Twon water quality, testing and treatment tagd march 2017

1. Water Quality, Testing
and Treatment

2. Water Quality and Testing
 Drinking water standards
 Common contaminants
 Testing
 Why?
 When?
 What?

3. Drinking Water Quality
 Federal Safe Drinking Water Act, 1974 (SDWA):
 Establishes standards for surface and groundwater
sources used for drinking water.
 EPA sets standards based on whether a
contaminant:
1. Harms human health
2. Is known to occur in drinking water
3. Can be detected in drinking water
 TCEQ is required to enforce the SDWA
Water Quality Law and Policy

4. Texas Private Well Regulations
• Well location requirements
• Well construction
• No requirements for water
testing or maintenance
after construction
Water Supply Regulations
EPA – National Drinking
Water Standards
• Public water systems
• Primary Standards – Health
• Secondary Standards –
Nuisance
• Can be used as a guide for
your private well.

5. Secondary Standards
• Secondary standards, or SMCL
• Set for aesthetic considerations
 Taste
 Color
 Odor
• 15 contaminants
• Examples:
 Iron
 Sulfate
 TDS
EPA Drinking Water Standards
Primary Standards
• Maximum Contaminant
Level, or MCL
• Pose risks to human health
• Over 80 contaminants
• Examples:
 Nitrate
 E. coli
 Arsenic
 Organic chemicals and
pesticides

6. Water Well Testing FAQs
How often should the well be tested?
• Annually for bacteria.
• Every few years for general chemistry such as nitrates
and salts.
• As frequently as needed for other contaminants of
concern (http://water.epa.gov/drink/contaminants/index.cfm)
How much will it cost?
• Varies depending on analyses selected.
• Basic E. coli test should be less than $50.
How do I find a lab?
• County Health Departments
• NELAC-certified labs on TCEQ website

7. Private Well Testing
Drinking Water Testing:
• County Health Departments and River Authorities
• NELAC-certified labs on TCEQ website
 http://www.tceq.texas.gov/goto/certified_labs
 512-239-3754

8. Private Well Testing

9. Private Well Testing
Irrigation and Livestock:
Texas AgriLife Extension Service Soil, Water and Forage
Testing Laboratory at TAMU (http://soiltesting.tamu.edu/)

10. Private Well Testing

11. Fecal Bacteria
 Microscopic organisms
found in feces of humans
and other warm-blooded
animals
 Not all are harmful by
themselves
 Indicator organisms:
indicate presence of
pathogenic bacteria,
viruses, parasites
 Fecal coliform and E. coli
are most commonly
tested

12. Why Check for Fecal Coliform?
• Indicator bacteria
 Indicates disease risk from
other organisms that are
pathogenic
• Cost effective
• MCL (maximum contaminant
level) is 0 colonies/100 ml
• Test annually and each time
the well is opened or repaired

13. HUMANS
50 FT. MINIMUM
SEPARATION
100 FT. MINIMUM
SEPARATION
DRAIN/SPRAY FIELD
Sources of Bacteria

14. LIVESTOCK
• 150 FT. MINIMUM SEPARATION
• DOWN SLOPE FROM WELL
Sources of Bacteria

15. DOMESTIC
ANIMALS
150 FT. MINIMUM SEPARATION
FROM PENS, YARDS AND RUNS
Sources of Bacteria

16. Nitrate
• Methemoglobinemia (blue baby syndrome)
 Pregnant/ nursing women
 Infants
 Elderly/ suppressed immune systems
• Sources: fertilizer, animal waste, sewage
Treatment: reverse osmosis, ion exchange, distillation

17. Nitrate
MCL = 10 ppm

18. Sources of Nitrates
HUMANS
50 FT. MINIMUM
SEPARATION
100 FT. MINIMUM
SEPARATION
DRAIN/SPRAY FIELD

19. FERTILIZER
Sources of Nitrates
STORAGE: 150 FT. MINIMUM SEPARATION

20. ANIMAL WASTE
Sources of Nitrates
• 150 FT. SEPARATION FOR PETS AND LIVESTOCK
• WILDLIFE: NO GUIDELINES

21. • Level of dissolved minerals,
including salts
• More than 500 mg/L tastes
salty
• Sodium is often referred to as
a measure of salinity, most
common cause of high TDS in
Texas
Total Dissolved Solids (TDS)

22. .
Salinity Tolerance - Animals
PPM TDS
0 - 3,000 O.K. for all livestock
3,000 – 4,999 Satisfactory, may result in temporary
refusal/diarrhea; poor quality for poultry
4,999 - 6,999 Reasonably safe, not for pregnant/
lactating animals
6,999 - 10,000 Risky to young, pregnant/lactating animals
or animals under heat stress
>10,000 Unsuitable for all livestock

23. .
Salinity Tolerance - Plants
PPM TDS
0 - 175 Excellent, no risk to plants
175 – 525 Good, not for sensitive plants
525 – 1,400 Permissible, not for low salt
tolerant plants
1,400 – 2,100 Doubtful, damage to high salt
tolerant plants
>2,100 Unsuitable

24. .
Other Water Quality Concerns: Boron
PPM Plants
<1 Toxicity to many sensitive plants may occur
at 1 ppm.
2-10 Most perennial grasses relatively tolerant at
2-10.
Livestock
<5 CAST recommendation
Boron can become toxic to some plants when the soil-water
concentration exceeds optimum plant growth levels

25. Critical Levels for Irrigation Water
Electrical Conductivity (EC)
Units Corn Sorghum Cotton
umhos/cm 1100 2700 5100
uS/cm 1100 2700 5100
mmhos/cm 1.1 2.7 5.1
dS/m 1.1 2.7 5.1
ppm 704 1728 3264
mg/L 704 1728 3264

26. Crop Response to Irrigation Water Salinity (EC)
Crop Percent Yield Reduction
0% 10% 25% 50%
Corn 1.1* 1.7 2.5 3.9
Peanut 2.1 2.4 2.7 3.3
Sorghum 2.7 3.4 4.8 7.2
Soybean 3.3 3.7 4.2 5.0
Wheat 4.0 4.9 6.4 8.7
Bermudagrass 4.6 5.7 7.2 9.8
Cotton 5.1 6.4 8.4 12.0
*EC in dS/m

27. Critical Levels for Irrigation Water
Electrical Conductivity (EC)
Units Carrot Boxwood Bermudagrass
umhos/cm 500 2000 4600
uS/cm 500 2000 4600
mmhos/cm 0.5 2.0 4.6
dS/m 0.5 2.0 4.6
Ppm 320 1280 2944
mg/L 320 1280 2944

28. Sodium (Na) Hazard
 Sodic Soil Condition
• Na accumulates on soil
• Loss of structure, hard,
compacted
• Infiltration, aeration,
root growth greatly
reduced
 Measurement
• Sodium Adsorption
Ratio (SAR) has no units

29. SAR – Soil Sodium Absorption Ratio
Sodium concentration in relation to calcium and
magnesium concentrations
• Na can replace Calcium and Magnesium adsorbed on
soil clays
• Causes dispersion of soil particles
• Soil becomes hard and compact, and water infiltration
is affected
• Soil structure can be damaged

30. .
SAR – Soil Sodium Absorption Ratio
<10 No sodium hazard. May be used on all
sensitive crops.
10-18 Medium sodium hazard. Gypsum and
leaching needed.
19-26 High sodium hazard. Generally unsuitable
for continued use.
>26 Very high sodium hazard. Generally
unsuitable for use.
Sodium relative to calcium and magnesium concentrations
SAR Value Sodium Hazard and Comments

31. .
Other Water Quality Concerns: Sulfate
Target Concentrations
Domestic water: > 250 ppm can cause diarrhea
(Secondary Drinking Water Standard)
Irrigation water: Moderate concentration can
reduce growth or cause specific injury
Adds to salinity
Livestock water: > 2000 ppm can cause diarrhea in
most livestock

32. .
Other Water Quality Concerns: Chloride
Target Concentrations
Domestic water: > 250 ppm may cause salty taste
(Secondary Drinking Water Standard)
Irrigation water: >900 ppm is considered non-suitable for
all agronomic crops
Livestock water: Limit not currently established
Adds to salinity

33. Routine Test:
• Conductivity
• SAR
• Individual ions
3-Level Rating:
• Acceptable
• Limiting
• Very Limiting

35.  Crop Management
• Select more tolerant plant species
Managing Marginal Quality Irrigation Water

36. Resources
Dr. Guy Fipps
http://twon.tamu.edu/fact-sheets/

39.  Crop Management
• Select more tolerant plant species.
 Water Management
• Water “deeply” to leach salts (leaching fraction)
Managing Marginal Quality Irrigation Water

40. Leaching Fraction to Control Salt
Accumulation in Soil
Water salinity (mmhos/cm)
• Depends on salinity of the
soil and the applied water
• Can require 5-100% extra
water to control salts

41. Managing Marginal Quality Irrigation Water
 Crop Management
• Select more tolerant plant species
 Water Management
• Water “deeply” to leach salts (leaching fraction)
• Typically 5-75% extra water
 Soil Management
• Mulch to reduce evaporation and improve leaching
• Deep tillage to improve drainage
• Chemical amendments – gypsum to remove sodium
• Routine soil testing to monitor

42. Soil Amendments for Sodium Management

43. Gypsum Rate Based on ESP (SAR)

44. Iron and Manganese
• Nuisance –unpleasant taste,
odor, and color
• Secondary MCL:
 Iron = 0.3 mg/L
 Manganese = .05 mg/L
• Stains- Iron (reddish brown)
Manganese (brownish black)
on concrete, laundry, and
plumbing fixtures

45. Iron and Manganese Treatment
Treatment depends on type and
concentration
• Initially clear, but particles form
and settle out
• Water from tap has solid
particles or has a tint
• Iron/manganese bacteria-
reddish or black slime in toilet
or faucets.
Treatment: Phosphate injection, water softener, oxidizing filter, aeration/filtration,
shock treatment and filtration

46. Hydrogen Sulfide
• Colorless gas with a “rotten egg” odor
• Formed by sulfur- and sulfate-reducing bacteria that can occur
naturally in groundwater
• Shallow or poorly constructed wells
• Wells drilled in shale, sandstone, near coal or oil fields

47. Hydrogen Sulfide (H2S) Treatment
• If the smell is only from the hot water faucet, problem likely is in
the water heater
 Ensure the water heater is set according to manufacturer’s
recommendation – often 140o will help. Careful of scalding.
 Problem might be caused by a chemical reaction with the
magnesium control rod (anode)
o Can be removed or replaced with an aluminum or zinc rod.
 Consider a tankless heater.
• If the smell is coming from both hot and cold faucets, but only
from water treated by a water softener and not in the untreated
water, problem likely is sulfur bacteria in the water softener.
 Hire a water treatment specialist to clean the water softener.

48. Hydrogen Sulfide (H2S) Treatment
• If the smell is strong when the water in both the hot and cold faucets
is first turned on, and becomes weaker or goes away after the water
has run for a while, or if the smell varies over time, the problem is
likely sulfur bacteria in the well or plumbing system.
 If from sulfur-reducing bacteria, shock chlorination may treat;
could follow with a UV filter OR manganese greensand filter (up
to 10 ppm) or continuous chlorination system (6 to 75 ppm)
• If the smell is strong when you first turn on the water in both the hot
and cold faucets and is more or less constant and persists with use,
the problem likely is H2S in the groundwater that supplies the well.
 A whole house carbon filter may remove enough (GAC up to 1
ppm and Catalytic C “more” depending on DO).
 Aeration tank, early-style pressure tank bladder (up to 2 ppm)

49. Hydrogen Sulfide (H2S) Treatment

50. What to Test for: Nearby Land Use
Problem Type Symptoms Recommended Test
Leaking fuel tank Hydrocarbon scan, VOCs
Landfills TDS, pH, heavy metals
Gas or oil drilling
TDS, chloride, sodium, barium, lead,
pH, corrosivity, strontium
Coal mining
TDS, iron, sulfate, pH, corrosivity,
manganese, aluminum
Septic system failure Fecal coliform/E. coli , nitrate
Intensive agricultural use
Total coliform, nitrate, pesticide
scan, pH, TDS
If suspect or observe

51. What to Test for: Nuisance Problems
Problem Type Symptoms Recommended Test
Red or brown Iron
Black Manganese
Reddish-brown slime Iron bacteria
White deposits, soap scum Hardness
Rotten egg Hydrogen sulfide
Metallic pH, iron, zinc, copper, lead
Salty TDS, chloride, sodium
Septic, musty, earthy Coliform bacteria, iron, methane
Gasoline or oil Hydrocarbon scan, VOCs
Soapy Surfactants, detergents
Brown, yellow, reddish Iron
Cloudy Turbidity, suspended solids
Black Manganese
Stains on Fixtures or
Plumbing
Odor or Taste
Appearance of water

52. What to test for: Health Concerns
Problem Type Symptoms Recommended Test
Gastrointestinal illness
coliform bacteria,
sulfates, Giardia
Water supplies used for infants less
than six months old, pregnant or
nursing women, or elderly with
genetically impaired enzyme system
Nitrates
Family member on recommended
low-sodium diet Sodium
Dicoloration of children's teeth Fluoride
Uses or
Symptoms

54. Questions?

55. Water Treatment Options

56. Water Treatment Options
• Particle and microfiltration
• Activated carbon filter
• Reverse osmosis
• Distillation
• Ion exchange – water
softening
• Disinfection
• Continuous chlorination
• Ultraviolet light

57. Water Treatment
• Test the well
• Locate contamination source if
possible
• Check well construction
• Inspect septic system
• Eliminate source of
contamination
• Consider drilling new well
Point of Entry (POE)
Treats water as it enters a
home, whole house
Point of use (POU)
Installed at the faucet

58. Licensed Water Treatment Specialists
www.tceq.state.tx.us/

59. Licensed Water Treatment Specialists
www.tceq.texas.gov/licensing

60. Licensed Water Treatment Specialists
www2.tceq.texas.gov/lic_dpa/index.cfm

61. Licensed Water Treatment Specialists
www2.tceq.texas.gov/lic_dpa/index.cfm?fuseaction=licall.searchgp

62. Licensed Water Treatment Specialists

63. Licensed Water Treatment Specialists

64. Licensed Water Treatment Specialists

65. Licensed Water Treatment Specialists

66. • Fecal coliform bacteria
 Indicator bacteria
 Indicates risk from other disease-causing organisms
 E. coli from human and animal digestive systems
• Iron, manganese, and sulfur-reducing bacteria
 Nuisance bacteria, not a health risk
Bacteria

67. Shock Chlorination
• Method of disinfecting a water well
• Not a long term solution
• Should be done anytime well system is “opened”
• Recommended to contact a licensed well driller
• If homeowner does it, make sure to follow correct procedure
Treating Bacteria

68. • If recurring, try to identify the source
• To kill bacteria and viruses:
 Chlorination
 Ultraviolet light
 Ozone
 Distillation
Treating Bacteria
• If you have a positive test for E. coli:
1. Boil all water intended for drinking or cooking
2. Re-test your well water
3. Hire a well driller to disinfect the well thoroughly with chlorine
4. Monitor the water quality to ensure the problem does not recur

69. Shock Chlorination of Stored Water
• Check to see if storage tank is the source
• Determine the correct amount of chlorine
Treating Bacteria

70. Continuous Chlorination
• Requires “contact time”
• Professionally installed
Treating Bacteria
• Disinfection by-products

71. Ultraviolet systems (UV)
• Disrupts bacteria life cycle
• More effective than chlorine
• Low cost to operate
• Easy to maintain
• No taste or odor
Treating Bacteria

72. • Ozone Systems
 Injects O3: oxidizes
 Treats bacteria, iron,
manganese
 Point-of-Entry
Treating Bacteria
• Distillation
 Removes inorganic
contaminants
 Volatile organic chemicals
(VOCs) may vaporize along with
water and re-contaminate
water
 Point-of-Use
Distillation

73. • Filtration
 Several types of filters
 Remove suspended solids
 Filters are made to remove specific particles sizes
 Can be used prior to other water treatments
Filtration

74. Filtration
Media Filters
 Used for suspended solids
 Often used prior to other water treatment devices
 Requires back
flushing
 Point-of-Entry

75. Cartridges
 Primarily used
for suspended
solids
 Sized by pore
space and flow
rate
Filtration
 Replace filters to avoid clogging
 Size by targeted contaminant

76. Activated Carbon Filters
• Coal or charcoal surface absorbs contaminants
• Processed to make large surface area available for adsorption
or chemical reaction
• Replace carbon regularly
• Point-of-use
• Most common
May treat:
― Chlorine
― Color
― Lead
― Radon
― Taste and odor

77. Reverse Osmosis (RO)
• Effective for a variety of
contaminants
• Pressure forces water
through a membrane
• Point-of-use
• Could overwhelm septic
Problem
Pollutants
Aluminum, Arsenic, Asbestos, Barium, Cadmium, Chloride,
Chlorine, Chromium, Copper, Fluoride, Iron, Hardness, Lead,
Magnesium, Manganese, Mercury, Nitrate, Radium, Radon,
Silver, Sodium, Sulfate, Endrin, Heptachlor, Lindane

78. Ion Exchange – Water Softener
• Water softeners
 Calcium and magnesium ions exchanged with sodium or potassium
 Can remove some dissolved metals
 Will not remove particles, pathogens, organic chemicals
 Works best if water has been pre-filtered
• Components
 Resin tank
 Brine tank
• Automatic
• Semiautomatic
• Manual regeneration
 Recharge based on water usage NOT time
• Dispose of discharged brine properly

79. Ion Exchange – Water Softener
Replacing hardness
with salinity will
extend appliances, but
may damage soils in
the septic leach field

83. Resources on specific water quality issues available
through: twon.tamu.edu and agrilifebookstore.org

84. Questions?