The
agro-industrial
industry
produces
a
lot
of
trash,
which
poses
problems
for
the
environment
and
hinders
productivity.
These
waste
materials
do,
however,
have
unrealized
potential
variety
useful
applications.
We
can
create
sustainable
resource-efficient
future
by
utilizing
wide
range
produced
industry.
Utilizing
these
wastes
in
creating
replacement
is
one
efficient
strategy
to
handle
them.
chapter
also
covers
various
kinds
that
are
produced,
such
as
agricultural
residues,
products
from
food
processing,
livestock
manure,
among
others.
This
aims
present
an
overview
management
strategies
opportunities
exploitation
waste,
highlighting
its
advantages
terms
resource
recovery
environmental
sustainability.
It
looks
at
use
energy
production,
practices,
production
value-added
products.
Additionally,
it
discusses
society
using
while
difficulties
obstacles
must
be
overcome
order
tactics
widely
used.
Sustainability,
Год журнала:
2022,
Номер
14(23), С. 15717 - 15717
Опубликована: Ноя. 25, 2022
It
is
urgent
that
we
increase
global
food
production
to
support
population
growth.
Food
requires
significant
resources,
amongst
them
water
and
energy.
Therefore,
any
losses
of
or
other
agricultural
products
also
means
a
waste
energy
resources.
A
amount
these
occurs
during
the
postharvest
stage,
primarily
processing
storage.
This
considered
avoidable
waste.
The
water-energy-waste
nexus
(WEW),
its
relationship
production,
needs
be
investigated
from
circular
bioeconomy
lens.
Furthermore,
alternative
uses
wastes
should
investigated.
review
focuses
on
agro-wastes
their
management
as
sources
for
bioactive
compounds,
biofertilizers,
biomaterials,
nanomaterials,
pharmaceuticals
medicinal
agents,
growth
media,
e.g.,
plant
tissue
culture.
We
potential
contribution
bioenergy
(bioethanol,
biogas,
biofuel).
Proper
may
mitigation
climate
change,
produce
innovative
bio-ingredients
biodegradable
materials,
enhance
green
bioeconomy.
argue
cannot
discussed
without
referring
role
within
system.
Thus,
this
handling,
applications,
environmental
impacts,
benefits
in
medical
industries
light
WEW
nexus.
Digital Chemical Engineering,
Год журнала:
2023,
Номер
8, С. 100103 - 100103
Опубликована: Май 16, 2023
The
thermochemical
conversion
of
biomass
is
a
promising
technology
due
to
its
cost-effectiveness
and
feedstock
flexibility,
with
pyrolysis
being
particularly
noteworthy
method
for
diverse
product
range.
Despite
the
potential
pyrolysis,
commercialization
remains
elusive,
there
growing
need
fully
understand
dynamics
facilitate
process
scaling
up.
However,
waste
complex,
time-consuming,
capital-intensive.
Machine
Learning
(ML)
has
emerged
as
possible
means
supporting
accelerating
research
despite
these
challenges.
This
study
provides
comprehensive
overview
use
ML
in
from
biorefinery
end-of-life
management.
In
addition,
success
optimization
control,
predicting
yield,
real-time
monitoring,
life-cycle
assessment
(LCA),
techno-economic
analysis
(TEA)
during
highlighted.
Several
methods
have
been
utilized
bid
pyrolysis;
potentiality
artificial
neural
networks
(ANNs)
learn
extremely
non-linear
input-output
correlations
led
widespread
adoption
networks.
Furthermore,
current
knowledge
gaps
future
recommendations
application
are
identified.
Finally,
this
demonstrates
development
well
scalability
biomass.
