Yahya Ghasemi Print III pdf

21
Mix design approaches
3.3.1. Particle-matrix model
The workability of concrete is governed by the inherent properties of the constituents, 
proportioning and the way the constituents are interacting with each other physically and 
chemically. Particle-matrix model (PMM) considers concretes in two separate phases, fluid 
material and a friction material. Based on this logic the matrix is considered as all of the 
particles less than 0.125 mm including cement, fines and possible chemical additives while
particle phase is defined as all of the particles larger than 0.125 mm. The model is particularly 
suitable for mixes where matrix phase is dominant e.g. self-compacting and high performance 
concrete (Smeplass and Mortsell, 2001; Reknes, 2001). 
The main difficulty here is to define the properties of the phases and to model the effect of 
these phases on each other. The basic concept of the model is shown in Figure 3.5. 
The approach relies on single parameter characterization of each phase (Mortsell et al., 1996) 
(Samarakoon et al., 2015): 
-
The flow resistance ratio of the matrix
-
The air voids modulus of the particles
Amount of matrix
Particle properties Matrix properties 
Figure 3.5. Particle matrix model concept for concrete (Bartos et al, 2004) 
3.3.1.2. The flow resistance ratio
The flow resistance ratio is calculated based on the results obtained from a modification of 
Marsh cone test called FlowCyl. The apparatus consist of a vertical cylindrical steel tube with 
a bottom outlet formed as a cone ending in a narrow nozzle and an electronic scale connected 
to a data logger where the flow properties of the material are characterized by the 
accumulated flow through the nozzle. The flow resistance ratio represents the difference in 
accumulation flow between the test material and an ideal fluid flowing through the FlowCyl 
and is defined as the ratio between the area under the loss curve (F
t
) and the area under the 
curve for the ideal fluid without any loss (F
i
) (Mortsell et al., 1996). see Figure 3.6. It should 
be mentioned that an ideal fluid is defined as an uncompressible nonviscous liquid which does 
Workability

22
Mix design approaches
not actually exist in nature and is commonly used for fluid flow problems (Landau and 
Lifshitz, 1987). 
Figure 3.6. Typical FlowCyl data for a matrix showing curves for an ideal fluid, measured points for 
actual matrix and calculated curve for loss. (Mortsell et al., 1996)
The flow resistance ratio can be calculated based on the following equations:
ߣ
ொ
=
ܨ
௧
ܨ
௜
(3.18) 
ߣ
ொ
=
݇
(
݇
௖
ܿ
ݓ
+
݇
௦
ݏ
ܿ
+
݇
௙
݂
ܿ
)
௡
(3.19)
where k, k
c
, k
s
, k
f
and 
n
are constants found by regression analysis of test data, c/w is cement 
water ratio by weight, s/c is silica fume to cement ratio by weight and f/c is filler to cement 
ratio by weight.

Download 3,95 Mb.

Do'stlaringiz bilan baham: