J. Build. Mater. Struct. (2022) 9: 44-56 Original Article 
DOI : 10.34118/jbms.v9i1.1373  

 

ISSN  2353-0057, EISSN : 2600-6936 

Basalt Powder Waste Application as Affordable Concrete Admixture 

Mbereyaho L*, Niyoyita J B, Kimararungu A, Ntakiyimana D 

 
University of Rwanda, College of Science and Technology. P.O Box: 3900 Kigali, Rwanda. 
* Corresponding Author: lmbereyaho2015@gmail.com  

Received: 06-06-2021 
 

 Accepted: 24-02-2022 

Abstract. Different weather conditions, like temperature and humidity influence on the 
performance of concrete structures to which they are normally subjected, especially at 
earlier stage of their service life. One of practical measures has been the regulation of the 
setting time of fresh concrete. Some admixtures are used in concrete to regulate the setting 
time and therefore increase structures performance under given situation. Almost all 
admixtures used in Rwanda are being imported from outside the country and this is one of 
factors affecting the construction cost. A big quantity of basalt powder at different sites in the 
country is left without being used and has been negatively impacting the environment. This 
study aimed at analyzing the potentials of basalt powder waste used in concrete as 
admixtures in different percentages, e.g. 0%, 5%, 10%, 15% and 20%. Different 
investigations on concrete incorporating basalt powder as admixture, such as the setting 
time, workability and compression tests were conducted. The results showed that the 
gradual incorporation of basalt powder waste as admixture up to 20%, accelerated the 
setting time more than 13 times, but decreased the compressive strength of concrete by 
around 24.5%, with comparison to normal concrete strength. The application of basalt waste 
in concrete would contribute not only to the reduction of environmental pollution but also to 
the provision of more affordable admixtures for mortar and concrete. 

Key words: Admixture, Basalt powder waste, Compressive Strength, Concrete, Setting time, Workability. 

1. Introduction 

The widespread application of concrete in construction of different structures and under 
different conditions has increased the requirement not only in its quantity, but also its high 
quality.  Concrete used should ensure the adequate performance of implemented structures 
under any condition to which they are exposed. Some special conditions, like high temperature, 
humidity, etc require that admixtures are added to the concrete mixture immediately before or 
during mixing in order to regulate its setting time or sustain some desired properties (Kosmatka 
and Wilson, 2011). In Rwanda, those admixtures have been in use especially when the 
concreting is performed during sunny period or under humid conditions. These admixtures are 
usually imported from abroad, and they are still expensive, especially with consideration of 
transportation services cost. In Rwanda basalt waste materials, produced by some construction 
industries, are disposed in the environment, and consequently they have been causing human 
health and sanitation concerns. Till today, this waste has been under use only as aggregates, 
especially in road construction projects, while its great part still remained improperly dumped 
in the environment. The utilization of basaltic waste would become a valuable contribution not 
only for preservation of the environment, but also in offering affordable product, while using 
local materials, and this is the main objective of the study. Among others, some specific 
objectives were identification of ordinarily used admixtures for concrete and their properties, 
survey on the availability of basalt waste in Rwanda, and determination of properties of fresh 
and hard concrete mixed with basaltic powder.      

mailto:lmbereyaho2015@gmail.com


 Mbereyaho et al., J. Build. Mater. Struct. (2022) 9: 44-56 45 

 

 

 Basalt rock has been under use in construction projects all over the world, including Rwanda. 
Also some previous works on the use of basalt waste in cement or concrete are available. Feng 
(2013), using the experimental study on mechanical properties of basalt fiber reinforced 
concrete, he found that the mixture with basalt fiber would efficiently enhance the ductility of 
the concrete and improve the compressive strength and split tensile strength of concrete 
matrices in different ages. He concluded that the compressive strength of concrete in the age of 
3days and the split tensile strength of concrete in the age of 28 days were improved more 
significantly, by 9% and 19% respectively. Dobiszewska and Beycioğlu (2017) used four types of 
common cement which were CEM I, CEM II/A-S, CEM II/A-V and CEM II/B-V for investigating the 
influence of waste basalt powder on selected properties of cement paste and mortar, where they 
established the positive effect on those properties and concluded that the incorporation of waste 
basalt powder into cement mortar as a partial substitution of cement was environmentally 
friendly and economically feasible. In their study about effect of basalt powder on the properties 
of cement composites, while modifying cement mortar by basalt powder in amount of 10, 20 and 
30% by weight of cement, Uneik and Kmecova (2013) realized that basalt powder had a positive 
effect on the consistency of fresh cement composites and the strength of hardened composite. 
The initial and final setting time were prolonged with the increase of the basalt content. During 
their study on effect of basalt powder addition on properties of mortar, Dobiszewska et al. 
(2019) established that the addition of basalt powder as a replacement of cement leads to 
deterioration of compressive strength, while the flexural strength of mortar improved in some 
cases. The study on mortar properties with basalt powder subjected to high temperatures, 
showed that the ratio of basalt powder does not change the strength reduction rate, and that the 
flexural strength performance of mortar mainly depended on fibre type and temperature rather 
than on basalt powder substitution (Akyuncu, 2019). In Rwanda, a study about engineering 
characteristics of volcanic rock aggregates found that they had a very high compressive strength 
and better permeability (Mutabaruka et.al, 2016). 

Dobiszewska and Barnes (2020) carried out an experimental investigation to evaluate the 
potential usage of waste basalt powder in concrete production, where the waste basalt powder, 
replaced 10%, 20%, and 30% sand, and the workability, compressive strength, water transport 
properties, and microstructural performances were evaluated. Among other results, the study 
showed that the compressive strength of concretes could increase up to 25%. Dobiszewska and 
Barnes (2020) investigated on the use of waste basalt powder in mortar when used as a partial 
replacement of fine aggregate and the experiments were performed on mixtures containing up 
to 20% replacement of sand by basalt powder to determine the impact on the compressive and 
flexural strength of mortar as well as on the flow characteristics, density, and porosity. The 
results indicated that use of basalt powder as a partial replacement of sand leads to 
improvement of the compressive strength and flexural strength. The mortar porosity in the 
capillary pore range was reduced. The study on Use of basalt powder in a cementitious mortar 
and concrete as a substitute of sand showed that powder basalt could be used as an effective 
substitute of fine aggregate in cementitious mortar and concrete and this improved some 
properties of cementitious mortar and concrete and enabled for the management of industrial 
waste (Dobiszewska, 2016). Among other results, the experimental study on basic mechanical 
properties of basalt fiber Reinforced concrete established that basalt fiber significantly 
improved the toughness and crack resistance performance of concrete and the improvement 
effect was the highest with the basalt fiber content of 0.3% and 0.4% (Zhou et al, 2020). This 
study is conducted with addition and not replacement of basalt powder in concrete, in order to 
assess its performance as an admixture. 



46 Mbereyaho et al., J. Build. Mater. Struct. (2022) 9: 44-56  

 

 

2. Research Materials and Methods 

2.1. Materials  

2.1.1. Basaltic powder waste 

The basaltic rocks are available in north-western part of Rwanda in the volcanic region 
(Mutabaruka et al., 2016). Many of local industries have been using these rocks in different 
construction activities like road pavement, building construction, where they are crushed and 
used as road base, asphalt pavement, concrete aggregate, etc. For this study, the samples of 
basalt waste powder were taken from the basalt rock crushing plant belonging to one of local 
construction company, NPD COTRACO Ltd located in Musanze district. The Fig.1 shows the used 
basaltic powder sample. 

2.1.2. Cement 

During this study TWIGA cement M32.5 grade was used throughout the whole investigation. The 
Fig. 2 presents the packaged and stored TWIGA cement. 

 

Fig.  1. Basaltic powder              

 

Fig.  2. TWIGA cement 

2.1.3. Coarse and fine aggregates 

The fine and coarse aggregates with the sizes of 4.75mm and 20mm, as well as specific gravity of 
2.61 and 2.655 respectively were extracted from local river. Those materials are shown in Fig.3 
and Fig.4 respectively. 

 

Fig.  3. Fine aggregates 

 

Fig.  4. Coarse aggregates 

2.1.4. Water used 

Clean water was used for mixing and curing of concrete.    



 Mbereyaho et al., J. Build. Mater. Struct. (2022) 9: 44-56 47 

 

 

2.2. Methods  

During the mixing Process, the design mix proportion 1:2:3 for cement, sand and coarse 
aggregate respectively was considered, while the used W/C ratio was 45% of cement. 

2.2.1. Experimental Design and Laboratory Test 

The purpose of this laboratory experiment was the determination of the compressive strength 
using concrete specimen, prepared with incorporation of basaltic powder added as admixture. 
The compressive strength was determined at 28 days of curing on the cubes of 150mm size. 
Other important tests like sieve analysis, setting time and workability of concrete mixed with 
basaltic powder were also checked. Details on these tests are given below, while respective 
results are presented in section 3. 

2.2.2. Sieve analysis of sand 

This test is conducted to determine the distribution of fine aggregate samples using standard 
sieve meshes, and this is one of aspects used to assess the aggregates quality.  

2.2.3. Used apparatus 

Standard sieves of different holes’ diameter in mm, shaking machine, laboratory balance, tray, 
Scoop, time stop watch, and calculator. The ordinary normal procedure was used in order to 
achieve the standard test results.  

2.3.4. Standard consistency test 

The consistency of cement is taken when a vicat plunger is allowed to penetrate, with the 
reading characterized by the standard consistency values in the range between 5-7 mm from the 
bottom or 33-35 mm from the top of mould. Tools used for this test are: vicat with plunger, 
needle, stop watch, glass plate, tray, balance and measuring cylinder (Fig.5). 

               

Fig.  5. Used tools (from left to right: Vicat apparatus with plunger and needle, stop watch and balance) 

2.3.5. The setting time test for cement 

As many constructions projects are subjected to different extreme conditions such as humidity 
or high temperature, the setting time of concrete needs to be checked in order to ensure its 
quality at earlier stage. The setting time of cement paste is presented into two states that are 
initial and final setting. The initial setting is regarded as the time elapsed between the moments 
under which the water is added to cement and the time when the paste starts losing its 
plasticity, while the final setting is regarded as the time elapsed between the moment at which 
the water is added into cement to the moment when the paste has completely lost its plasticity. 

Apparatus used: movable rod with cup, needle, standard vicat mould, needle with hallow 
circular cutting edges of 5mm diameter and weight balance. The standard procedure was used 
for this test as presented below (see also Fig.6). The initial setting time procedure is presented 
below: 



48 Mbereyaho et al., J. Build. Mater. Struct. (2022) 9: 44-56  

 

 

1. Use approximately 300 gram of dry cement with additional of 0.85 p (p=weight of water 
for standard consistency to make paste). 

2. Fill the mould with paste, then fix specific needle to moving rod apparatus. 

3. Release the needle to penetrate cement paste. 

4. Note the time and depth to which the needle penetrates the cement paste. 

5. Repeat the procedure until the penetration will be 34.5-35.5 mm from the top of mould, 
means that it is 5±0.5mm from the bottom of mould. 

6. Plot a curve between time (Minutes) and unpenetrated height in mm. 

7. Find on graph initial setting time when penetration of needle is within 5±0.5mm. 

 

Fig.  6. Initial setting time test 

The procedure used for the final setting time test is the following: 

1. Attach needle with circular cutting edge. 

2. Release the needle slowly  

3. The time when the needle makes impressions on the hardened cement paste is recorded. 

Slump Test: The workability is described as ability of fresh concrete to be easily transported, 
compacted, and placed without any reduction of concrete qualities. The most commonly method 
used to measure the workability of fresh concrete in laboratory or on site is slump test.  

Apparatus: Slump cone (with bottom diameter=200 mm, top diameter=100 mm, and height=300 
mm), weighing balance, tray, standard tamping rod, concrete mixing machine. 

Compression Test: The compressive strength is the one of the most important properties of 
hardened concrete which describes its ability to resist forces. This test is mainly conducted on 
28 days hardened concrete by using compression testing machine and it plays an important role 
in controlling and conforming the quality of concrete.  

Apparatus: cube moulds 150mm size, weighing machine, ramming rods, compression testing 
machine. The Fig. 7 shows the mould and used balance 



 Mbereyaho et al., J. Build. Mater. Struct. (2022) 9: 44-56 49 

 

 

        
Fig.  7. Used cube mould (left) and balance (right) 

3. Results and discussion 

As it was stated in section 2, the conducted experiments are: sieve analysis, consistency, setting 
time, workability and the compressive strength. Established results are presented and discussed 
in this section. 

3.1. Sieve analysis  

Following the procedure presented earlier, established results are presented in Table 1. 

Table 1. Sieve analysis 

Sieve 
size(mm) 

Weight of aggregate 
retained(g) 

% of aggregate 
retained 

Cum % of aggregate 
retained 

% of aggregate 
passing  

4.75 8.33 1.40 1.40 98.60 
2.36 21.62 3.65 5.05 94.45 
1.18 195.38 32.94 37.99 62.01 
0.6 123.81 20.88 58.87 41.13 
0.3 145.14 24.47 83.34 16.66 

0.075 97.56 16.45 99.79 0.21 
pan 1.26 0.21 100.00 0.00 

Total 593.1 100.00 286.44 313.06 

Fineness Modulus=cum % of aggregate retained/100= 286.44/100=2.8644 

From the above table the following can be underlined: 

● The value of fineness modulus indicates that the used aggregates are “fine aggregates” 
because its value is within 2-3.2 standard range of fine aggregate as it is recommended 
by standards 

● The maximum sieve size used is 4.75 mm, and minimum is 0 075 mm and the retained 
aggregates are 1.40% and 16.45% respectively. Referring to IS 383 (Bureau of Indian 
Standards, 2016), it can be concluded that this is a fine aggregate of zone II 

3.2. Standard consistency test 

The consistency test results for normal cement and cement mixed with basaltic powder are 
presented in Table 2 and Table 3, respectively. 

Table 2. Normal consistency of cement 

S/N % of water Initial reading Final reading Height of penetration 

1 20 40 34 6 
2 22 40 11 29 
3 24 40 6 34 

From Table 2, it can be seen that the established consistency of cement was 24% of water, and 
therefore the cement paste was normal (Mishra, 2014). 



50 Mbereyaho et al., J. Build. Mater. Struct. (2022) 9: 44-56  

 

 

Table 3. Normal consistency of cement mixed with 5% basaltic powder 

S/N % of water Initial reading Final reading Height of penetration 
1 20 40 38 2 
2 22 40 35 5 
3 24 40 31 9 
4 26 40 29 11 
5 28 40 16 24 
6 30 40 7 33 

From Table 3, it is noted that the consistency of cement mixed with 5% of basaltic powder was 
30% of water. The same test with 10%, 15% and 20% of basaltic powder showed the similar 
percentage of water.  

3.3. The setting time test results 

3.3.1. Initial setting time test 

Following the recommended procedure the following quantities were used: Mass of cement 
=300gr; Quantity of water=300*30%*0.85=76.50 gr .Test results with 5% of mixed powder are 
presented in Table 4. 

Table 4. Setting time data of cement with 5% of basaltic powder 

S/N 
Time(in 
Minutes) 

Initial reading 
Penetration 
Height 

Remaining Height 

0 0 40 40 0 
1 6.30 40 40 0 
2 13.00 40 39 1 
3 19.30 40 39 1 
4 26.00 40 39 1 
5 32.30 40 38 2 
6 39.00 40 38 2 
7 45.30 40 37 3 
8 52.00 40 36 3 
9 58.30 40 36 4 

10 65.00 40 36 4 
11 71.30 40 36 4 
12 78.00 40 36 4 
13 84.30 40 36 4 
14 91.00 40 36 4 
15 97.30 40 34.5 5.5 

3.3.2. Final setting time 

The Fig. 8 demonstrates the variation of penetrated height in function time. 



 Mbereyaho et al., J. Build. Mater. Struct. (2022) 9: 44-56 51 

 

 

 

Fig.  8. Time versus unpenetrated height 

Hence from chart above   

 Initial setting is 97.30 minutes 

 Final setting is 190 minutes 

The setting time for concrete mixed with and without Basaltic powder is given in Table 5, while 
the respective chart is presented in Fig. 9. 

Table 5. Initial and final setting time of concrete mixed with and without Basaltic powder 

Basaltic in % Water in % Initial setting time in minutes Final setting time in minutes 
0 24 30 600 
5 30 97.30 190.00 

10 30 0-6.30 58.30 
15 30 0-6.30 52.30 
20 30 0-6.30 45.30 

 

Fig.  9. Final setting time 



52 Mbereyaho et al., J. Build. Mater. Struct. (2022) 9: 44-56  

 

 

The results in table 5 and respective Fig.8 show that the initial setting time at 5% basalt cement 
is 97.30 minutes and final setting time 190 minutes. Then with the increase of basalt content, the 
initial and final setting time gradually decreased, and it can be noted that the addition of basalt 
waste up to 20% decreased the sitting time from 600 to 45.30 minutes, giving a setting time 
reduction of more than 13 times. This may be due to the chemical composition of basalt with 
regards to the set accelerators  admixtures (Kosmatka et al., 2008; Myrdal, 2007).The initial 
setting time lay between 0 and 6.30 minutes while final setting time are 48.30, 52.30 and 45.30 
respectively. According to Krishna (2017), the standard initial and final setting time of cement is 
30 and 600 minutes respectively. Therefore this result shows that basaltic powder should be the 
best mineral admixture to be used in humid condition due to its quick setting. 

3.4. Slump Test 

The used concrete mix is 1:1.6:2.7 (W/C=0.45) Ingredients are obtained by weight method. 

The following standard procedure for this test was used: 

1. Prepare apparatus.  

2. Take mix proportion: 1:1.6:2.7 by weight; use Water cement ratio=0.45. 

3. Sampling and measuring the concrete ingredients. 

4. Prepare mixing machine and pouring the sample. 

5. Cleaning internal surface of slump cone. 

6. Fixing slump cone to the base on ground. 

7. Fill the fresh concrete into slump cone in equal three layer and each layers should be 
compacted twenty-five blows. 

8. Level the top of the cone by straight edge. 

9. Remove the slump cone slowly upward and approach the empty slump cone near by the 
compacted concrete  

10. Determine the slump result using gradual rule by measuring the difference between 
concrete and cone. 

11. Obtain the height difference in mm as slump of concrete. 

Slump test results are given in table 6, while respective chart is given in Fig. 10 

Table 6. Observation of slump cone 

S.N Basaltic powder in 
percentage (%) 

Height of slump 
H1(mm) 

Height of subsided 
concrete H1(mm) 

Slump (H1-H2 =mm) 

1 0 300 234 66 
2 5 300 236 64 
3 10 300 246 54 
4 15 300 237.5 62.5 
5 20 300 231.5 68.5 



 Mbereyaho et al., J. Build. Mater. Struct. (2022) 9: 44-56 53 

 

 

 

Fig.  10. Slump test results 

From the results in Fig.10, it can be observed that initially the slump decreased with addition of 
10% basalt powder waste from 66 mm up to 54 mm, and then it started increasing and became 
68.5 mm at 20% basalt powder in concrete. Also, staying on this Fig.10, it is noted that the 
overall slump decrease was only around 3.7%. This situation may be explained by the fact that 
the structure of basalt allows a slight water absorption until it is saturated. In general, according 
to standards, the normal slump of concrete should be within 50-100mm for normal reinforced 
concrete, placed with vibration (Bureau of Indian Standards, 1959). Therefore the obtained 
slump results are normal and the incorporation of the tested basalt powder waste should not 
damage the workability of concrete. 

3.5. Compressive strength test  

The standard procedure was used and the compression test results are presented in Table 7, 
while the respective chart is presented in Fig.11 

 

Fig.  11. Compression test results 



54 Mbereyaho et al., J. Build. Mater. Struct. (2022) 9: 44-56  

 

 

Referring to the results presented in Fig. 11, it can be observed that the addition of 5% basalt 
powder waste in concrete, its compressive strength reduced abruptly by 52.80%. Then after that 
the gradual incorporation of basalt powder increased the compressive strength, to finally show a 
general decrease of around 24.5%. This situation may be attributed not only to the low final 
water/cement ratio, which made the hydration process difficult and not adequate, but also to the 
basalt chemical composition which prevented the strength from further sensitive decrease.  
However, the shown compressive strength at 20% basalt waste incorporation allows confirming 
that this concrete can still be used where appropriate, depending the designed compressive 
strength. 

3.6. Discussion 

The purpose of the study was to assess the potentials of basalt powder wastes as concrete 
admixture. Though all checked properties are important for assessing concrete performance, the 
influence on the fresh concrete setting time and on its compressive strength are here discussed.  
As it was presented earlier, many of previous studies related to basalt waste application in 
concrete checked its potentials as a replacement of one of concrete components (Dobiszewska 
Beycioğlu, 2020; Dobiszewska and Barnes,2020; Akyuncu, 2019; Dobiszewska and Beycioğlu, 
2017; Uneik and Kmecova, 2013) and quite all reported about the positive influence of basalt 
material on concrete properties. Only Dobiszewska et al., (2019) established that the addition of 
basalt powder as a replacement of cement leads to the deterioration of compressive strength. 
There was a little about the use of basalt powder as concrete admixture, and therefore only 
concrete standards values regarding the setting time, slump and compressive strength, as well 
as basalt chemical composition were used for comparison.   

Setting time test results showed that the addition of basalt waste decreased both the initial and 
final sitting time for fresh concrete (Fig. 9), but remained under the standards limits (Krishna, 
2017). This is considered as positive result to consider basalt powder waste as set accelerator 
admixture.   

The results showed a general decrease of compressive strength of concrete with incorporation 
of basalt powder waste, comparing with normal concrete, even if there was a gradual increase 
after 5% basalt powder waste addition (Fig.11). These results are in acceptance with previous 
findings (Dobiszewska et al., 2019). For application of this concrete, the % of basalt powder 
waste incorporation should depend on the designed concrete strength. 

Finally, regarding the new admixture affordability, this is based on the local availability of basalt 
rock as its raw material, and it has also been confirmed by previous studies (Dobiszewska and 
Beycioğlu; 2017). 

4. Conclusion  

The general objective of this study was to investigate on the use of basalt powder waste in 
concrete as admixture, in order to take advantage from its local availability and solve the 
problem related to its negative impact to the environment. It has shown that the basalt rock is 
available in Rwanda, especially in Northern – Western province and currently has been used 
mainly in road pavement and building construction. During this study, the properties of concrete 
mixed with 0%, 5%, 10%, 15%, 20% basaltic powder like workability, setting time and 
compression strength were checked. The following key findings were established:  

 Compared to plain concrete, the workability test was achieved up to 80% due to the 
variation of water quantity.  

 The amount of water needed during mix was slightly greater than that of plain concrete, 
and therefore basaltic powder can be used as water reducer.  



 Mbereyaho et al., J. Build. Mater. Struct. (2022) 9: 44-56 55 

 

 

 The setting time of concrete mixed with basalt waste as admixture decreased with increase 
of percentages of basalt powder waste, and therefore the waste acted in concrete properly 
as admixture and would be suitable especially in humid condition. 

 With increase of the basalt powder in concrete, the compressive strength decreased in the 
beginning, but after 5% and until fixed 20% basalt powder, the strength started increasing. 
However, this increase did not attain the compressive strength for normal concrete.  

From the above, it can be concluded that the use of basalt powder waste in concrete would 
provide a local and affordable as well as a sustainable solution regarding set accelerator 
admixture. Concerning the concrete compressive strength, due to the initial reduction and then 
increase of the strength, a due care should be made to ensure the incorporated % of basalt 
powder does not decrease the designed concrete strength. Further study may check the 
durability of basaltic concrete with varying basalt powder at different ages. This study was more 
interested in setting time with consideration of other minimum requirements for concrete 
performances, and it did not establish the % of added basalt waste at which the standard 
compressive strength would be achieved; therefore this can be the scope for further study. 

Acknowledgement 

The authors sincerely acknowledge the technical support from the University of Rwanda,College 
of Science and Technology leaadership, especially regarding the provision of laboratory 
facilitaties during this study.  All individuals or institutions that contributed in one or other ways 
for the successful completion of this work, but not stated in this section are also acknowledged. 

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https://civilread.com/cement-initial-final-setting-time
https://www.civilclick.com/slump-test/
https://doi.org/10.1016/j.proeng.2013.09.010