Prevention & Control
Download
Report
Transcript Prevention & Control
Microbial Life in Paper Machine:
Prevention and Control
TAPPI Monograph: Microorganisms in Papermaking
Piyush K. Verma, Nishi K. Bhardwaj, R. Varadhan
Avantha Centre for Industrial R & D, Yamuna Nagar (Haryana)
IPPTA ZONAL SEMINAR
ON
Best Maintenance Practices in Pulp and Paper Mill to Improve Profitability
Why do microbes grow?
Sunlight
IPPTA ZONAL SEMINAR
ON
Best Maintenance Practices in Pulp and Paper Mill to Improve Profitability
Changes in Operational / Industry Practices
Water system closure
Noxious chemical cycle up
Nutrients cycle up
Stagnant chests
Neutral to alkaline conditions
Increased use of recycled pulps
Large chests constructed with long dwell times
Reduced biocide programs due to cost constraints
IPPTA ZONAL SEMINAR
ON
Best Maintenance Practices in Pulp and Paper Mill to Improve Profitability
Microbial Deposits
Filamentous bacteria
Algae
Fungi
Non Microbial Deposits
In addition to wood
fibers, fibrils, fines and
fillers, other materials
also get deposited:
Moulds/ Yeast
•
Strength additives
•
Uncooked
granules
Mimic microbes
Reference TAPPI Monograph: Microorganisms in Papermaking, Papercon, 2011.
starch
Comparison of Biological Activity Test Methods
Method
Time
Accuracy Quantitative
results
Comments
Bio-Lert
1-4 hours Very Good
Yes
Rapid simple procedure
Standard
Plates
Dip-Stick
48-72
hours
24 hours
Excellent
Yes
Yes
Yes
Time consuming
procedure
Results not rapid enough
ATP<30 min
luminescence
Good
May be
TTC, Indicator 4-48 hours
Dyes
Good
Yes
Fair
No
Ninhydrin
Spray
5 min
Simple test, results not
rapid enough, pulp times
can interfere with test
Results not rapid
enough, sample
preparation sometimes
complicated
Rapid amino-nitrogen
test, not quantitative
Reference: Bajpai P (2012) Slime Control. In: Bajpai P (eds) Biotechnology for pulp and paper processing.
pH Preference of Microbes?
Alkaline Vs. Acid
Effect of pH on microbial growth
Acid
Alkaline
Typical
fungi
filamentous
bacteria
Predominant
single cell
single cell
Typical
filamentous
bacteria
protozoa
algae
protozoa
algae
1X
2-4 X
bacteria
Minor
Organism
Biocide
needs
Reference TAPPI Monograph: Microorganisms in Papermaking, Papercon, 2011.
Machine Surfaces
• Headbox
• Approach piping
• Frame
Fresh Water
Filamentous bacteria,
algae, protozoa,
worms
Broke Towers
Heavily contaminated
Back Water
Entry (Check) Points for Microbes
White Water System
Recycled Fibres
Paper Mill Additives
Why do We Care About Microbes?
Deposit
from foil
pan
Reduced paper quality & strength
Odor problems/ Obnoxious odors
Rejected paper, Customer complaints
Sheet
defects
Machine downtime
Viscosity deterioration of coating batches
Brightness , shade issues
Screening / filtering issues
Corrosion (MIC)
Decreased profitability
Reference TAPPI Monograph: Microorganisms in Papermaking, Papercon, 2011.
Mill Safety Issues
Reference TAPPI Monograph: Microorganisms in Papermaking, Papercon, 2011.
Biocorrosion
Microbiologically influenced corrosion
Direct
Biofilm formation
Indirect
Corrosive metabolic byproducts
Types of Microbes Involved in MIC
Metal depositors
Slime forming bacteria
Acid formers
Sulfate reducing bacteria (SRB)
Slime Forming Bacteria
Typically aerobic
All produce an exopolymer
Contains water, polysaccharides & protein
Traps inorganic salts, fibers, fines, fillers & debris
Metal Depositors
Gallionella, Sphaerotius, Crenothrix, Leptothrix
All aerobic; oxidize either iron or manganese to oxides
Acid Producers
Clostridium (anaerobic)
Thiobacillus (aerobic)
Sulfate Reducing Bacteria
All SRBs are anaerobic
Desulfovibrio most common genus
SRBs do not attack metal directly
Typically produce localized pitting corrosion
Monitoring Biocorrosion
After it has occurred
Post mortem examination
In situ monitoring
Difficult
Side stream monitoring
Suspension of coupons in raw or process water
Biofouling sampling device
Strategies to control microorganisms
Water quality
Housekeeping
Oxidants- short term kill
Biocides- short and long term kill
Thermal
Radiation (UV/ gamma)
Key Elements of Microbial Control Program
Engineering survey
Microbiological survey
Product selection
Implementation/ Follow up
Engineering Survey
Three major systems of concern Recycled lines/ Dead legs
Recirculated water system
Freshwater sources
Stock system
Temperature and pH
Additives system
Process additives
Tank volumes/ capacity
Current biocide program
Sampling points
Microbiological Survey
Deposit analysis
Microbiological analysis
Chemical analysis
Microbial survey of process waters, additives & stock chests
Product Selection
• Oxidizing biocides (very fast kill; short duration)
o May be stabilized (hydantoins, sulfamate)
o Typically continuous dosing
• Non oxidizing biocide (slower kill; Longer half life)
o Typical intermittent dosing
o Inhibits reproduction, doesn’t necessary kill
• Non biocidal technology
o Enzymes, biodispersants & adjuvants
Monitoring and Follow Up
• Employ routine monitoring , Machine runnability, quality, defects
etc.
Oxidants and Biocides: Functions
Oxidants and Non Oxidizing Biocides:
Kill all aerobic bacteria
Maintain adequate level of oxidant and/or biocide
Oxidants:
Oxidize compounds
Oxidants: Oxidation of processing chemicals, e.g. polyacrylic acid
and CMC, limits the levels that can be used.
Oxidants
Hydrogen Peroxide
Short term MB control
Environmentally friendly
Microbial resistance (degradation to water and oxygen by
catalase enzyme)
Hypochlorite & Chlorine
Affects viscosity
Chlorinated organic compounds
Effective at neutral to acid pH
Very corrosive
Oxidants
Ozone
Excellent
Short term MB Control
Peracetic acid
Short term MB control
Environmentally friendly
Sodium Chlorite
Short term MB control
Neutral to acid pH
Chlorine dioxide
Does not chlorinate
Short term MB control
Biocides (Non–oxidizing)
Mills that produce food contact paper and paperboard
Iso thiazolin
Benzisothiazolin
Glutaraldehyde
Bromonitropropane diol
Sodium orthophenyl phenate
Thione
Reference TAPPI Monograph: Microorganisms in Papermaking, Papercon, 2011.
Additional Non-oxidizing Biocides
Methylisothiazolin(MIT)
Tetrakishydroxymethyl phosphonium sulfate (THPS)
Dodecylquanidine(DGH)
Oxazolidines
Dibromodicyanobutane (DBDCB)
Methylenebiosthiocyanate( MBT)
Hydantoins
HCHO
Bromohydroxyacetophenone( BHAP)
Adamantanes
HCHO
Reference TAPPI Monograph: Microorganisms in Papermaking, Papercon, 2011.
Microbial Tolerance or Resistance to Oxidants
and Biocides
Biofilm
Tolerance
Resistance
Prevention of biofilm formation
Cleaning
Sterilization
Areas of Concern for Paper Mill Microbial Control
Unloading raw materials
Adequate microbiological control in slurry prior to unloading
Uncontaminated hoses, lines, pumps, etc.
Each raw material should have its own unloading system
Biocide-biocide compatibility, Biocide-process chemical compatibility
Raw material storage/ screening facilities
Adequate MB control in raw material storage tank
Storage tank recirculation system, good mixing
Equipment to add oxidants and/or biocides into the intake side of the
recirculation pump
Biocide-biocide compatibility, biocide-process chemical compatibility
Water quality (closed water system: water reuse)
Coating
Adequate MB control for each coating ingredient
Coating biocide should be effective and compatible
Coating storage tank
Key area for intensive bacterial monitoring
Adequate MB control
Run tank (excess coating typically recycled back to run tank)
Adequate MB control
Crucial area for MB control
Recirculation line from coater to coater feed tank
Boilouts-Chemical Cleaning Programs
Goals of Boilout
Remove Organic and inorganic build-up
Remove deposits
Clean the forming fabric
Housekeeping = Runnability
Boilout Benefits
Prevention of Premature Slime Accumulation
Prevention of Corrosion Pitting
Prevention of Scale Formation
Removal of Organic Deposits
Biolout Components
Caustic (Sodium Hydroxide)
Acid (Sulfuric)
Organic Penetrants
Inorganic Dispersants
Forming Agents
Typical Boilout
Pre Boilout wash-up
pH of 12-12.5
Temperature of 1300-14500F
Re-circulation, Neutralization
New Technology Options
Modes of action of microbicides, biodispersants, enzymes and
biofilm inhibitors
Product
Mode of Action
Microbiocides Reduce/ control microbial populations
Biodispersants Loosen wet-end deposits and support the effect of
microbiocides
Enzymes
Cleave specific bonds in the EPS
Biofilm
inhibitors
Prevent the formation of a concentrated EPS layer
around cells thus preventing biofilm growth
Reference TAPPI Monograph: Microorganisms in Papermaking, Papercon, 2011.
New Technology Options
Enzymes & Biodispersants
0.1-0.5% typical usage rates
Proprietary combinations of enzymes, dispersants and surfactants
Neutral pH Boilouts: Effective in removing MB, starch, cellulosic
and protein containing deposits
Alternative if high or low pH solutions are problematic
Use of dispersants and penetrants with standard temperature and
time
Accelerates removal of general wet end deposits during neutral
boilout procedures
Reduces boilout time, maintenance on machine can be completed
during the boilout
Causes no problems in waste treatment facilities
Green Principles & Enzymes
Prevent Waste
Design safer chemicals and products
Design less hazardous chemical synthesis
Use renewable feedstock
Use catalysts, not stoichiometric reagents
Avoid chemical derivatives
Maximize steam economy
Use safer solvents and reaction conditions
Increase energy efficiency
Design chemicals and products to degrade after use
Analyze in real time to prevent pollution
Minimize the potential for accidents
Reference TAPPI Monograph: Microorganisms in Papermaking, Papercon, 2011.
Monthly average values of Total bacterial Count at the wire pit
in a tissue mill using the enzymatic biocide. Red bars indicate
base line values
Bacterial counts at the wire pit in a tissue mill after the usage of
enzymatic biocide
Reference: Juan C. Cotrino and Victor Ordonez (2011), TAPPI Papercon Conference
Monthly average values of Total bacterial Count at the machine
chest in an OCC recycling mill. Red bar indicate base line values
Bacterial count at the machine chest of an OCC recycling mill after
the usage of enzymatic biocide.
Reference: Juan C. Cotrino and Victor Ordonez (2011), TAPPI Papercon Conference
Summary
Microbial colonization of machines increases downtime and
decreases profitability.
Biofilms form deposits that lead to sheet defects.
Microbial spoilage of additives and fibers can alter pH, cause
odors, and reduce sheet strength and quality.
Understanding the papermaking process and basic microbial
physiology is essential in diagnosing and solving problems.
Monitor microbiological contaminants throughout the paper mill.
Define biocide treatment with lab studies and confirm with field
testing.
Follow biocide manufacturers recommendations.
Follow up with routine monitoring.
Summary
Effective house cleaning & biocide application are integral parts of
successful integrated microbial control strategies.
Oxidants and biocides must be selected with both efficacy and
compatibility in mind.
Oxidant and biocide application techniques must adhere to
environment, safety, and health regulations.
Resistance development is a reality. Oxidant, biocide, and microbial
testing application must be accurate, precise, and as “real time” as
possible.
Oxidants and biocides must not only be effective, they must not
interfere or compromise subsequent papermaking applications.
Summary
Mechanical cleaning to remove deposits.
Caustic cleaning with water/ dispersant flush.
After repairs, system refilled with water plus dispersant and nonoxidizing biocide that are non-aggressive to metallurgy; repeated
as needed.
Under “normal operations”, system treated with nonionic
dispersant and biocide.
Successful boilouts depend on: Adequate time, Proper pH,
(alkalinity), Correct temperature, Solution formulation, Proper
wash-up after the boilout.
Work with machine crew to establish good practices: Safety, Setup, Clean-up & Inspection.
IPPTA ZONAL SEMINAR
ON
Best Maintenance Practices in Pulp and Paper Mill to Improve Profitability
http://www.tappi.org/content/events/11papercon/documents/700.
655%20pptA.pdf