Primary Standards - Virginia Household Water Quality Program

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Transcript Primary Standards - Virginia Household Water Quality Program

Spotsylvania/Stafford County
Drinking Water Clinic
Interpretation Meeting
Virginia Household Water Quality Program
Virginia Master Well Owner Network
Virginia Cooperative Extension
Biological Systems Engineering Department
Virginia Tech
Why are we here?
• Caring for your private water system
• Well location, protection, and construction
• Well maintenance and care
• Drinking water regulations – knowing how
much is too much
• Water testing – what’s in your water?
• Dealing with problems
• Additional resources
2
Private Water Supplies in Virginia

Majority of households in 60 of Virginia’s 95
counties rely on private water supply systems
(> 1,700,000 people)

In the U.S. municipal water supplies are regulated
by the EPA under the Safe Drinking Water Act;
private supplies are not!

Homeowners relying on private water supplies:
◦ Are responsible for all aspects of water system
management
◦ May lack knowledge and resources to effectively manage
◦ Usually don’t worry about maintenance until problems arise
3
How does water move to my well?
(Bedrock/drilled well)

In this part of Virginia, groundwater
moves through fractures, or cracks in the
bedrock

Water can come from many different
directions, depths, and sources into one
well

It can take water hours, days, or years to
move through bedrock

Well casing extends through loose
“overburden” and into the bedrock, where
an “open” borehole continues
underground

Water can come from any fractures that
intersect the open borehole
4
How does water move to my well?

In drilled or bored wells in sandy
aquifers, groundwater fills up the
pore spaces between grains of
sediment or sand

In shallow wells, water moves
relatively quickly from the
surface down into the water
table; with deeper wells, it takes
more time.

There are a large range of
depths of wells reaching aquifers
at varying levels
5

Photo credit: Swistock, Penn State Univ
Proper well location
Well should be at least:
◦ 5 feet from property boundary
◦ 10 feet from building foundation
(50 feet if termite treated)
◦ 50 feet from road
◦ 50 feet from sewers and septic tanks
◦ 100 feet from pastures, on-lot sewage system
drainfields, cesspools or barnyards

Upslope from potential contamination

Not in an area that receives runoff
6
Proper well construction

Contract a licensed driller:
◦ Valid Class A, B or C contractor license with WWP
(Water Well and Pump) classification
Well casing
◦ Minimum of 20’ for bored, 50 – 100’ deep for
drilled, depending on class of well
◦ Extends 12” above ground

Grouting to a minimum of 20’

Sanitary well cap or sealed concrete cover

Ground slopes away from well
12”
Photo credits: SAIF Water Wells ; Penn State University

7
The Finished Product – Drilled Well
8
http://www.omafra.gov.on.ca/english/environment/06-117.htm
Well Maintenance Tips

Do not use fertilizers, pesticides, oil, or paint
around well

Keep area around well clean and accessible

Keep careful records
◦ original contract, water test results and any
maintenance or repair information

Every year:
◦ Conduct thorough visual inspection of well
◦ Check cap for cracks, wear and tear, tightness

Every 5-10 years have well inspected by a qualified
professional (with WWP classification)
9
Private Water Supply Regulations
• Virginia Private Well Regulations
o Specify application, inspection and
construction requirements
o No requirements for maintenance or water
testing after construction of well –
responsibility of the owner!
• EPA National Drinking
Water Standards
o Apply to PUBLIC systems
o Primary (health) and Secondary
(nuisance)
o Can be used as guidance for private
systems to know “how much is too much”
10
EPA Drinking Water Standards
Primary Standards
Secondary Standards
• Also called Maximum
Contaminant Level (MCL)

Also called SMCL or RMCL

Cause aesthetic problems:
• Cause health problems
o
Staining
• Enforced for public systems
o
Taste
• Over 80 contaminants
o
Odor
• For example:

Can naturally occur in
ground water

About 15, including:
o
Nitrate
o
Lead
o
Coliform
o
Iron
o
Most organic chemicals and
pesticides
o
Fluoride
o
Chloride
11
Testing water quality

Why test?
◦ Protect family’s health and safety
◦ Many contaminants undetectable by human senses
◦ Preventive measures often more effective and less expensive
◦ Legal protection

When to test?
◦ Routine tests every 1-3 years
◦ Pregnant woman or infant in the home
◦ Recurring gastrointestinal illness
◦ Change in taste, appearance, odor of water
◦ Any services or repairs are done
12
What should I test for?

Every year test for coliform bacteria
◦ Simple, relatively inexpensive test
◦ Indicates possible contamination from human or animal waste

Every three years test:
◦ pH (secondary std: 6.5 – 8.5)
◦ Total Dissolved Solids (TDS; secondary std 500 mg/L)
◦ Other contaminants based on local land uses nearby and
condition of water
13
Conditions or nearby activities of concern
Conditions or Nearby Activities
Test for:
Recurring gastro-intestinal illness
Coliform bacteria, E. Coli
Household plumbing contains metals
pH, lead, copper
Corrosion of pipes and plumbing
Corrosivity, pH, lead
Nearby areas of intensive agriculture
Nitrate, pesticides, coliform bacteria
Coal or other mining operations
Metals, pH, corrosivity
Dump, junkyard or landfill
VOCs, TDS, pH, sulfate, chloride, metals
Odor of gasoline or fuel oil
VOCs
Objectionable taste or smell of water
Hydrogen sulfide, corrosivity, metals
Stained plumbing fixtures or laundry
Iron, copper, manganese
Salty taste
Chloride, TDS, sodium
Scaly residues, soaps don’t lather
Hardness
Rapid wear of water equipment
pH, corrosivity
Water is cloudy, frothy or colored
Colors, detergents
 If you need help figuring out what to test for, call Erin!
Adapted from “Drinking Water for Household Wells”, EPA, 2002
14
Understanding test results

Most results provided as concentrations:
◦ mg/L (milligrams per liter) ≈ ppm (parts per million)
◦ µg/L = (micrograms per liter) ≈ ppb (parts per billion)

Other units unique to test
◦ Radon, hardness, pH

Compare to EPA standards:
http://www.epa.gov/safewater/contaminants/index.html
15
Sources of potential contaminants or
issues of concern
well
Surface water contamination: nitrate, bacteria
Source may be plumbing
materials or existing water
treatment device:
sodium from
Where a contaminant comes
copper
leadwith it!
affects how we can deal
bacteria
Often found in groundwater naturally, may
be due to man’s activities on or below
ground:
arsenic
TDS
iron
hardness
16
Options for problem water
1. If possible, control the source of pollution
◦ Divert runoff, maintain septic system
2. Improve maintenance of water system
◦ Install sanitary well cap, slope the ground
3. Treat the water to reduce contaminant
concentration
◦ Match the treatment option to the pollutant
◦ Consult a professional
4. Develop a new source of water
◦ Deeper well, develop spring, connect to
public water
17
http://static.howstuffworks.com/gif/septic-tank-cleaning-1.jpg, http://www.shipewelldrilling.com/Pictures/well_drilling_rig.jpg, http://www.clearflow.ca/REVERSE_OSMOSIS2.jpg
Treatment Considerations

Be sure to explore ALL of your options

Always have water tested by a certified lab

Be aware of unscrupulous businesses – look for
National Sanitation Foundation (NSF) and Water
Quality Association (WQA) certifications, consult
Better Business Bureau (BBB)

Point of Use (POU) vs. Point of Entry (POE)

Weigh benefits and limitations of a device:
◦ Cost
◦ Maintenance requirements
◦ Warranty
18
Spotsylvania and Surrounding Counties:
Who participated?
County
# participants
Spotsylvania
65
Stafford
27
Louisa
1
Caroline
1
King George
1
19
Spotsylvania and Surrounding Counties
Questionnaire Results (n=95)
Problems experienced with water
% reporting
Objectionable odor
23.2
Staining of fixtures, appliances, laundry
53.7
Unpleasant taste
21.1
Corrosion of pipes and plumbing fixtures
16.8
Unnatural color or appearance
9.5
Presence of particles
12.6
Sources of potential contamination
% reporting
Septic drain field (< 100’)
20
Heating oil storage (< 100’)
6.3
Stream (< 100)
10.5
Field crop operation (< 1/2 mile)
22.1
Major farm animal operation (< 1/2 mile)
23.2
20
SAMPLE Test Report
Test
Iron (mg/L)
Manganese (mg/L)
Hardness (mg/L)
Sulfate (mg/L)
Fluoride (mg/L
Total Dissolved Solids
(mg/L)
pH
Sodium (mg/L)
Nitrate-N (mg/L)
Total Coliform Bacteria
E. Coli Bacteria
First Draw Data:
Arsenic (mg/L)
Copper (mg/L)
Lead (mg/L)
Flush Data:
Arsenic (mg/L)
Copper (mg/L)
Lead (mg/L)
Household
Water Sample
Maximum Recommended
Level or Range
ND
0.073**
44.7
1.2
ND
0.3
0.05
180
250
2
84.5
5.8**
8.1
ND
Present**
Absent
500
6.5 to 8.5
20
10
Absent
Absent
ND
1.1**
0.007
0.01
1.3
0.015
ND
ND
ND
0.01
1.3
0.015
ND indicates not detected (below the instrument detection limit);
**Measured value exceeds recommendation for household water
21
2012 Spotsylvania and Surrounding Counties Results (95)
Std
Ave
Max/Extreme
% Exceeding
Std
0.3
0.126
2.95
8.4
Manganese (mg/L)
0.05
0.027
0.40
14.7
Hardness (mg/L)
180
45.9
259.9
4.2
Sulfate (mg/L)
250
15.9
98
1.0
Fluoride (mg/L)
2.0/4.0
0.11
0.77
0.0
500
137
1013
2.1
5.1
29.5 (<6.5)
8.2
0 (>8.5)
Test
Iron (mg/L)
Total Dissolved Solids (mg/L)
6.5 to 8.5
6.8
Sodium (mg/L)
20
28.97
683.4
27.4
Nitrate-N (mg/L)
10
0.184
2.04
0
Total Coliform Bacteria
ABSENT
--
--
46.3 (present)
E. Coli Bacteria
ABSENT
--
--
5.3 (present)
pH
22
2012 Albemarle and Surrounding Counties Results
(96 samples)
Test
Std
Copper (mg/L) – First Draw
Copper (mg/L) – Flushed
1.0/1.3
Arsenic (mg/L) – First Draw
Arsenic (mg/L) – Flushed
0.010
Lead (mg/L) – First Draw
Lead (mg/L) – Flushed
0.015
Ave
Max/Extreme
% Exceeding
Std
1.076
7.259
22.1
0.096
1.634
1.1
0.001
0.001
0
0.001
0.002
0
0.019
0.405
29.5
0.001
0.014
0
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
Cannot be smelled, tasted or seen

Coliform bacteria is an indicator
organism – means diseasecausing bacteria may be present

Public standard is 0 colony
forming units(cfu)/100 mL
(ABSENT)

If present, test for fecal coliform or
E. coli presence – indicator that
sewage or animal waste is
present.
Photo credits: www.water-research.net, www.britannica.com
Coliform Bacteria
24
If Coliform Bacteria are PRESENT

Don’t panic!

Examine well for pathways surface water can
enter well (cracks in casing), make sure
sanitary well cap is installed and secure,
ground slopes away from well, etc.

Consider shock chlorination

Retest after shock chlorination

Long term treatment options: ozonation, UV
light, continuous chlorination
25
http://www.kimicontrol.com/microorg/escherichia_coli.jpg
If E. Coli Bacteria are PRESENT

Take immediate steps to address

Shock chlorinate

Retest water

In the meantime, consider boiling or use
another source of water for drinking or
cooking

Check for potential contamination sources

Consider long-term treatment options: UV
light, ozonation, continuous disinfection
26
pH



Measure of the
acidity or alkalinity
of a substance
(0 – 14) scale
Logarithmic scale:
pH = 5 is 100
times more acidic
than pH = 7
Good indicator of
general water
quality
Increasing acidity
0
1
2
Battery acid
Gastric acid
Lemon juice
3
Vinegar
4
Neutral
5
Coffee
6
Milk
Distilled water
7
8
9
Recommended
pH range
6.5 – 8.5
Baking soda
Sea water
10
Increasing alkalinity 11
12
13
14
Milk of magnesia
Ammonia
Bleach
Lye
27
Corrosive Water

Also called aggressive water

Corrodes metal plumbing – can leach metals, causes pitting
and leaks, reduces length of appliance life

Most commonly caused by low pH; other contributing
factors include alkalinity, temperature, TDS levels

EPA recommends drinking water be non-corrosive

Excess copper or lead in drinking water is a health concern

Depending on pH, treat with acid neutralizing filter or
soda ash injection
http://www.bushman.cc/photos/Copper_Water_Pipe_Corrosion.jpg; http://www.cee.vt.edu/ewr/environmental/teach/wtprimer/corrosion/corrosion.html
28
Corrosive Water: Metals of concern

Lead
◦ Many serious health effects, especially in children and infants
 Developmental, neurological, reproductive and renal
◦ EPA MCL is 0 mg/L with a health action level of 0.015 mg/L.
◦ Sources include:
 Pipes in older homes (pre-1930)
 Solder in homes built prior to 1986
 “Lead-free” brass fixtures (<8%) – even in NEW homes!

Copper
◦ High levels can cause nausea, vomiting, stomach cramps; infants and
children particularly sensitive
◦ EPA MCL is 1.3 mg/L
◦ Nuisance effects noticeable at 1.0 mg/L
http://www.gravitaexim.com/images/Lead-pipe.jpg
29
Addressing Lead or Copper in Water

Options to consider:
◦ Discuss test results with your physician if concerned!
◦ Metals will be highest with corrosive water and contact time with
pipes. Flushing pipes may address problem. Make sure that
water runs until it is as cold as it gets before drinking
◦ Activated carbon filter (e.g. Brita)
 MAKE SURE IT IS LABELED TO REMOVE LEAD
 MAKE SURE TO CHANGE AS DIRECTED
◦ Address corrosivity of water – if pH < 6.5, can use acid
neutralizing filter; however, corrosivity can be caused by other
factors as well
◦ Reverse Osmosis
◦ Use another source of water known to be safe
30
http://wi.water.usgs.gov/pubs/FS-221-95/p2.gif
Nitrate (NO3-N)

Serious health concern for infants
◦ Methemoglobinemia or “blue baby syndrome”
 Nitrate  nitrite during digestion and blood cannot carry oxygen
◦ MCL 10 mg/L NO3-N or 45 mg/L of NO3
 If 3-5 mg/L, use do not use water for infants under 6 months

Sources include fertilizer, animal manure, sewage

NO3 dissolves and moves easily through soil

Test in spring months; levels change over time

BOILING INCREASES concentration of nitrates!!!

Treatment: distillation, reverse osmosis, ion exchange
31
/www.cotrip.org/winterdriving/images/pic6.jpg; /www.apswater.com/images/fleck%205600.jpg
Sodium

Low levels occur naturally; high levels may
be from man-made source
◦ Road salt storage or application
◦ Industrial waste
◦ Sewage, fertilizers or animal waste
◦ WATER SOFTENER

Sodium: EPA MCL for people on low-sodium diets: 20 mg/L

Consider other sources of salt in diet and discuss with Dr.

Higher levels may indicate contamination – test for bacteria
or other contaminants

Salty taste; and may accelerate corrosion of pipes and water
heaters

Treat using distillation, reverse osmosis, demineralization
32
Total Dissolved Solids (TDS)

Water is a great solvent – dissolves many compounds
as it travels over and under ground

TDS is a measure of all dissolved impurities

Natural sources: limestone, salt deposits, other minerals

Man-made sources:
◦ Septic systems and sewage
◦ Run off from agricultural or urban land
◦ Road salt, industrial sources

General indicator of water quality;
test at least every three years

EPA SMCL is 500 mg/L

Treat using distillation or reverse osmosis
http://en.wikipedia.org/wiki/Total_dissolved_solids
33
http://www.freedrinkingwater.com/images-water-quality/chemicals/water%20in%20reddish-brown.jpg
Iron and Manganese

Nuisance - not health concern

SMCL: Iron = 0.3 mg/L
Manganese = 0.05 mg/L

Red-brown/black staining, particles,
metallic taste

Treatment depends on type/form of iron
◦ Ferrous: water initially clear  orange-brown
or black solid particles
◦ Ferric: solid particles apparent immediately,
or water has a tint
◦ Iron bacteria: not a health concern; feed on Fe and Mn,
forming red-brown or black-brown slime

Treatment: water softener, aeration and filtration,
ozonation, distillation
34
Nuisance problems
http://www.process-controls.com/techsales/Dynamic_Descaler/images/before_1.jpg, www.tamhil.com/english/content.asp?id=24
35
Nuisance problems
Photo credits: www.ehrenner.com/Chloronation.html, www.bookofjoe.com/2006/01/13/index.html, cleanwellwater.com/acidic_water_bluegreen_stains
36
Nuisance problems
Photo credits: Midland Corrosion Associates, www.awqinc.com/ph.html, www.ehrenner.com/Chloronation.html,
http://www.copper.org/applications/plumbing/techcorner/images/erosion_corrosion.jpg
37
What do you recall about…..

Iron and manganese

Bacteria

Hardness

Corrosive and Scaling Water

Metals

Nitrate

Sodium

TDS

Fluoride
38
Virginia Master Well Owner
Network Training Workshop
New opportunity for
private water supply users!
Visit www.wellwater.bse.vt.edu
today to find out more and complete an
application
or contact Erin Ling
[email protected]
540-231-9058
39
Erin Ling
([email protected])
Virginia Household Water Quality Program
Virginia Master Well Owner Network
Brian Benham
([email protected])
www.wellwater.bse.vt.edu
Email: [email protected]
Ph: 540-231-9058
40
Resources

Virginia Household Water Quality Program
www.wellwater.bse.vt.edu

Virginia Certified Lab Listing:
http://www.wellwater.bse.vt.edu/files/lablist2010.pdf

EPA Private Wells Site
http://www.epa.gov/ogwdw/privatewells/whatyoucando.html

National Groundwater Association Well Owner
http://www.wellowner.org/

Water Systems Council Wellcare Hotline
http://www.wellcarehotline.org/

National Sanitation Foundation: www.nsf.org

Water Quality Association: www.wqa.org

Consumer Reports or Better Business Bureau
www.consumerreports.org OR www.bbb.org
41
End of slide show. Additional slides
follow if you wish to add them.
42
www.goodcleanwater.com/fyi.htm; www.watersoftening.org/effects_of_hard_water.htm;
Hardness/Scaling

Hard water contains high levels of
calcium and magnesium ions
◦ Dissolved into water during contact with
limestone and other minerals

Not a health risk – nuisance
◦ Decreased cleaning action of soaps, detergents
◦ Scale build-up in pipes and on appliances
◦ Reduced efficiency and lifespan of water heaters

No EPA standard for public systems

Treat using water softener
Hardness Rating
Grains per Gallon
mg/L
Soft
Less than 1.0
Less than 17.1
Slightly-Moderately Hard
1.0-7.0
17.1-120
Hard
7.0-10.5
120-180
Very Hard
Over 10.5
Over 180
43
Fluoride

Occurs naturally in varying levels
◦ Naturally high levels of F in E. Virginia groundwater

Added to many public water systems for reduced
dental caries and strong teeth and bones

Health concerns:
◦ Long term exposure: links to bone cancer
◦ Shorter term exposure: dental or skeletal fluorosis

EPA MCL 4.0 mg/L and SMCL 2.0 mg/L

Optimum levels for public systems 0.8 - 1.2 mg/L

Limited use for children up to 8 years

Treatment (reverse osmosis) removes ALL fluoride
http://www.willamettedental.com/en_us/ALL/patients/pps/retailproducts_prettysmile.gif; http://en.wikipedia.org/wiki/Dental_fluorosis
44
Arsenic

Occurs naturally in some rocks; more common in
groundwater supplies when water tables rise and fall
frequently

Used in wood preservatives, paints, pesticides, etc.

Linked to many types of cancer, stomach pain,
paralysis, and blindness

EPA primary standard is 0.010 mg/L

Reverse osmosis to remove
45
Treatment Options
Primary Problem
Treatment Method
Notes
Corrosive water, copper,
lead, leaks
Acid neutralization
Uses limestone chips or soda
ash to increase water pH and
hardness to prevent corrosion
Arsenic, fluoride
Activated alumina
Water pH must be less than
8.5 Pretreatment with
oxidation may be necessary to
achieve good arsenic removal
Hydrogen sulfide,
methane, volatile
organics, radon
Aeration
Expensive and susceptible to
cogging by other pollutants but
very effective when multiple
gases are present
Sulfate, nitrate, arsenic
Anion exchange
Increases chloride
concentration in treated water.
May make water more
corrosive.
Chlorine, pesticides,
Carbon filter
herbicides, radon,
miscellaneous tastes and
odors, volatile organics
Disinfection should be used
on water supplies with
bacterial contamination
because bacteria can multiply
in filter. Carbon must be
replaced periodically.
Adapted from Tips for Buying Water Treatment Equipment by Stephanie Clemens and Bryan Swistock, Penn State University
46
Treatment Options
Primary Problem
Treatment Method Notes
Bacteria, iron and
manganese
Chlorination
Water must be clear for chlorine
to work. Requires tank for
storage and contact time.
Removes everything
except volatile organics,
pesticides, herbicides
Distillation
Produces small amounts of
bland-tasting water. Space
needed to store treated water.
Iron, manganese,
hydrogen sulfide
Oxidizing filters
Periodic addition of chemicals
and backwashing is necessary.
Good option when all three are
present.
Bacteria, metals, odors,
tastes
Ozone
Expensive to purchase and
operate but very effective at
removing multiple pollutants.
All dissolved pollutants
Reverse osmosis
Produces small amounts of water
and some waste water. Will not
remove most organic pollutants
or bacteria
Adapted from Tips for Buying Water Treatment Equipment by Stephanie Clemens and Bryan Swistock, Penn State University
47
Treatment Options
Primary Problem
Treatment Method Notes
Soil, sand, other particles Sediment filter
Must be routinely changed or
backwashed
Removes scale or
Softener
hardness and limited
amounts of dissolved iron
and manganese
Causes increase in water sodium
level. Water may become more
corrosive after softening.
Bacteria
Water must be free of sediment
to kill bacteria effectively.
Change bulb annually.
Ultraviolet light
Adapted from Tips for Buying Water Treatment Equipment by Stephanie Clemens and Bryan Swistock, Penn State University
48