Abstract:
ABSTRACT
The problems associated with increasing strength of concrete are the focus of
a wide area of research. High and ultra-high strength concrete tends to develop
early cracking. The lower the w/b the earlier and greater the development of
autogenous shrinkage which increases with increasing compressive strength.
This leads to internal cracking and weakening the performance of concrete.
Providing the means of internal curing to solve the problem of autogenous
shrinkage related to high and ultra- high strength concrete is limited to light
weight aggregate LWA. Recently, the Super Absorbent Polymer SAP, which
is considered to be smart materials that can hold and absorb water effectively
and release it when needed in dry conditions, has been used for this purpose.
This study comprises two stages. The first stage includes the production of
five concrete mixes with different strength levels (normal, high, very high and
ultra-high strength). These are: reactive powder concrete RPC, modified
reactive powder concrete MRPC, high strength concrete HSC, self- compact
concrete SCC and normal strength concrete NSC. The properties of concrete
in the fresh and hardened state are studied for the five concrete mixes with and
without SAP addition. These properties include: workability for fresh
concrete, compressive strength, (splitting and flexural) tensile strength,
modulus of elasticity, autogenous and drying shrinkage. The second stage
IV
covers the effect of SAP addition on flexure behaviour of the reinforced
concrete beam. Ten beams are casted, five for concrete mixes without SAP
and the other five beams with SAP addition. Load carrying capacity,
deflection and crack width has been investigated.
The results collected from the first stage reveal that the addition of SAP
increases workability for mixes due to increased quantity of water in the mix.
Addition of SAP reduces strength of concrete in term of compressive,
splitting, flexural as well as modulus of elasticity up to 28 days. After 28 days,
clear improve in compressive strength was recorded which belong to
continuous hydration process due to availability of water from internal curing
(with the addition of SAP) which promotes continuous development in
compressive strength clearly at the age of 56 days. It is expected to gain more
strength at ages after 56 days. SAP addition is found to reduce autogenous and
drying shrinkage remarkably; for autogenous shrinkage the reduction is (64%,
46%, 42%, 62%, and 54%) and drying shrinkage reduction was (89.5%, 72%,
82%, 70% and 71%) for RPC, MRPC, HSC, SCC and NSC respectively.
Results of the second stage reveal that the addition of SAP increases load
carrying capacity for reinforced concrete beams of all types of concrete.
Moreover, the deflection of the reinforced concrete beams containing SAP is
reduced compared with reinforced concrete beams without SAP. The
reduction in deflection is (9.4%, 8%, 20%, 23% and 12%) for RPC, MRPC,
HSC, SCC and NSC respectively. The same results are attained for crack
width which is improved due to SAP addition, the reduction is (12.5%, 11.8%,
13.7%, 13.3%, and 20%) for RPC, MRPC, HSC, SCC and NSC beams
respectively. It can be concluded that it is possible to use SAP as internal
curing agent in order to improve properties of concrete in general on the long
term as it takes time in order to release water to maintain hydrations.