1. Understanding Livestock Odors��Ron Sheffield�Animal Waste Extension Specialist
3. Odors from Livestock Facilities Highly emotional issue
Rural development
Economic importance of livestock industry
Only after we understand the problem can we work towards acceptable solutions.
4. Olfaction-Sense of Smell Complex
Evokes a reaction
Humans detect > 10,000 odors
Mixtures of gases
Able to detect extremely low concentrations
5. Conception of Odors and Smells Describe a childhood odor memory
What is your favorite odor? Why?
Describe your most unusual odor memory
6. Breathing vs. Sniffing
7. Normal Olfactory Sensitivity
9. How are odors produced? By-products of microbial degradation of manure and organic matter
Uncontrolled anaerobic conditions
Highly dependent on the amount and type of microbial activity
10. Manure Decomposition Over 80 to 200 different gasses identified
Manure gasses related to anaerobic decomposition
Ammonia (NH3+)
Methane (CH4)
Hydrogen sulfide (H2S)
Odorants
volatile fatty acids
Dust and other particulate matter
11. Manure Gasses Hydrogen Sulfide
Methane
colder climates, poor ventilation, anaerobic decomposition of stored manure
Ammonia (NH3)
dominates in warmer climates
anaerobic by-product
compounded by recycling of lagoon effluent for waste handling
12. Dust Sources
Feed
Dried Manure
Dander (dead skin)
Hair
Other particulate matter
viral, bacterial, and fungal agents
endotoxin, glucans
Dual role as possible odorant and odor carrier
13. Odor and Gas Emissions Parameters that effect odor and microbe production
moisture content
temperature
pH
oxygen concentrations
environmental conditions (season, wind patterns)
14. Manure Gases Nose detection at low levels
Hydrogen Sulfide (H2S)
Nose detection at high level
Methane (CH4)
Some gases may have a compounding odor effect
16. Odor Emission Sources Livestock buildings
Manure storage units
Land application sites
Method of land application
Feed storage
Mortality storage or disposal units
17. Odor Sources “Background” odor
buildings
lagoons or storage ponds
Seasonal variations in odor
“Short-term” odors
agitation
land application / spray irrigation
18. Odor and Gas Emissions Can be controlled through design and management
ventilation system
management and “housekeeping” practices
waste management system
waste application system
19. Odor Chemistry Odorous Compounds
Aliphatic (fatty) Acids
Amines
Ammonia
Aromatics
Sulfur (inorganic and organic)
20. Compounds Produced through Anaerobic Decomposition Methane
Carbon Dioxide
Carbon Monoxide
Ammonia
Hydrogen Sulfide
Acetic, Propionic, Butyric Acids
Cadaverine and Putresine - bacterial breakdown of amino acids
21. Osmophores Odors are caused by this group of radicals
CHO- Aldehydes
CH2OH- Carbinols
CO-2 Carbonyls
COOH- Carboxyls
OH- Hydroxyl compounds
SH- Sulphydryls
22. Osmophores Odor/smell is due to the presence of different molecules
C2H5OH Ethyl Alcohol, sweet-smelling
C3H5OH Allyl Alcohol, irritating smell
C9H19OH Nonyl Alcohol, offensive smell
23. Oxygen Transfer Replacement of oxygen by sulfur
Non-odorous compounds
H2O Water
H2O2 Hydrogen Peroxide
CO2 Carbon Dioxide
Compounds become odorous
H2S Hydrogen Sulfide
H2S2 Hydrogen Persulfide
CS2 Hydrogen Disulfide
24. Biochemical Oxidation Proteins, amino acids & carbohydrates are plentiful energy source for bacteria
Aerobic or anaerobic process
Bacteria “transfer” oxygen from compounds to a hydrogen acceptor
2NO3- + 12H+ = N2 + 6H2O
CO2 + 8H+ = CH4 + 2H2O
SO4 + 10H+ = H2S + 4H2O (odorous)
25. Purple Sulfur Bacteria - PSB Biochemical Oxidation in Anaerobic Lagoons in NC and southern US
Purple lagoon color
Photosynthetic bacteria
Use H2S as an electron acceptor instead of O2 and NO3
Reduces emission of sulfur compounds and sulfur based odors
26. Photosynthesis
27. Anaerobic Lagoons Studies have been inconclusive relating environmental conditions to the presence of PSB in lagoons
loading rate (TS, VS, NH3, SO4)
class of animals
Temperature
Lagoon start-up procedures
30. Odors and Gases Odor Intensity
measure of detection sensed by the nose
Gas Concentration
actual concentration of gas in the air
The relationship between odor intensity and gas concentration is different for each gas
31. Gas vs Odor Measurement Gas
Identify individual gases
Measure concentrations
Odor - Olfactometry
Analyze mixture
Correlates with odor
Uses human sense of smell
32. Gas Measurement Instantaneous
Integrated average
Precision & detection limit
33. Gas Measurement Patches
Tubes - Indicator & Diffusion
Jerome® meter - H2S
Electronic Sensors
GC / Mass Spectrometer
35. Odor Intensity vs. Gas Concentration Weak positive correlation's for some gases
Ammonia (NH3)
Hydrogen Sulfide (H2S)
Example:
High odor intensities indicate high gas concentrations of NH3 and H2S
However, high gas concentrations do not necessarily indicate a high odor intensity
36. Odor Transport Difficult to document the impact area of gases
Transmitted via air currents
wind direction
wind speed
weight of gas
adsorption to dust particles
39. Dust & Lagoon Interaction Related to Odor Transport
40. Limits to Measuring Odors Changes in weather or micrometeorological conditions
temperature, humidity, inversions
Odor emissions change with time
Wind speed and direction
A snap-shot in time may not reflect the conditions an hour/day before or after a measurement
41. Technologies to Control Odor Prevent odor generation
Capture or destroy odors before any release to the atmosphere
Dispersion or disguise of odors
42. Odor Prevention Technologies Anaerobic treatment
Aeration or Oxidation
Feed additives
Manure pit or lagoon additives
pH control
43. Technologies to Capture Odors Manure storage covers
synthetic
organic mats
Biofilters
Biomass filters
Washing walls
44. Technologies to Disperse Odors Site Selection
Ventilation Design
Vegetated Wind Breaks
Windbreak Walls
Stacks or Chimneys
Perfumes
Masking Agents
