or carbonated zone and can cause a

or carbonated zone and can cause a reduction in bond
strength at the bond interface.
Careful attention should be paid to surface preparation and
drying times of MPC if impermeable membranes are applied
over it. The MPC and membrane manufacturers should be
contacted for detailed recommendations.
Because of the small interval between initial and final
setting times, MPC generally is not hard troweled.
The field technician does not have the flexibility of
varying the water content, and therefore, MPC cannot be
placed in a dry-pack consistency. The mixing water typically
has a tolerance of only ±10%. Any variation of the water
content from that specified by the manufacturer reduces both
the strength and the durability of the MPC mortar.
The neat or extended magnesium phosphate mortar
develops a very rapid exothermic reaction that can produce
relatively high temperatures. The mortar should not be
placed at temperatures above 27 °C (80 °F) or in the sunlight
within the temperature ranges of 15 to 27 °C (60 to 80 °F).
Hot weather formulas are available for use in warm ambient
conditions. The manufacturer should be consulted when
placing the material in thickness greater than 100 mm (4 in.)
or in insulated cavities where the heat generated cannot
escape. Extending the mixture with aggregates or cool water
can slow down the exothermic reaction.
In a hardened state, MPC quickly produces high strength
and high modulus of elasticity. Therefore, it is not flexible
and does not have the toughness that is typically found with
organic-modified mortars and is susceptible to fracturing
from impact loads.
With the normal setting formulations of MPC, high heat
peaks are encountered. With sustained exposure to temperatures
in excess of 80 °C (180 °F) in service, strength reductions
can develop, but its compressive strength can be expected to
exceed that of normal concrete.
c) Applications—Patching applications are the most
common use of MPC, and are cost effective for rapid repairs
where a short down time is important. Common uses are in
highway, bridge deck, airport, tunnel, and industrial repairs.
Repairs in a cold-weather environment are important
applications. Due to the exothermic nature of the reaction,
heating the materials and the substrates is not usually
necessary, unless the temperature is below freezing. MPC is
useful for cold-weather embedments and anchoring because
of its high bond strength and low shrinkage rate.
d) Standards—Currently, no standards are available for MPC.
3.2.10 Preplaced-aggregate concrete—Preplaced-aggregate
concrete is produced by placing coarse aggregate in a form
and later injecting a portland cement-sand grout, usually
with admixtures or a resinous material, to fill the voids.
Preplaced-aggregate concrete differs from conventional
concrete in that it contains a higher percentage of coarse
aggregate. ACI 304R and ACI 304.1R gives guidance on
mixing and placing preplaced-aggregate concrete.
a) Advantages—Because of the point-to-point contact of
the coarse aggregate, drying shrinkage of preplaced-aggregate
concrete is approximately 1/2 that of conventional concrete.
Because the aggregate is preplaced and the grout pumped