Moisture Testing of Concrete Walls and Floors Kenneth A. Trimber KTA-Tator, Inc. Inspection of Cleaning and Painting Webinar Learning Objectives • Identify the ASTM test methods,

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Transcript Moisture Testing of Concrete Walls and Floors Kenneth A. Trimber KTA-Tator, Inc. Inspection of Cleaning and Painting Webinar Learning Objectives • Identify the ASTM test methods, 

Moisture Testing of Concrete Walls
and Floors
Kenneth A. Trimber
KTA-Tator, Inc.
Inspection of Cleaning and Painting
Webinar Learning Objectives
• Identify the ASTM test
methods, instrumentation, and
procedures used for
determining the moisture
content of concrete floors and
walls
• Define the challenges the
industry is facing when
assessing moisture content,
especially on walls
• Describe what SSPC is doing
to address the challenges
Sources of Moisture
•
•
•
•
•
•
•
Construction practices/curing
Ground water
Joints and leaks
Condensation in wall cavity
Wind-driven rain
Pressure washing
Recognition of sources helps to determine test locations
3
Effect of Entrapped Moisture on
Coating Performance
• Reduced
Adhesion
• Poor Film
Integrity
• Efflorescence
• Blistering
• Peeling
4
Standards for Moisture Testing
• Test methods for
determining
moisture content in
concrete are
published by ASTM
Moisture Detection
• Part 1 – Concrete Floors
• Part 2 – Concrete/CMU/Brick Walls
6
Part 1 - Moisture Detection
Concrete Floors
7
Measuring Moisture Content –
ASTM Standards for Concrete Floors
•
ASTM F1869-11, Standard Test Method for Measuring Moisture Vapor Emission
•
ASTM F2170-11, Standard Test Method for Determining Relative Humidity in
•
ASTM F2420-05(11), Standard Test Method for Determining Relative Humidity on
•
ASTM D4263-83 (2005), Standard Test Method for Indicating Moisture in Concrete
•
ASTM F2659-10, Standard Guide for Preliminary Evaluation of Comparative
•
ASTM F710-08, Preparing Concrete Flooring to Receive Resilient Flooring
Rate of Concrete Subfloor Using Anhydrous Calcium Chloride
Concrete Floor Slabs Using in situ Probes
the Surface of Concrete Floor Slabs Using Relative Humidity Probe Measurement and
Insulated Hood
by the Plastic Sheet Method
Moisture Condition of Concrete, Gypsum Cement and Other Floor Slabs and Screeds
Using Non-Destructive Electronic Moisture Meter
8
Anhydrous Calcium Chloride (Floors)
•
ASTM F1869-11, Standard Test Method for Measuring Moisture Vapor
•
Expose known area of bare
concrete to known weight of
anhydrous calcium chloride for
60 to 72 hours
Reweigh the anhydrous calcium
chloride after exposure
Weight gain is converted to
moisture vapor emission rate
(MVER) expressed as:
lbs moisture/1000 ft²/24 hours
•
•
Emission Rate of Concrete Subfloor Using Anhydrous Calcium Chloride
9
Anhydrous Calcium Chloride
Testing (con’t)
• Space should be at same
temperature and RH as
expected during normal use
• If not possible, maintain 75° F
± 10°F and 50% ± 10%
relative humidity for 48 hours
prior to and during testing
• Exception – when service
environment involves
temperature or RH extremes
(cold storage room) – use the
above conditions
10
Anhydrous Calcium Chloride
Testing (con’t)
• All coatings, existing flooring
completely removed to bare
concrete in a 20”x20” area
• Surface roughened by grinding
to create a slight profile equal
to ICRI CSP1 to CSP2 (added
2011)
• Remove all dust
• If floor coverings or coatings
are removed, need to wait for
24 hours before initiating
testing
11
Anhydrous Calcium Chloride
Testing (con’t)
• Weigh the sealed container of
anhydrous calcium chloride
• Remove the lid from the container and
center under the dome supplied with
the kit – save the blue sealing tape
• Firmly seal the perimeter of the dome
to the floor
• Leave to calcium chloride in place
under the dome for 60 to 72 hours
• Remove the container, replace the lid,
reattach the tape and reweigh to 0.1
gram (lab or field – use same scale)
• Use the formula to determine MVER
12
Anhydrous Calcium Chloride
Testing (con’t)
• Test Frequency
– 3 locations for the first 1,000
square feet
– 1 location for each additional
1,000 square feet or fraction
thereof
• Acceptance Criteria
– ASTM F710, Standard Practice
for Preparing Concrete Floors
to Receive Resilient Flooring
recommends a maximum of 3
lb/1,000 ft²/24 hours in the
absence of manufacturer’s
guidelines.
13
Testing with Relative Humidity
Probes - Floors
•
ASTM F2170-11, Standard Test
•
Small holes are drilled into
the concrete
Sleeves are inserted into the holes
and capped
An RH probe (different
styles are available depending
on the manufacturer) is
placed into the hole to
obtain a direct reading of the
relative humidity
•
•
Method for Determining Relative
Humidity in Concrete Floor Slabs
Using in situ Probes
14
Testing with Relative Humidity
Probes (con’t)
• Slab and occupied air space
above the floor at service
temperature and RH for at least
48 hrs prior to testing
• Drill holes for RH probes
• Hole depth depends on
percentage of slab thickness:
– If drying from top (e.g., on
grade) – 40% of total
thickness (1 ½” for 4” slab)
– If drying from both top and
bottom (e.g., elevated
reinforced slab) – 20% of total
thickness (3/4” for 4” slab)
• Remove dust by vacuuming
15
Testing with Relative Humidity
Probes (con’t)
• A sleeve is installed into
the hole
• Some manufactures also
insert a sensor probe at
the same time
• The sleeve is capped off
for 72 hours to achieve
equilibrium
16
Testing with Relative Humidity
Probes (con’t)
• After the stabilization
period, the RH is
measured
17
Testing with Relative Humidity
Probes (con’t)
• Test Frequency
– 3 locations for the first 1,000
square feet
– 1 location for each additional
1,000 square feet or fraction
thereof
– On-grade and below-grade
slabs – 1 location within 3 feet
of each exterior wall
• Acceptance Criteria
– ASTM F710-08 (Preparing
Concrete Floors to Receive
Resilient Flooring suggests max
75%
– Finnish and Swedish standards
range from 60% to 90%
depending on type of covering
18
Relative Humidity of Air Immediately
Above the Floor
•
ASTM F2420-05(11), Standard
•
Insulated hood is used to create an
air pocket immediately above the
surface of the concrete – the RH
within the air pocket is measured by
inserting the probe of an RH meter
into the hood
Test Method for Determining
Relative Humidity on the Surface of
Concrete Floor Slabs Using Relative
Humidity Probe Measurement and
Insulated Hood
19
Relative Humidity of Air Immediately
Above the Floor(con’t)
•
•
•
•
•
Hood constructed from rigid
thermal insulation with a recessed
pocket
Hood lined with vapor-barrier
material to isolate the pocket from
ambient conditions outside of the
hood – must have no permeability
Surface area of air chamber -30 to
40 square inches with a minimum
chamber depth of 0.25 inches
Seal to surface with preformed
sealant adhesive
(photo from ASTM standard)
20
Relative Humidity of Air Immediately
Above the Floor (con’t)
• Slab and occupied air space above the floor at service temperature
and RH for at least 48 hrs prior to installing hood
• If not possible, maintain 75° F ± 10°F and 50% ± 10% relative
humidity during testing
• Concrete must be clean and free of coatings, adhesive, and other
material
• If coverings removed for the test, floor must be exposed to the
above conditions for 24 hours before installing the hood
• Hood must be completely sealed and remain in place a minimum
72 hours before inserting probe to measure air temperature and
RH
• Measure ambient temperature, RH, and dew point outside of the
hood
21
Relative Humidity of Air Immediately
Above the Floor (con’t)
• Test Frequency
– 3 locations for the first 1,000
square feet
– 1 location for each additional
1,000 square feet or fraction
thereof
– On-grade and below-grade
slabs – test locations must
include center of the floor
and close to exterior walls
• Acceptance Criteria
– None in ASTM
22
Common Test Requirements Calcium Chloride, RH probes, RH hood
• Ambient Conditions
– As expected in normal use (RH probe/hood – for 48 hrs in advance)
– If not possible, 75 ± 10°F; 50 ± 10% RH – for 48 hours in advance
– If coverings removed, for calcium chloride and RH hood, wait 24 hours
• Test Frequency
– 3 locations for the first 1,000 square feet
– 1 location for each additional 1,000 square feet or fraction thereof
– RH probe – test within 3 feet of each wall; RH hood – also in center
• Test Duration
– 60 to 72 hours (calcium chloride); 72 hours prior to testing (RH probe
and RH hood)
23
Plastic Sheet Test - Floors
•
ASTM D4263-83 (2005), Standard
•
The perimeter of an 18” x 18” plastic
sheet is firmly taped to the surface
Testing conducted when surface
temperature and ambient conditions
are within the specified limits for the
coating system
Test sites – out of direct sunlight or
direct heat
•
•
Test Method for Indicating Moisture
in Concrete by the Plastic Sheet
Method
24
Plastic Sheet Test - Floors (con’t)
•
•
•
•
After a minimum of 16 hours,
examine the concrete and backside
of the plastic for signs of moisture
Test Frequency – 1 location per 500
square feet of floor area, or portion
thereof
Acceptance Criteria – not stated in
the standard, but coatings typically
not applied if moisture is visibly
present
ASTM F710 Standard Practice for
Preparing Concrete Floors to Receive
Resilient Flooring describes a
procedure that combines the use of
moisture meters and the
polyethylene sheet test
25
Electronic Moisture Meters - Floors
•
•
•
ASTM F2659-10, Standard Guide for
Preliminary Evaluation of Comparative
Moisture Condition of Concrete, Gypsum
Cement and Other Floor Slabs and
Screeds Using Non-Destructive Electronic
Moisture Meter
Relative moisture content of the concrete
½ to 1 inch depth beneath the
instrument
Electrical Impedance
26
Electronic Moisture Meters (con’t)
• Slab and occupied air space above the floor at service temperature
and RH for at least 48 hrs prior to testing
• If not possible, maintain 75° F ± 10°F and 50% ± 10% relative
humidity
• Concrete must be clean and free of coatings, adhesive, and other
material
• If coverings removed for the test, floor must be exposed to the
above conditions for 24 hours prior to testing
• Measure surface temperature within 8 inches of the test locations,
and the ambient temperature, RH, and dew point temperature in
the vicinity of the test areas
27
Electronic Moisture Meters (con’t)
• Test Frequency (ASTM F2659)
– 8 locations for the first 1,000
square feet
– 5 locations for each additional
1,000 square feet
– 1 location within 3 feet of each
exterior wall
– Each location 1 ft²
– 3 to 5 instrument readings per
location – record highest
• Acceptance Criteria
– None in ASTM
28
Electronic Moisture Meters (con’t)
• ASTM F710-08, Preparing Concrete
Floors to Receive Resilient Flooring
– Addresses many considerations prior to
installing resilient flooring, including moisture
(anhydrous calcium chloride and RH probes
and acceptance criteria)
– Appendix X2.5 addresses the electrical
impedance test (discussed above in ASTM
F2659-10)
– Appendix X2.4 discusses electrical resistance
test
• Electrodes placed on surface, or into 2
pre-drilled holes, 1” deep
• Manufacturer may recommend inserting
concrete nails into the holes and
touching the electrode to the ends of the
nails
29
Measuring Moisture Content –
ASTM Standards for Concrete Floors
•
ASTM F1869-11, Standard Test Method for Measuring Moisture
•
ASTM F2170-11, Standard Test Method for Determining Relative
•
ASTM F2420-05(11), Standard Test Method for Determining
•
ASTM D4263-83 (2005), Standard Test Method for Indicating
•
ASTM F2659-10, Standard Guide for Preliminary Evaluation of
•
ASTM F710-08, Preparing Concrete Flooring to Receive Resilient
Vapor Emission Rate of Concrete Subfloor Using Anhydrous Calcium
Chloride
Humidity in Concrete Floor Slabs Using in situ Probes
Relative Humidity on the Surface of Concrete Floor Slabs Using
Relative Humidity Probe Measurement and Insulated Hood
Moisture in Concrete by the Plastic Sheet Method
Comparative Moisture Condition of Concrete, Gypsum Cement and
Other Floor Slabs and Screeds Using Non-Destructive Electronic
Moisture Meter
Flooring
30
Part 2 - Measuring Moisture Content –
Concrete Walls
• The only ASTM standard
available is the plastic sheet test
• Electronic instruments are used
on walls, but there no ASTM
standards addressing them
31
Measuring Moisture Content –
Plastic Sheet Test - Walls
• ASTM D4263-83 (2005),
Standard Test Method for
Indicating Moisture in Concrete
by the Plastic Sheet Method
• Same procedure as described
for floors
• Frequency is 1 location per 500
ft² of wall area or portion
thereof, with a minimum of 1
test for each 10 feet of vertical
rise in elevation, starting within
1 foot above the ground
32
Electronic Moisture Meters – Walls
Industry Guidance is Needed
• ASTM standards are not available to address moisture testing of
walls with electronic instruments.
• Guidance is needed to address available instrument options and
how they operate, accuracy of readings through existing
coatings and on textured surfaces, advantages/disadvantages of
each type
33
Electronic Moisture Meters – Walls
Industry Guidance is Needed (con’t)
• Pre-test conditioning
requirements
• Effects of weather
(recent rain events) and
direct sunlight or shade
on the results
• Conditions can not be
controlled as is the case
with floors
34
Electronic Moisture Meters – Walls
Industry Guidance is Needed (con’t)
• Selecting Test Surfaces:
–
–
–
–
–
Block or brick face
Textured or smooth
Mortar joints
Grouted cells
Bond beams
35
Electronic Moisture Meters – Walls
Industry Guidance is Needed (con’t)
• Test locations and
frequency – number and
location of readings
needed to properly
characterize the moisture
content
36
Electronic Moisture Meters – Walls
Industry Guidance is Needed (con’t)
• Test locations and
frequency when pressure
washing for painting –
when is the surface dry
enough – could be hours
or days
• Compare post-wash
readings with pre-wash
readings – identical
locations
37
Electronic Moisture Meters – Walls
Industry Guidance is Needed (con’t)
• Testing Insulation
– Criteria for testing
insulation board from
interior of building
– How to determine the
presence of damp core
fill insulation
38
Additional Challenges – Walls and Floors
Interpretation of Results
• Instruments and methods assess
moisture at different locations
within the substrate (surface,
various depths, entire thickness)
• Instruments and methods do not
always lead to the same
conclusions regarding percent
moisture or relative humidity
(results are difficult to compare)
39
Additional Challenges – Walls and Floors
Interpretation of Results(con’t)
•
Instruments and methods
determine the presence of
moisture differently:
–
–
Percent Moisture (liquid water)
Relative Humidity (water vapor)
•
75 to 80% RH equates to a
moisture content of ~2%
•
CCAA* indicates that concrete
can be nearly saturated with
water and still only register a
moisture content of ~5%
*Source: Moisture in Concrete and
Moisture-Sensitive Finishes and
Coatings, published by Cement
Concrete & Aggregates Australia
(CCAA)
40
SSPC Response to Industry Need for
Concrete Moisture Testing Standards
A newly formed SSPC
Commercial Coating
Committee is developing
guides to address moisture
testing of concrete walls,
equipment used, test
locations and test
frequencies, and the
interpretation of the results
41
Concrete Moisture Testing Summary
•
•
•
•
The surface should be examined
for unacceptable levels of moisture prior
to painting. Sources of moisture include
construction activities, leaks and ground
water, condensation inside the wall, and
pressure washing for painting
ASTM methods are available for moisture
testing of floors, but not walls
It is difficult to interpret and compare
results between the methods, and
conclusions may differ between methods
SSPC is working to fill the void for
standardization by developing a guidance
document to address test instruments,
test locations, test frequency, and
interpretation of results
Moisture Testing of
Concrete Walls and Floors
Questions?