens deliver
Collected by Frequency of collection
to recycling Transport
truck
center
Direct transport
Reuse
Piggyback collection Recycled Transfer station
separate vehicle
Recovered

Shred/hale Shred/pulp

Energy recovery/ Material recovery
thermal reduction

Residue
Incineration
Pyrolysis Reuse as fuel

Residue

Land disposal
SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
 2.2. Waste management

Collection

Pick-up
Landfill

Treatment /
Valorization
Separation technologies
Break bag Incineration
Size separation
Size reduction Thermal conversion Gasification
Density separation
Magnetic separation Pyrolysis
Compression
Biological conversion Composting

Bio methanation
Conversion technologies
Ex.: landfill liner system Acid hydrolysis /
alkaline hydrolysis
Chemical conversion
Methanol conversion

SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
2.2. Waste management. Collection

Collection
Based on decisions made by elected representatives. The generated wasted can
be collected by:
-city employers
-private firms that contrat with city goverment (contract collection)
-private firms that contrat with private residents (private collection)

MAIN POINT TO COLLECTION:
separation of waste in the source is required!

Colours can be different depends on the waste management legislation!
SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
 2.2. Waste management. Collection

Paper and cardboard

Plastics and containers

Glass

Organic

Remain fraction

SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
 2.2. Waste management. Collection
Bulky

Electrical & electronic Equip. (WEEE)

Textile

Batteries Specialised
companies

Medicines and Drugs

Used oil

End-of-life tire (sp.NFU)

SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
 2.2. Waste management. Collection

“Yellow Container”
YES (SÍ) NO
Metallic cans Organic matter
Drink cans (soda, refresh, beer,…) Glass packaging
Cans of preserves (vegetables, meat, fish, pet food, …) Paper and carboard

Aerosols (deodorant, lacquer, kitchen cleaners, wood polishes,...) Toys
Aluminum trays and plates Appliances
Metallic can and caps Biberons
Tetra Brik Rubber gloves
Brik of milk, cream, smoothies, juices, wine, … Kitchen utensils
Plastic food packaging Fruit boxes

Bottles (water, soft drink, milk, juice, oil, liqueurs, sauces,...) Plastic buckets

Dairy product packaging (yogurts, flan and other milk desserts, cheese, butter,
margarine,...) Batteries

Trays and boxes made of "white cork", expanded polystyrene or EPS
Plastic egg cups, disposable plastic caps,
SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
 2.2. Waste management. Collection

Glass container (hemispherical) green.
YES (GLASS) NO (“CRYSTAL”)
Glass bottles of any color Vehicle glasses
Glass jars (conserves, semiconserved honey, …) Lamps

Cosmetic jar and perfume bottle Mirrors

Window glasses

Fluorescent tubes

These "crystals" must be deposited in the "Clean Points" or in "Collection and Recycling
Centers"

SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
2.2. Waste management. Collection

Paper and cardboard in container blue

YES NO

Newspapers and magazines

Information, advertising, … leaflets Bricks

Small cardboard boxes (biscuits, detergent, shoes,...) Diapers

Egg cartons Dirty papers

Paper bags Wax papers

Cardboard boxes (chopped)? Metalized paper

Plasticized paper

SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
 2.2. Waste management. Collection Organic matter
WASTE IS PROHIBITED
YES NO OUTSIDE THE
CONTAINER
Fruit and vegetable scraps Animal excrement (In the waste
container)
Cooked foods, dairy products, meat Glass, metals and plastics (in the
and fish scraps. Container for yellow container)
organic matter Diapers and sanitary napkins (in
Natural sawdust, dirty kitchen paper the waste container)
and wood ashes. Tobacco filters and sawdust
made of treated wood (in the
Coffee and infusion grounds and waste container)
filters Clay, ceramic (in the waste
Leaves, flowers and plants, green or container)
dried Aluminum paper (in the waste
Remains of orchard, lawn, and container)
Garden
chopped pruning Medicines, medicine containers
composter
Rice, boiled pasta, leftover nuts, and x-rays (at the pharmacy or
chopped bread, eggshells and shells recycling center)
SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
 2.2. Waste management. Collection

Collection methods

- door to door collection

-waste containers curbside pickup

-backyard pickup

Door-to-door waste collection was the most used in the past and is still used in areas
with high population density or with reduced sidewalk space.
It generates problems with schedules, noise, dirt,...
The system of street collection in waste containers being imposed.

To take into account… DENSITY!
SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
2.2. Waste management. Collection

Collection methods Allows the selective
collection of waste
- waste containers curbside pickup
Attention! Less populated
- door to door collection areas → by requiring
residents to transport waste
-backyard pickup to a specific point.

To take into account… DENSITY!
SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
2.2. Waste management. Collection

WASTE COLLECTION SYSTEM DESIGN CALCULATION:
Estimating Truck Capacity

ratio of the density after compaction to that before compaction

SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
2.2. Waste management. Collection

WASTE COLLECTION SYSTEM DESIGN CALCULATION:
Estimating Truck Capacity

stop

SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
 2.2. Waste management. Separation in the plant

https://www.youtube.com/
watch?v=c2Tr-U0nALM

https://www.youtube.com
/watch?v=20Ihfe6X_UM

Organic matter

SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
2.2. Waste management. Separation in the plant
Eddy current (Corrientes de Foucault)
Eddy current separation (ECS) is a
physical technology of separating
nonferrous metallic particles from other
particles. In ECS, alternating eddy
current was induced in nonferrous
metallic particles when meeting variable
magnetic field generated by the rotation
of magnetic drum of eddy current
separator. The alternating eddy current
caused a new magnetic field in
nonferrous metallic particles. The
magnetic field of eddy current separator
and the new magnetic field had the
same magnetic field direction. Thus,
repulsive force between the two
magnetic fields was generated and
changed the movement of nonferrous
metallic particles and separated them
from other particles.
SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
 2.2. Waste management. Treatment fractions

RAEE Resíduos de Aparatos Eléctricos y Electrónicos
WEEE Waste Electrical and Electronic Equipments
SOURCE: State Framework Waste Management Plan (PEMAR 2016-2022)

SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
 2.3. Waste treatment. Thermal conversion
Heavy metals
THERMAL CONVERSION Lead
Inorganic mercury
Acid gases
Pollutant generated Methyl mercury
Sulfur dioxide
in those process Cadmium
Nitrogen oxides
Chromium
Arsenic
Organics …
Dioxin and furans
PCBs (polychlorinated biphenyls)
INCINERATION
GASIFICATION
PYROLYSIS According to the needs of O2 and temperature
THERMICAL
CONVERSION O2 PRODUCTS

INCINERATION EXCEED HOT GASES (N2, CO2, H2O) O2 SOLIDS (ASH) 900-1200ºC
HOT INFLAMABLE GASES (N2, CH4,
GASIFICATION DEFICIT CO2). SYNGAS. HEATING VALUE 5500 COKE (C, INERT) LIQUID 750-850ºC
kJ/m3
PYROLITIC OIL
HOT INFLAMABLE GASES (N2, CO, H2, COKE (C, INERT)
PYROLYSIS ABSENCE GASEOUS HIDROCARBONS).
(ACETIC ACID, 300-750ºC
ACETONE,
HEATING VALUE 26000kJ/m3
METHANOL)

SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
2.3. Waste treatment. Thermal conversion

THERMAL CONVERSION

INCINERATION
Prior to 1940, incineration was common in North America and western Europe.
Many incinerators were eliminated because of foul odors and dirty smoke

environmental conflict!
Pros:
– Reduce volume 90%, weight 75%
– Heat from burning converted to electricity
Cons:
– Can create air pollution
– Concentrates toxins in ash
– More costly than landfills

SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
2.3. Waste treatment. Thermal conversion

THERMAL CONVERSION

MSW is not a very good fuel!

SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
 N2
2.3. Waste treatment. Thermal conversion. Incineration CO2
H2O
INCINERATION O2
Reductions: Dioxins
90% volume Furans

75% weight

Gas Scrubbing
900-1200°C System?

Weighing
scale

Unloading
point ash

SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
 2.3. Waste treatment. Thermal conversion. Gasification
Ash / Slag Smokestack
GASIFICATION Air + O2
Air 5
SOLID WASTE Electricity
GASIFIER GAS PURIFICATION SYNGAS COMBUSTION
+ heat
1 C+ 1/2O2 CO
3 4
Water H2S 2CO + O2 2CO2
C+ O2 CO2 2 CH4 + O2 2CO2 + H2O
C+ CO2 2CO NH3 6
C+ H2O CO + H2 Suspended Particles
C+ 2H2 CH4 CO2 sequestration

750-850°C

SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
 2.3. Waste treatment. Thermal conversion. Pyrolysis
PYROLYSIS

300-750°C

SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
 2.3. Waste treatment. Thermal conversion. Pyrolysis
Pyrolysis of Solid Waste
Pyrolysis is a thermal degradation of a substance in the absence of oxygen, whereby these substances are
decomposed by heat, without combustion reactions occurring. The basic characteristics of this process are the
following:
The only oxygen present is the content of the waste to be treated.
The working temperatures are lower than those of gasification, ranging from 300°C to 750°C.
As a result of the process, the following is obtained:
Gas, whose basic components are CO, CO2, H2, CH4 and more volatile compounds from the cracking of organic
molecules, together with those already existing in the waste. This gas is very similar to the synthesis gas obtained in
gasification, but there is a greater presence of tars, waxes, etc. to the detriment of gases, due to the fact that pyrolysis
works at lower temperatures than gasification.
Liquid waste, basically composed of long-chain hydrocarbons such as tars, oils, phenols, waxes formed by condensing
at used temperature.
Solid waste, composed of all non-combustible materials, which have either not been transformed or come from a
molecular condensation with a high content of carbon, heavy metals and other inert components of the waste.

SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
2.3. Waste treatment. Biological conversion

BIOLOGICAL CONVERSION
COMPOSTING
BIOMETHANIZATION
Compost microorganisms

SPECIAL REQUERIMENTS !
The requirements are different for
composting and for bio methanization.
Acidogenic Acetogenic Methanogenic
bacteria bacteria archaea Temperature
Moisture
Organic load (charge)
Balance between C and N
Technology
Aerobic or anaerobic environment

SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
2.3. Waste treatment. Biological conversion

Temperature
< 20 ºC Psychrophilic (psychros gr  cold)
20-40 ºC Mesophilic
40-60 ºC Thermophilic
> 60 ºC Hyperthermophilic

Optimum Total Solids concentration
40-65% for composting
4-30% for biomethanization

SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
2.3. Waste treatment. Biological conversion

C/N Ratio
C/N ratio low – Excess N is lost as ammonia
C/N ratio high – Microbes lack sufficient N and composting is slow
OPTIMUN RATE:
Microbes assimilate C
Need starting ratio (C/N) of 30/1 or 40/1

Optimum Oxygen Level (in aerobic processes like composting)
Composting microbes require at least 5%
Optimum is 10% or more
Atmosphere is 21%
Insufficient oxygen
– Anaerobic decomposition, little heat produced, slow composting
– Produces methane and other odorous compounds

SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
 2.3. Waste treatment. Biological conversion
AEROBIC VS ANAEROBIC

AEROBIC
→
Aerobic New
Organic Matter + O2 +
Microorganisms
CO2 + H2O + NO3- +SO42- +
Microorganisms
Glucose aerobic degradation
38 adenosine
C6 H12 O6 + 6O2 → 6CO2 + 6 H2O + ENERGY triphosphate,
ATP

ANAEROBIC

Organic Matter + Anarobic
Microorganisms → CH4 + CO2+ New
Microorganisms

Glucose anaerobic degradation
Biogas: 0,8 m3 Biogas/kg glucose
Composition 1:1 → (CH4 :CO2 )

C6 H12 O6 → 3 CH4 + 3CO2 Heat power: 4250 kcal/m3

1 m3 biogas = 0.6 L diesel (gasoil)

SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
 2.3. Waste treatment. Biological conversion. Composting
“Coping” natural decomposition and humification to transform organic material into
compost

HUMUS?

Pieces of fruit
Vegetable scraps CO2and other gases
Coffee beans Eggshells
heat
Grass and plant clippings
Dry leaves
water
Finely cut wood and bark chips
Shredded newspaper It is important that composter is in
Straw O2 Garden
contact with the "natural" soil to
composter
Sawdust from untreated wood ensure drainage and the load of
microorganisms.
SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
 2.3. Waste treatment. Biological conversion. Composting COMPOSTING
1. Mesophilic phase
Bacteria:
4. Maturation phase
Gram-
Bacteria:
Pseudomonas
Gram-
Gram +
Actinomycetes
Bacillus
Fungus:
Lactobacillus
Ascomycota
Actinomycetes
Zygomycota
Fungus:
Oomycote
Ascomycota
Algae
Penicillium
Nematoda
Aspergillus
Zygomycota
Mucor

3. Cooling phase
2. Mesophilic phase Bacteria:
Bacteria: Actinomycetes
Bacillus Fungus:
Thermus Source: Joaquín Moreno Casco (2008) Ascomycota
Hydrogenobacter Basidiomycota
Actinomycetes: Protozoa
SOIL AND WASTE TREATMENT
Streptomyces JORDI GARRIGÓ REIXACH
WASTE
NematodaTREATMENT
2.3. Waste treatment. Biological conversion. Composting

COMPOSTING TECHNOLOGIES

Static piles: is the simplest and
least cost approach to composting large
volumes of organic waste materials.

Windrow (rows) composting:
the way of setting the piles

Passively aerated windrows
(PAWS)
SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
2.3. Waste treatment. Biological conversion. Composting

COMPOSTING TECHNOLOGIES

Forced aeration, static piles

Enclosed (in-vessel) composting

Vermicomposting (worms)
Composting at home!!!

SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
 2.3. Waste treatment. Biological conversion. Composting
Criteria for fertilizers made from residues
Concentration limits of heavy metals in fertilizers (solid or liquid) made from residues
(mg/kg dry matter)
Heavy metal A B C
Cd 0.7 2 3
Cu 70 300 400
Ni 25 90 100
Pb 45 150 200
Ni 200 500 1000
Hg 0.4 1.5 2.5
Cr 70 250 300
Cr+4 No detectable según el método oficial

Cr+6 is irritating and can cause blindness in prolonged exposure (in drinking water its
limit is 0.05 mg/L according to the WHO). Cr+3 is considered an essential element.

Real Decreto 506/2013, de 28 de junio, sobre productos fertilizantes. Ministerio de la Presidencia. «BOE» núm.
164, de 10 de julio de 2013. Referencia: BOE-A-2013-7540

SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
2.3. Waste treatment. Biological conversion. Biomethanization

SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
 2.3. Waste treatment. Biological conversion. Biomethanization
1. Receipt + mixture 5. Final products
Heat
Livestock Urban Solid
waste Waste 3. Biogas treatment
Power
Biofilter electric
Selection of turbines
garbage bag
Electricity

4. Phase separation

Receiving tank Solid phase
Post-digestion Centrifuge
Agricultural
Grinder use
pump Digestion

Liquid phase

Mixing vessel Pasteurization Process line
Heat line
2. Bio digestion Biogas line

SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
2.3. Waste treatment. Biological conversion. Biomethanization
Optimal pH
Complex Organic Compounds
carbohydrates, proteins, fats
Hydrolytic bacteria 4.8 – 5.0
Hydrolysis
Simple Organic Compounds
Sugars, amino acids, fatty acids
Acidogenic bacteria
Acidogenesis 5.5 – 6.0

Organic acids and alcohols

Acetogenic bacteria Acetogenesis 5.5 – 6.0

Acetic acid
H2, CO2
Acetate

Methanogenic archaea
CH4, CO2 Methanogenesis 6.5- 7.2
(biogas)

SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
2.3. Waste treatment. Biological conversion. Biomethanization
High solids Typical mass balance
(dry anaerobic digestion)
20-30% TS

SSO (Source-Separated Organics)

TS, Total Solids

SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
 2.3. Waste treatment. Biological conversion. Biomethanization
Low solids Typical mass balance
(wet anaerobic digestion)
4-10% TS

SSO (Source-Separated Organics)

TS, Total Solids

SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
2.3. Waste treatment. Biological conversion. Biomethanization

SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
2.3. Waste treatment. Biological conversion. Biomethanization
Configurations AD (Anaerobic Digestion)

35ºC 55ºC

SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
 2.3. Waste treatment. Biological conversion. Biomethanization
Configurations
AD (Anaerobic Digestion)

Mechanical Shaker
Shaker Shaker
OFUSW OFUSW BIOGAS
INPUT BIOGAS INPUT
BIOGAS
Thermophilic
Heating Reactor

Heating Mesophilic
Reactor
Anaerobic
Heating
Reactor
THERMOPHILIC
OFUSW EFFLUENT
Organic fraction of
MESOPHYLIC
EFFLUENT
Urban Solid Waste EFFLUENT
OUTPUT
SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
2.3. Waste treatment. Biological conversion. Biomethanization
Typical Biogas Parameters
Biogas CH4: 60% by volume
CO2: 40% by volume
H2S: 200 to 4000 ppm
Trace contaminants (highly variable):
siloxanes, chlorinated organics and VOCs
Biogas yield Methane Methane yield
Waste Type (m3/Tm waste) (%) (m3/Tm waste)
Leaves 23 60 24
Grass 34 60 20
Mixed paper 112 60 67
Brush 67 60 40
Food waste 144 60 86
FOG (Fats, Oil and Grease) 390 60 234

SOIL AND WASTE TREATMENT
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WASTE TREATMENT
2.3. Waste treatment. Biological conversion. Biomethanization

Biogas upgrading

Two steps involved in biogas treatment:

Cleaning (removal of minor impurities components of biogas)
Upgrading (removal of CO2 content) aims to increase the low
calorific value of the biogas, and thus, to convert it to a higher fuel
standard

The final product is called biomethane which composed of CH4 (95–
99%) and CO2 (1–5%), with no trace of H2S.

SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
2.3. Waste treatment. Biological conversion. Biomethanization + Composting

SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
2.3. Waste treatment. Biological conversion. Biomethanization + Composting

BIOMETHANIZATION..common in developing countries

Fuel

Animal Dung Biogas plant Light

Biofertilizer
SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
 2.4. Waste landfill

Types of landfills

Real Decreto 426/2020, de 7 de julio, por el que se regula la eliminación de residuos mediante
depósito en vertedero. Legislación basada en la Ley 22/2011, de 28 de julio, de residuos y
sueños contaminados.
Residuos peligrosos: residuo que presenta una o varias de las
–Hazardous waste landfills características… H1 Explosivo, H2 Oxidante…etc.

Residuos no peligrosos: residuos que no están cubiertos por el
–Non-Hazardous waste landfills apartado e) del artículo 3 de la Ley 22/2011

Residuos inertes: aquellos residuos no peligrosos que no experimentan
– Inert waste landfills transformaciones físicas, químicas o biológicas significativas.

“Liquid” waste
Infectious waste
Tires (NFU)

SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
2.4. Waste landfill

Site selection for the disposal of solid wastes

In choosing a localization for a landfill, consideration should be given to the
following variables:

-Public opposition A landfill should be located more than:
-Proximation of major roadways -300 m from water streams
--Speed limits -500 m from houses, schools and
--Load limits on roadways parks
-Bridge capacities -No minimal distance from airport
-Traffic patterns and congestion runways (but more than 10.000m)
-Haul distance (in time)
-Hydrology
-Availability of cover material
-Climate (for example, floods, mud slides, snow…)
-Zoning requirements
-Buffer areas around the site (for example, high trees on the site perimeter)
-Historic buildings, endangered species, wetlands and similar environmental
factors)

SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
2.4. Waste landfill

SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
 Landfill barriers
2.4. Waste landfill

Hazardous Non-Hazardous Inert waste
waste landfills waste landfills landfills

MASS OF WASTE
MASS OF WASTE
MASS OF WASTE

DRAINAGE LAYER ≥ 0.5M DRAINAGE LAYER
DRAINAGE LAYER ≥ 0.5M
for leachate collection for leachate collection
for leachate collection
WATERPROOF ARTIF. LINING ARTIFICIAL GEOLOGICAL
WATERPROOF ARTIF. LINING ARTIFICIAL GEOLOGICAL BARRIER ≥ 0.5m
BARRIER ≥ 0.5m When the natural geological
ARTIFICIAL GEOLOGICAL When the natural geological barrier is not enough
BARRIER ≥ 0.5m barrier is not enough
When the natural geological NATURAL GEOLOGICAL
barrier is not enough NATURAL GEOLOGICAL BARRIER
BARRIER Material of permeability and
NATURAL GEOLOGICAL Material of permeability and thickness equivalent to: k ≤ 1.0
BARRIER thickness equivalent to: k ≤ 1.0 x 10-7 m/s and thickness ≥ 1m
Material of permeability and x 10-9 m/s and thickness ≥ 1m
thickness equivalent to: k ≤ 1.0
x 10-9 m/s and thickness ≥ 5m
>5m >1m >1m
SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
 2.4. Waste landfill

Environmental risks:

Excessive slope → Stability

Inadequate waterproofing of the base → Leaching non-controlled

Mismanagement of the gases generated → Air pollution

Slipping of the waste mass on the impermeable layer → Stability

Air pollution

Biodiversity impact

Groundwater pollution

Soil fertility effects

Visual and health impacts

SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
 2.4. Waste landfill
Operating methods employed in landfill

The trench method: used on level or gently sloping
land where the water table is low. A trench is
excavated. The solid waste is placed in it and
compacted. The soil that was taken from the
trench is laid on the waste an compacted. The area method: the solid waste is deposited
on the surface, compacted and covered with a
layer of compacted soil. The cover material may
come from on or off site
SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
 2.4. Waste landfill
Sectional view through a MSW landfill
TRENCHES
Length: 30 – 300 m
Widths: 5 – 15 m
Depth: 3 – 9 m

Source: Tchobanoglous et al., 1993
SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
 Landfill barriers
2.4. Waste landfill

The regularization, waterproofing and
drainage layers will be placed if
necessary, in the opinion of “the
competent authority” for the
authorization of the closure of the
landfill.

SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
 2.4. Waste landfill
LANDFILL GASES
natural byproduct of the decomposition of Typical constituents found in Municipal Solis Waste
organic material in anaerobic (without landfill gas
oxygen) conditions. It contains several %
Component
gases: (dry volume basis)
Methane 45- 60
The generation of landfill gases depends on: Carbon dioxide 40- 60
Nitrogen 2- 5
Waste composition (in particular the amount Oxygen 0.1- 1.0
of readily degradable organic material). Sulfides, disulfides, mercaptans,… 0- 1.0
Age of waste. Ammonia 0.1- 1,0
Density of the waste. Hydrogen 0- 0.2
Moisture content and its distribution through Carbon monoxide 0- 0.2
the waste mass.
Trace constituents 0.01- 0.06
Acidity / alkalinity (pH).
Characteristic Value
Nutrient availability.
Temperature (°C) 35-50
Temperature.
Density (g/cm3) 1.02- 1.05
Presence of toxic agents and chemical
Moisture content Saturated
inhibitors
High heating
MSW:value (kJ/m3Solid
Municipal ) Waste 16,000- 20,000

Source: Tchobanoglous et al., 1993

SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
2.4. Waste landfill
Evolution of the landfill gases

SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
 Valorization of landfill gases
2.4. Waste landfill
Collection of landfill gases

How methane gas flow from the landfill and through
filters to provide both heat and electricity

Suction
Scrubber
(purifier)

SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
 2.4. Waste landfill
-Rainfall
Leachate -Surface drainage
Liquid that passes through the landfill and that has -Groundwater
extracted, dissolved and suspended matter from it. come from -Liquid produced from the
decomposition of the waste
Leachate constituents

Source: Tchobanoglous et al., 1993
SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
 Landfill barriers
2.4. Waste landfill
Non hazardous waste Non hazardous waste
Inert waste high biodegradable low biodegradable Hazardous waste
organic matter (>15%) organic matter (0.30m)
MINERAL DRAINING LAYER MINERAL DRAINING LAYER REINFORCING WATERPROOF
GEOSISNETTIC or CLAY
(>0.30m) (>0.30m) BARRIER
Waterproofing
WATERPROOF BARRIER WATERPROOF BARRIER MINERAL WATERPROOF
Non-compulsory
REGULARIZATION LAYER BARRIER (K≤10-9 m/sec. in 1m
GAS COLLECTION LAYER GAS COLLECTION LAYER GAS COLLECTION LAYER
(if deemed necessary) (if deemed necessary)
REGULARIZATION LAYER REGULARIZATION LAYER REGULARIZATION LAYER
(≥ 0.50m) (≥ 0.50m) (≥ 1 m)

WASTE MASS WASTE MASS
WASTE MASS
WASTE MASS

Desarrollo técnico del Real Decreto 181/2001 relativo a las instalaciones
dede vertido de residuos (in BOE-A-2002-1697-consolidado)
SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
 2.4. Waste landfill

The “bathtub effect” (sp.
“efecto borde de bañera”)
is the accumulation of
infiltrated leacheate above the
impermeable liner.

SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
 2.4. Waste landfill
A secure landfill design for toxic or radioactive waste
disposal

SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT
 Main ideas from UNIT 2

Separation at the source is the key-factor to a appropriate valorisation of wastes

The collection of wastes can be different depending on the management

Biological treatments are applied to organic substrates

Environmental requirements are crucial for microorganism involve in biological treatments

Thermal valorisation is one of the easiest way to treat the waste, but other more

sustainable approaches should be studied

Landfill has to be avoided as final destination of wastes

Construction of landfills has to be done following the legislation and technical procedures to

avoid environmental risks and, always, depending on the nature of waste.

The landfill is a “living being” which evolves until maturation (leachates and biogas

composition)

SOIL AND WASTE TREATMENT
JORDI GARRIGÓ REIXACH
WASTE TREATMENT