Inorganic Polymer Concrete-A Review

Kailiang Shi

1,*,a

School of Civil Engineering and Architecture,WuHan Universityof Technology, LuoShi Road 122, WuHan, China

*Corresponding author

：

TEL +86 15527357058

Keywords: Inorganic polymers; concrete; alkali-activated; physical and mechanical properties.

Abstract: The physical and mechanical properties of IPC (inorganic polymer concrete) and its influencing factors are

introduced on the basis of references to domestic and foreign papers. Moreover, the paper made a forecast

of IPC’s application prospects. Integrated with the various physical and mechanical properties and

environmental performance of IPC, it is found that inorganic polymer concrete has very important

application value, which is of great significance for developing countries with energy shortage.

1 INTRODUCTION

The IPCis high performance concrete. Its

Cementitious materials are aluminum silicate

minerals or industrial waste (such as fly ash, slag,

etc.), which are mixed into the sodium silicateand

sodium hydroxide composite alkali activator. IPC

has many advantages such as corrosion resistance[7],

high strength, good impermeability and frost

resistance. The use of industrial waste such as fly

ash can not only reduce cement consumption and

carbon dioxide emissions, but also save energy and

reduce costs. [1]

Data shows that the transport industry and

Portland cement are the two largest producers of

carbon dioxide, which contribute to 7% of the global

carbon dioxide emissions [2]. In addition, the whole

world produces a large number of industrial waste

every year. So it’s a good example of industrial

ecology to substitute Portland cement with fly ash

produced from coal-fired power plants and abrasive

slag produced from iron smelters. Therefore, IPC

becomes new structural material with good

development prospects internationally. At present,

the international research on IPC has been for many

years, [3] mainly covering its performance and

application domain.

2 PHYSICAL MECHANICAL

PROPERTIES

2.1 Durability

The durability of Portland cement concrete is poor

due to the low stability of calcium hydroxide and

other substances produced by Portland cement

hydration.[4]Under the influence of chemical

activator, the depolymerization of -O-Si-O-Al-O-

chains in the vitreous structure of inorganic polymer

cementitious materials produces [Si04]4- and

[Al04]4-, which in turn form new -O-Si-O-Al-O-

grid structure. It’s more stable than the Portland

cement’s hardened body composed of inorganic

small molecule structures such as C-S-H, CH, etc. In

addition to the C-S-H gel, the hydrated product of

IPC also contains a large amount of hardly soluble

zeolite-type minerals. As a result, IPC has excellent

durability.

2.1.1Frost Resistance

Paper [5] studied the frost resistance of slag-based

IPC. The study found that IPC has a frost resistance

rating of F300 or higher and a frost resistance

durability coefficient of 0.9-0.95. It fully meets the

freezing requirements of concrete in cold regions.

The reason for good frost resistance is that there are

relatively few large pores in the IPC structure, it

contributes largely to IPC’s dense structures. At the

same time, IPC has high strength and good

impermeability, it’s not easy for external moisture to

enter and cause damages to the inner structure.

2.1.2 High Temperature Resistance

Wang Qing [6] et al. studied the high temperature

resistance of slag-based IPC at different

temperatures. The study found that the high

temperature performance of IPC is much better than

ordinary Portland cement concrete. Under high

temperature, the IPC has excellent surface

characteristics compared to ordinary silicate

concrete.

At 800 °C, the strength loss of IPC is only 40%,

which is much less than 60% of ordinary Portland

cement concrete.

2.1.3 Anti-penetration

D. Cao [5] et al. studied the impermeability of slag

based IPC. The study found that IPC has

impermeability rating of S40 or more and excellent

resistance to chloride ion penetration which can

effectively prevent the invasion of water, chloride

ions and other erosion media.

Kaituo S[8] et al. studied the resistance of IPC to

chloride penetration when the calcium oxide content

was 10%, 15% and 20% respectively. The study

found that when the chlorine ion content is 20%, the

chloride ion permeability is minimal. The main

reason is that as the content of calcium oxide

increases, the internal polymerization degree of IPC

increases, the internal pores shrink, the concrete

structure becomes denser and the resistance to

chloride ion becomes better.

2.2 Compressive Strength

Abundant researches have demonstrated that IPC

has excellent early strength.

Gang Wang et al. measured that the 3d

compressive strength of the inorganic polymer

reached 39.27 MPa. Mingyu Hu et al. obtained fly

ash IPC with compressive strength of not less than

26 MPa for 28 days. Yuzhu Su et al. made fly ash-

silica fume IPC, its 7d and 28d compressive strength

were measured to be 78.5 MPa and 89.0 MPa,

respectively.

Factors such as concrete mix ratio, raw material

types and curing temperature will also affect the

strength of IPC.

J. Wongpa [9] et al. analyzed the relationship

between compressive strength of IPC specimens

with fly ash/mineral powder = 4, sodium

silicate/sodium hydroxide = 2.5 and S/A

(solution/ash) and P/Agg(paste/aggregate). Elie

Kamseu [10] et al. studied the effect of fine

aggregate types on the compressive strength of IPC.

It can be seen that when the amount of aluminum in

the aggregate is higher, the concrete structure is

denser.AS 3600 [11] proposed that different types of

fly ash and activator composition can also affect the

strength of the IPC. Y. Fu et al. proposed that curing

temperature will affect the compressive strength of

slag IPC.

2.3 Deformation Performance

2.3.1 Modulus of Elasticity

According to the specification [12], the modulus of

elasticity of ordinary Portland cement concrete is

proportional to the square root of the compressive

strength. Research shows that the elastic modulus

and compressive strength of IPC are also closely

related, different scholars have given different

empirical formulas. The specific formulas are shown

in Table 1.

Table 1: IPC relationship formulas between elastic modulus and compressive strength.

paper formula serial number

paper[9] E  1687



𝑓



 16078 (1)

paper [11] E  0.043𝜌

.



𝑓



 20% (2)

paper [13] E  0.024



𝑓



 0.12𝜌

.

(3)

paper [14] E  3320



𝑓





 6900

𝜌

2320



.

(4)

paper [15] E  3.38𝜌

.





𝑓







.

10



(5)

paper [16] E  0.043𝜌

.

𝜂



𝑓



(6)

Notes:



: compressive strength of concrete, in MPa;



: average compressive strength of the cylinder,

in MPa;

ρ: density of IPC, in kg/m3；

η: correction coefficient, η  1.1  0.002f







1.0.

Formula (2) only applies to concrete with

strength less than 40 MPa, and the values obtained

by the formula are the upper and lower limits of the

elastic modulus. Formula (3) is suitable for concrete

with strength greater than 40 MPa. Formula (5) is

closer to AS 3600. Formula (4) is closer to the lower

limit of elastic modulus in formula (2). For high-

strength concrete, the modulus of elasticity obtained

with formula (3) is higher, and formula (6)

introduces parameter η on the basis of AS 3600,

which is an improvement over the normative

formula.

X. Fan [17] measured the elastic modulus of IPC

and OPC (ordinary Portland concrete) with the

strength of 60 MPa. According to the test, the elastic

modulus of IPC is 3.16  10



MPa, which is 11.8%

smaller than that of 3.6  10



MPa of OPC.

2.3.2 Poisson's Ratio

M. Sofi[18] et al. made six IPC specimens with the

strength of 50 MPa and tested their Poisson’s ratios.

Tests have shown that IPC’s Poisson's ratio is

between 0.23-0.26, which is larger than that of

OPC’s 0.11-0.21 [19]. X. Fan [17] measured the

Poisson's ratio of IPC and OPC with a strength class

of 60 MPa. The test found that the Poisson's ratio of

IPC was 0.26, which was 22.2% greater than that of

OPC.

The researches show that the IPC’s elastic

modulus is smaller than that of OPC, while IPC’s

Poisson's ratio is relatively larger, which indicate

that IPC has better deformation performance than

OPC.

2.4 High Temperature Resistance

Due to the unique grid structure of IPC gels, it has

similar properties to ceramic materials and better fire

resistance than ordinary Portland concrete.

Zuda [20] et al.used vermiculite and calcium

carbide as IPC aggregates, resulting in excellent fire

resistance. Vermiculite can increase the internal void

of IPC and tightly bind the cementitious materials

and aggregates through internal voids. Calcium

carbide has very small deformation under high

temperature.Junaid [21] studied the deformation

properties of fly ash-based IPC at high temperatures.

IPC will undergo constant temperature creep and

transient thermal creep in the high temperature

environment.Pan [22] et al. studied the transient

thermal creep of inorganic polymer gels at high

temperatures and compared them with ordinary

concrete. Studies have shown that the transient

thermal creep of inorganic polymer cementitious

materials can contribute to the accommodation of

the uneven deformation caused by inconsistent

deformation of various components, and it’s

beneficial to the high temperature performance of

IPC.

3 HPC APPLICATION AND

OUTLOOK

IPC has high strength and short setting period, so it

has been used in many projects such as rapid road

repairs and dam repairs. Y. Fu et al. used slag and

activator as cementitious materials to deploy rapid

repair IPC that was used in airport pavement repair.

Its slump is over 160mm, its flexural strength and

compressive strength at 4h is 3.03 MPa and 26.19

MPa respectively, which can meet the technical

requirements for road surface repairs of the airport.

Due to the high temperature resistance of IPC,

some scholars have studied the incorporation of

lightweight aggregates into inorganic polymer gels

for rocket diversion tanks and kiln liners.

IPC is resistant to chloride ion permeability and

sulfate corrosion, it can be applied to marine

engineering, such as bridge piers for offshore

bridges, offshore drilling platforms and subsea

tunnels, etc. These considerations have not yet been

formally implemented and the feasibility remains to

be further studied.

4 CONCLUSIONS

Inorganic polymer concrete has very excellent

physical and mechanical properties, and its

outstanding advantages such as fire resistance,

corrosion resistance, frost resistance, high strength

and quick setting make it easy to put into

engineering. Because of its green energy saving

property, IPC has received extensive attention in the

field of concrete research. The cement that will

generate a lot of carbon dioxide in the production

process is replaced with industrial waste such as fly

ash and slag, which meets the concept of sustainable

development. IPC has important research

significance for countries such as China and India,

which are relatively short of energy and need to

build a large number of infrastructure.

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