33

Recycled Aggregate Concrete with Fluorescent Waste Glass and Coal/
Wood Ash Concrete Wastes

Patricija Kara1*, Aleksandrs Korjakins1

1Riga Technical University, Institute of Materials and Structures, Professor Group of Building Materials and Products, 
1 Kalku Str., Riga, LV-1658, Latvia 

* corresponding author: patricija.kara@rtu.lv

Consumption of natural aggregate as the largest concrete component is constantly and rapidly increasing with the 
increase	in	the	production	and	utilization	of	concrete.	Recycled	aggregate	is	a	valuable	resource	as	replacement	for	virgin	
aggregate	in	concrete.	In	present	study	is	investigated	the	approach	of	optimized	utilization	of	concrete	aggregate	wastes	
(CAW)	in	concrete.	The	produced	concrete	cube	specimens	with	fluorescent	waste	glass	powder/suspension	and	fly/wood	
ash after determination of their mechanical properties are recycled and used as partial replacement of natural aggregates in 
recycled aggregate concrete (RAC). Therefore, it helps to convert waste product with determined properties into recourse 
and potentially to reduce the amount of waste disposed and preserve natural resources. The mechanical properties of recycled 
aggregate	concrete	are	discussed	from	the	point	of	the	potential	of	its	utilization	in	structural	concrete.

Keywords: fluorescent waste glass suspension, coal/wood ash, recycled concrete aggregate waste.

DARNIOJI ARCHITEKTŪRA IR STATYBA
2012. No. 1(1) 

JOURNAL OF SUSTAINABLE ARCHITECTURE AND CIVIL ENGINEERING
ISSN 2029–9990

1. Introduction

Concrete as a primary building construction material 
is the most consumed man-made material in the world. In 
2007 the world concrete consumption was 11 billion tons 
or	 approximately	 11.7	 ton	 for	 each	 living	 human	 being	
(Mehta 2006, Naik 2005, Naik 2008). One of the most 
important parts of concrete is cement as hydraulic binder 
and production of cement itself is an energy-intensive and 
highly polluting process which contributes about 5-8% 
to global CO2 emissions and accounts for 3% of total 
(5% of industrial) energy consumption worldwide. 
Production of each ton of cement results one ton of carbon 
dioxide	 (CO2) (Gartner 2004) into the atmosphere. The 
aggregates	 constitute	 approximately	 80%	 of	 concrete	
volume. According to Mehta (2006), the global concrete 
industry consumes about 10 billion tons of sand and rocks 
and taking into account today’s industry development this 
number is even higher. Concrete being as a primary material 
in construction industry also is one of the most consuming 
landfills	waste	materials.	The	disposal	of	the	construction	
and	 demolition	 (C&D)	 waste	 is	 becoming	 increasingly	
difficult	and	expensive	and	also	environmental	concerns	are	
increasingly	limiting	the	option	of	landfilling	such	waste.	
The scarcity of virgin aggregates and the increasing cost 
of	landfilling	the	C&D	waste	are	encouraging	more	value-
added use of recycled aggregate (demolished concrete). 
Production and transport of virgin aggregates generate 
emissions representing 0.0046 million tons of carbon 
equivalent	 for	each	 ton	of	virgin	aggregate,	compared	 to	

only	0.0024	million	tons	of	carbon	equivalent	per	 ton	of	
recycled aggregates (E.P.A. 2003). Planners, engineers and 
public authorities are looking for ways of making reuse of 
C&D	waste	and,	therefore,	there	is	important	concern	to	find	
optimal approach of production of concrete with preferably 
reduced	 cement	 volume	 and	 equal/improved	 properties	
in comparison to conventional concrete, concrete waste 
utilization	and	 its	 recycling.	 In	2002	 the	 total	volume	of	
C&D	waste	was	over	1	billion	tons	annually	(Mehta,	2002).	
According	to	data	in	2008,	about	300	million	tons	of	C&D	
waste were generated in the U.S. each year and about 50% 
of this waste was recovered for recycling and the rest was 
landfilled	(Damtoft	2008).

Recycled aggregate is a valuable resource; value-
added consumption of recycled aggregate, as replacement 
for	virgin	aggregate	in	concrete,	can	yield	significant	energy	
and	environmental	benefits.	Concrete	produced	with	coarse	
recycled aggregate and natural sand differs from normal 
concrete produced with virgin aggregates in terms of 
some mechanical properties and durability characteristics. 
Some	of	these	differences	depend	upon	the	quality	of	the	
original concrete from which the recycled aggregate is 
obtained for use in recycled aggregate concrete (Tavakoli 
1996, Hansen 1983, Shayan 2003). Original concrete of 
relatively	 low	 strength	 tends	 to	 produce	 lower-quality	
aggregates when compared with higher-strength original 
concrete as far as the effects on the strength and durability 
of recycled aggregate concrete are concerned. It has been 
reported that recycled aggregate concrete with properties 

  

  

 

http://dx.doi.org/10.5755/j01.sace.1.1.2615 



34

in fresh and hardened states that are comparable to those 
of normal concrete can be produced using coarse recycled 
aggregate	of	desired	quality	and	natural	sand	(Shayan	2003,	
Hansen 1992). The use of recycled aggregate in concrete is 
hindered by its higher water absorption (two to three times 
that of normal aggregate) and the increased shrinkage of 
the resulting recycled aggregate concrete. These drawbacks 
result largely from the cement hydrates (from old concrete) 
that adhere to the surface of recycled aggregates. It should 
be noted that most aggregates offer engineering properties 
that are superior to these of cement hydrates (Nassar and 
Soroushian 2012). Recycled aggregates constitute only 5% 
of the total aggregate used in concrete (Mehta 2006, Naik 
2005, Naik, 2008).

Several researchers (Salem et al. 2003, Buyle-Bodin and 
Hadjieva-Zaharieva	2002,	Ravindrarajah	1985)	have	found	
increased water absorption, drying shrinkage and particularly 
air permeability of the recycled aggregate concrete when 
compared with normal. An initial absorption that is nearly 
four times that of normal concrete has been measured with 
recycled	 aggregate	 concrete	 (Buyle-Bodin	 and	 Hadjieva-
Zaharieva 2002). Increased moisture absorption and drying 
shrinkage	of	recycled	aggregate	concrete	adversely	influence	
its long-term performance and durability (Mehta 2006, 
Neville 2000, Basheer et al. 2001). Moisture movement in 
hydrated	 cement	 paste	 influences	 the	 drying	 shrinkage	 of	
concrete. Large-volume use of recycled aggregate concrete 
requires	 resolution	 of	 the	 problems	 with	 increased	 water	
absorption drying shrinkage resulting concrete.

Glass is also one of the most popular materials due to 
progressive	growth	of	urbanization	nowadays,	but	increased	
production of glass causes also simultaneously the growth 
of	glass	wastes.	Disposal	of	this	waste	is	a	complex	problem	
for many countries in the world. According to data of 2009 
in Latvia have been imported 42.6 thousand tonnes of glass 
and the recycling of glass waste was 12.5 thousand tonnes 
(Kara et al. 2012). Recycling of post-consumer glass for use 
as raw material in production of new glass is very limited, 
mainly	 due	 to	 the	 mixed-color	 nature	 of	 waste	 glass.	 In	
the	sixties,	many	studies	have	been	devoted	to	use	crushed	
glass waste as an aggregate for concrete production (Pike 
et al. 1960, Schmidt and Saia 1963, Jonhston 1974). This 
aggregate was also applied in road construction. The glass 
waste was also used for production of glass tiles and bricks, 
wall	panels,	glass	fibre,	agriculture	 fertiliser,	 landscaping	
reflective	beads	and	tableware	(Reindl	1998).	The	properties	
of glass seemed comparable to those of large aggregate in 
terms of constitution, strength and durability, and the larger 
size	of	the	glass	meant	lower	processing	costs.	These	early	
attempts however, were unsuccessful due to the alkali–
silica reaction (ASR) which takes place in the presence of 
the amorphous waste glass and concrete pore solution with 
marked	 strength	 reduction	 and	 simultaneous	 excessive	
expansion	 (Shao	 2000).	 Due	 to	 high	 disposal	 costs	 of	
glass wastes, the use of glass as concrete aggregate again 
attracted the attention of researchers and it was found that if 
glass	was	ground	to	a	particle	size	of	300μm	or	smaller,	the	
ASR	induced	expansion	could	be	reduced	and	in	fact,	data	
reported	in	the	literature	that	if	waste	glass	finely	ground	
under	75μm,	this	effect	does	not	occur	and	mortar	durability	

is	 guaranteed	 (Shao	 2000).	 The	 benefits	 of	 developing	
alternative or supplementary cementing materials as partial 
substitution for ordinary Portland cement (OPC) powder 
were described by Malhotra and Mehta (1996).

Non-recycled	 waste	 glass	 due	 to	 specific	 chemical	
composition	 (with	 heavy	 and	 toxic	 metals)	 constitutes	
a problem for solid waste disposal and therefore it has 
even	 more	 limited	 market	 in	 comparison	 to	 mixed-color	
nature of waste glass (cullet). Non-recycled waste glass 
like	fluorescent	lamp	glass	causes	a	problem	for	disposal	
because	it	is	not	biodegradable	and	landfill	is	not	the	best	
environment	friendly	solution	for	 it.	For	example,	yearly	
from	300	to	500	tonnes	of	fluorescent	lamps	are	partially	
recycled in Latvia (Kara 2012). The used borosilicate (DRL) 
and leaden silicate (LB) waste glass powders obtained from 
fluorescent	 lamp	 chippings	 after	 recycling	 process	 which	
includes	lamp	classification,	glass	separation,	cleaning	from	
harmful components, crushing into chippings and grinding 
can	be	applicable	as	microfiller	in	concrete	(Shakhmenko	
2009, Kara 2012).

Waste	 glass	 as	 powder	 milled	 to	 certain	 surface	
specific	 area	 in	 order	 to	 accelerate	 beneficial	 chemical	
reactions in concrete offers desired chemical composition 
and reactivity for use it as a supplementary cementitious 
material (SCM) for enhancing the chemical stability, pore 
system characteristics, moisture resistance and durability 
of	 concrete.	 The	 beneficial	 effects	 of	 milled	 waste	 glass	
can enhance the residual cement occurring on the surface 
of recycled aggregates, thus improving the performance 
characteristics of recycled aggregate concrete (Nassar and 
Soroushian 2012). The old mortar / paste clinging to the 
surface of recycled aggregate are porous in nature due to 
the	presence	of	large	oriented	crystals	of	calcium	hydroxide	
(a product of cement hydration) at the aggregate-remnant 
interface.	 When	 milled	 waste	 glass	 is	 used	 in	 recycled	
aggregate concrete as partial replacement of cement, 
it	 interacts	 with	 calcium	 hydroxide	 to	 form	 calcium	
silicate hydrate (C-S-H) which is the key binder among 
cement	 hydrates.	 This	 reaction	 can	 enhance	 the	 quality	
of the remnant cement paste on recycled aggregates, thus 
benefiting	the	impermeability	and	dimensional	stability	of	
recycled aggregate concrete (Nassar and Soroushian 2012).

In present study is investigated the approach of 
optimized	utilization	of	concrete	aggregate	wastes	(CAW)	
in concrete. The produced concrete cube specimens with 
fluorescent	waste	glass	and	fly/wood	ash	after	determination	
of their mechanical properties are recycled and used as 
partial replacement of natural aggregates in recycled 
aggregate concrete (RAC). Therefore, it helps to convert 
waste product with determined properties into recourse 
and potentially to reduce the amount of waste disposed and 
preserve natural resources.

2. Methods

An	experimental	study	was	carried	out	to	investigate	
the effects on the mechanical properties of concrete with 
CAW	 obtained	 from	 crushed	 concrete	 specimens	 (from	
previous studies with cement substitution at level of 30% 
with waste borosilicate (DRL) glass chippings obtained 
from	 fluorescent	 lamps	 and	 ground	 into	 powder	 with	



35

specific	surface	area	of	2310	cm2/g and coal/wood ashes 
(Kara, 2012)) after they have been stored as concrete waste. 
Crushed concrete specimens grains from coal/wood ash 
concrete,	DRL	–	fluorescent	waste	glass	concrete,	DRLS	–
fluorescent	waste	glass	suspension	concrete	were	separated	
into fractions (4/8mm, 8/11.2mm, 11.2/16mm) (see Fig. 1). 

Ordinary Portland cement CEM I 42.5N from “Kunda 
Nordic” (Estonia) was applied as binding agent. Cement 
conforms to standard EVS EN 197-1:2002 “Cement –  
Part	1:	Composition,	specifications	and	conformity	criteria	
for common cements”. Natural local aggregates (gravel, 
crushed	stone	and	sand)	have	been	used	for	mix	preparation.	

Coal Ash Wood	Ash DRL DRLS
Fig. 1. Concrete aggregate wastes

Sikament	56	polycarboxylat	plasticizing	agent	was	added	in	
several	concrete	mixes.	

A	total	of	15	different	concrete	mixes	were	prepared.	
Three	 sets	 of	 experiments	 were	 hold.	 The	 first	 set	 of	
experiments	included	7	mixes	and	was	made	with	natural	
aggregate	 substitution	 by	 100%:	 control	 mix	 with	 gravel	
4-11.2mm	 (named	 CTRL),	 control	 mix	 with	 crashed	
stones	4-11.2mm	(named	CTRL1),	2	mixes	with	coal	RAC	
4-11.2mm but different w/c ratios – RC (w/c=0.49) and 
RC1(w/c=0.59)	4-11.2mm,	1	mix	with	wood	RAC	(named	
RW)	4-11.2mm,	1	mix	with	DRL	fluorescent	waste	glass	
RAC	 4-11.2mm	 (named	 RDRL)	 and	 1	 mix	 with	 DRL	
fluorescent	waste	glass	suspension	RAC	4-11.2mm	(named	
RDRLS).

The	second	set	of	experiments	included	4	mixes	and	
was made with natural aggregate substitution by 50%: 
Control	 mix	 with	 gravel	 4-11.2mm	 (50%)	 and	 crashed	
stones	4-11.2mm	(50%)	(named	CTRL2),	1	mix	with	coal	

RAC (50%) 4-11.2mm and with gravel 4-11.2mm (50%) and 
crashed	stones	4-11.2mm	(50%)	(named	RC2),	1	mix	with	
wood RAC (50%) 4-11.2mm and with gravel 4-11.2mm 
(50%)	and	crashed	stones	4-11.2mm	(50%)	(named	RW2),	
1	mix	with	DRL	fluorescent	waste	glass	suspension	RAC	
(50%) 4-11.2mm and with gravel 4-11.2mm (50%) and 
crashed stones 4-11.2mm (50%) (named RDRLS2).

The	 third	 set	 of	 experiments	 included	 4	 mixes	 and	
was made with natural aggregate substitution by 50% and 
plasticizer:	Control	mix	with	gravel	4-11.2mm	(50%)	and	
crashed	 stones	 4-11.2mm	 (50%)	 (named	 CTRL3),	 1	 mix	
with coal RAC (50%) 4-11.2mm and with gravel 4-11.2mm 
(50%) and crashed stones 4-11.2mm (50%) (named RC3), 
1	mix	with	wood	RAC	(50%)	4-11.2mm	and	with	gravel	
4-11.2mm (50%) and crashed stones 4-11.2mm (50%) 
(named	 RW3),	 1	 mix	 with	 DRL	 fluorescent	 waste	 glass	
RAC (50%) 4-11.2mm and with gravel 4-11.2mm (50%) 
and crashed stones 4-11.2mm (50%) (named RDRL3). 

Table 1. Concrete mix compositions, kg/m3

Mix	type
W/C	
ratio

Portland cement 
CEM I 42,5 N

Gravel  
(4,0-11,2 mm)

Crashed stone 
(4,0-11,2 mm)

Natural sand 
(0,3-2,5 mm)

Quartz	sand	
(0-1,0 mm)

CAW
Plasti-
cizer

Water

CTRL 0.49 410 1000 - 650 119 - - 200
CTRL1 0.49 410 - 1000 650 119 - - 200
RC 0.49 410 - - 650 119 1000 - 200
RC1 0.59 410 - - 650 119 1000 - 242
RW 0.49 410 - - 650 119 1000 - 200
RDRL 0.49 410 - - 650 119 1000 - 200
RDRLS 0.49 410 - - 650 119 1000 - 200
CTRL2 0.59 410 500 500 650 119 - - 242
RC2 0.59 410 - 500 650 119 500 - 242
RW2 0.59 410 - 500 650 119 500 - 242
RDRLS2 0.59 410 - 500 650 119 500 - 242
CTRL3 0.49 410 845 155 650 119 - 7 200
RC3 0.49 410 423 77 650 119 500 7 200
RW3 0.49 410 423 77 650 119 500 7 200
RDRL3 0.49 410 423 77 650 119 500 7 200



36

Details	for	different	mixes	are	shown	in	table	1.
All	 concrete	 mixes	 were	 made	 with	 capacity	 of	 

6.2	litres.	The	mixing	procedure	was	following:
 ▪ Mixing	of	the	dry	ingredients	for	120	s;
 ▪ Adding 70% of the total water for 60 s;
 ▪ Adding	the	rest	of	the	water	and	mixing	for	60	s.
As	 soon	 as	 the	 mixing	 finished,	 Abram	 slump	 test	

was	carried	out	for	each	mix	in	accordance	with	LVS	EN	 
12350-2:2009 “Testing fresh concrete – Part 2: Slump test”. 

Specimens	 were	 cast	 in	 100x100x100	 mm	 plastic	
or steel moulds, which conform to standard LVS EN 
12390-1:2009 “Testing hardened concrete – Part 1: Shape, 
dimensions	 and	 other	 requirements	 for	 specimens	 and	
moulds”. The moulds were cleaned and lightly coated 
with form oil before the casting procedure. Concrete was 
compacted on a vibrating table. After that the specimens 
were covered with polyethylene pellicle and left to set for 
24	 hours	 (w/t	 plasticizing	 agent)	 and	 for	 48	 hours	 (with	
plasticizing	agent).	Then	they	were	removed	from	moulds	
and cured in water (with temperature +20±2°C) for 7 days 
and in curing chamber (with air temperature +20±2°C and 
relative	humidity	≥95%,	see	Figure	1)	for	other	21	days	or	
until testing, thus conforming to LVS EN 12390-2:2009 
“Testing hardened concrete – Part 2: Making and curing 
specimens for strength tests”. To evaluate hardened concrete 
properties compressive strength test was carried out. Before 
the test, the specimens were dried. The testing was done 
according to LVS EN 12390-3:2009 “Testing hardened 

concrete – Part 3: Compressive strength of test specimens”. 
Compression testing machine with the accuracy of ±1% 
was used; the rate of loading was 0.7 MPa/s. Compressive 
strength was conducted up to 112 days. Three specimens per 
mix	for	each	age	were	prepared	and	the	mean	compressive	
strength value was calculated. The concrete strength 
containing ground waste glass was compared to the concrete 
control	mix.	

3. Results and Discussion

The results for fresh concrete properties – slump test – 
are	summarized	in	table	2.	

The	slump	class	for	almost	all	mixes	varied	between	S1	
and	S2,	except	for	the	control	mix	with	plasticizer	(CTRL3)	
and	mix	with	DRL	fluorescent	waste	glass	suspension	CAW	
(RDRLS2).	Coal/wood	CAW	showed	better	workability	on	
concrete	 in	 comparison	 to	 fluorescent	 waste	 glass	 CAW.	
That could be described by different water absorption 
levels	of	CAW	in	mixes.	However,	as	it	is	evident	from	the	
experiment,	additional	water	amount	improved	workability	
of RDRLS2 and also decreased the compressive strength 
value.

Concrete cubes’ strength tests were carried out after 7, 
28,	56,	84	and	112	days.	After	7	days	of	hardening,	the	first	
part of samples was tested on compression strength. The 
specimens	were	dried	before	the	test.	Three	tests	per	mix	
for each age were carried out – to measure the compressive 
strength. The testing was done according to LVS EN  

Table 2. Slump test results

CTRL CTRL 1 RC RC1 RW RDRL RDRLS CTRL2 RC2 RW2 RDRLS2 CTRL3 RC3 RW3 RDRL3
Slump, 
mm

30 10 30 40 30 20 20 45 45 50 95 160 20 55 40

Slump, 
class

S1 S1 S1 S1 S1 S1 S1 S2 S2 S2 S2/S3 S4 S1 S2 S1

P. Kara, A. Korjakins
 

42 

 

The slump class for almost all mixes varied between S1 and S2, except for the control mix with plasticizer 

(CTRL3) and mix with DRL fluorescent waste glass suspension CAW (RDRLS2). Coal/wood CAW showed 

better workability on concrete in comparison to fluorescent waste glass CAW. That could be described by 

different water absorption levels of CAW in mixes. However, as it is evident from the experiment, additional 

water amount improved workability of RDRLS2 and also decreased the compressive strength value. 

Concrete cubes’ strength tests were carried out after 7, 28, 56, 84 and 112 days. After 7 days of hardening, 

the first part of samples was tested on compression strength. The specimens were dried before the test. Three 

tests per mix for each age were carried out – to measure the compressive strength. The testing was done 

according to LVS EN 12390-3:2009 “Testing hardened concrete – Part 3: Compressive strength of test 

specimens”. Compression testing machine with the accuracy of ±1% was used; the rate of loading was 0.7 

MPa/s. 

Fig. 2 shows the results from the first set of experiments when natural aggregates were substituted by CAW 

at level of 100%. Two kinds of natural aggregates were available during the experiments: gravel and crushed 

stones. As to the results of the compressive strength of CTRL and CTRL1, they don’t differ so much, however 

compressive strength of crashed stones was higher than gravel and this natural aggregates were considered more 

for experiments. At the age of 7 days mixes with wood CAW and RDRLS showed higher results than mix with 

DRL fluorescent waste glass powder and coal CAW. At the age of 28 days the results of CAW concrete were 

lower in comparison to control mixes, only RDRLS had higher result for 7-11% in comparison to control mixes. 

At the age of 56 days all mixes had equal or higher results on compressive strength in comparison to control 

mixes. The best results were for RW = 66.4MPa and RDRLS=66.0MPa, but at the age of 112 day mix RDRLS 

gained higher strength for 8% than mix RW with value of 74MPa. 

 

 

Fig. 2. Influence of CAW (100%) content and curing time on the concrete compressive strength 

 

Fig. 3 shows the results from the second set of experiments when natural aggregates were substituted by 

CAW at level of 50%. The water amount was increased for this set of experiments in order to improve concrete 

workability. The compressive strength results were lower for all mixes with CAW in comparison to control 

mixes and only RDRLS2 mix at the age of 56 days showed equal result to CTRL2, 60.4MPa, not big difference 

was observed at later ages of curing specimens.  

 

Fig. 2. Influence of CAW (100%) content and curing time on the concrete compressive strength



37

12390-3:2009 “Testing hardened concrete – Part 3: 
Compressive strength of test specimens”. Compression 
testing machine with the accuracy of ±1% was used; the rate 
of loading was 0.7 MPa/s.

Fig.	2	shows	the	results	from	the	first	set	of	experiments	
when	natural	aggregates	were	substituted	by	CAW	at	level	
of 100%. Two kinds of natural aggregates were available 
during	the	experiments:	gravel	and	crushed	stones.	As	to	the	
results of the compressive strength of CTRL and CTRL1, 
they don’t differ so much, however compressive strength 
of crashed stones was higher than gravel and this natural 
aggregates	were	considered	more	for	experiments.	At	the	
age	of	7	days	mixes	with	wood	CAW	and	RDRLS	showed	
higher	results	than	mix	with	DRL	fluorescent	waste	glass	
powder	and	coal	CAW.	At	the	age	of	28	days	the	results	of	
CAW	concrete	were	lower	in	comparison	to	control	mixes,	
only RDRLS had higher result for 7-11% in comparison to 
control	mixes.	At	the	age	of	56	days	all	mixes	had	equal	
or higher results on compressive strength in comparison to 

control	mixes.	The	best	results	were	for	RW	=	66.4MPa	and	
RDRLS=66.0MPa,	but	at	the	age	of	112	day	mix	RDRLS	
gained	higher	strength	for	8%	than	mix	RW	with	value	of	
74MPa.

Fig. 3 shows the results from the second set of 
experiments	when	natural	aggregates	were	substituted	by	
CAW	 at	 level	 of	 50%.	The	 water	 amount	 was	 increased	
for	 this	 set	 of	 experiments	 in	 order	 to	 improve	 concrete	
workability. The compressive strength results were lower 
for	 all	 mixes	 with	 CAW	 in	 comparison	 to	 control	 mixes	
and	only	RDRLS2	mix	at	the	age	of	56	days	showed	equal	
result to CTRL2, 60.4MPa, not big difference was observed 
at later ages of curing specimens. 

In	 the	 third	 experiment	 set	 (Fig.	 4)	 plasticizer	 was	
added	into	mix	keeping	the	same	water	amount	as	in	the	first	
set	of	experiments.	Plasticizer	influenced	on	workability	of	
control	mix	and	not	so	much	on	the	CAW	mixes.	Coal	CAW	
mix	had	worse	workability,	RW3	and	RDRL3	better	as	in	
second	experiment	set.	The	compressive	strength	results	of	

Recycled Aggregate Concrete with Fluorescent Waste Glass and Coal/Wood Ash Concrete Wastes 

43 

 

                            

Fig. 3. Influence of CAW (50%) content and curing time on the concrete compressive strength 

 

                            

 

Fig. 4. Influence of CAW (50%) and plasticizer content and curing time on the concrete compressive strength 

 

In the third experiment set (Fig. 4) plasticizer was added into mix keeping the same water amount as in the 

first set of experiments. Plasticizer influenced on workability of control mix and not so much on the CAW 

mixes. Coal CAW mix had worse workability, RW3 and RDRL3 better as in second experiment set. The 

compressive strength results of RC3 were equal to control mix within the 7 and 28 days, and were higher at the 

age of 56-112 days. The best result for this group was mix RDRL3 with the value of 76.5 MPa. 

It is possible to see from present research that recycled concrete aggregate is a valuable resource as 

replacement for virgin aggregate in concrete carrying some environmental benefits. Increasing recycled concrete 

aggregate content leads to increased water absorption, however it depends on the CAW used. As it was observed 

from the first set of experiments the slump’s value of coal/wood CAW mix was equal to control mix, also with 

modified w/c ratio CAW mix’s slump was equal to control mix, and only mixes with fluorescent waste glass 

suspension were performing better workability except the third set of experiments with plasticizer. That could be 

described by the morphology of CAW grains and also chemical composition of old mortar remained from 

previous studies (Kara 2012). 

The optimal natural aggregate substitution level with CAW in concrete could be around 100% with 

optimized w/c ratio and needed workability taking into account that compressive strength for concrete structural 

elements is important at the age of 7 days and 28 days. In comparison to control mix only RW and RDRLS 

mixes could competitive results but taking into account that structural elements compressive strength is in the 

range up to 50 MPa, the results obtained from this study are satisfied for all mixes.  

Fig. 3. Influence of CAW (50%) content and curing time on the concrete compressive strength

Recycled Aggregate Concrete with Fluorescent Waste Glass and Coal/Wood Ash Concrete Wastes 

43 

 

                            

Fig. 3. Influence of CAW (50%) content and curing time on the concrete compressive strength 

 

                            

 

Fig. 4. Influence of CAW (50%) and plasticizer content and curing time on the concrete compressive strength 

 

In the third experiment set (Fig. 4) plasticizer was added into mix keeping the same water amount as in the 

first set of experiments. Plasticizer influenced on workability of control mix and not so much on the CAW 

mixes. Coal CAW mix had worse workability, RW3 and RDRL3 better as in second experiment set. The 

compressive strength results of RC3 were equal to control mix within the 7 and 28 days, and were higher at the 

age of 56-112 days. The best result for this group was mix RDRL3 with the value of 76.5 MPa. 

It is possible to see from present research that recycled concrete aggregate is a valuable resource as 

replacement for virgin aggregate in concrete carrying some environmental benefits. Increasing recycled concrete 

aggregate content leads to increased water absorption, however it depends on the CAW used. As it was observed 

from the first set of experiments the slump’s value of coal/wood CAW mix was equal to control mix, also with 

modified w/c ratio CAW mix’s slump was equal to control mix, and only mixes with fluorescent waste glass 

suspension were performing better workability except the third set of experiments with plasticizer. That could be 

described by the morphology of CAW grains and also chemical composition of old mortar remained from 

previous studies (Kara 2012). 

The optimal natural aggregate substitution level with CAW in concrete could be around 100% with 

optimized w/c ratio and needed workability taking into account that compressive strength for concrete structural 

elements is important at the age of 7 days and 28 days. In comparison to control mix only RW and RDRLS 

mixes could competitive results but taking into account that structural elements compressive strength is in the 

range up to 50 MPa, the results obtained from this study are satisfied for all mixes.  

Fig. 4. Influence of CAW (50%) and plasticizer content and curing time on the concrete compressive strength



38

RC3	were	equal	to	control	mix	within	the	7	and	28	days,	
and were higher at the age of 56-112 days. The best result 
for	this	group	was	mix	RDRL3	with	the	value	of	76.5	MPa.

It is possible to see from present research that recycled 
concrete aggregate is a valuable resource as replacement for 
virgin aggregate in concrete carrying some environmental 
benefits.	 Increasing	 recycled	 concrete	 aggregate	 content	
leads to increased water absorption, however it depends 
on	the	CAW	used.	As	it	was	observed	from	the	first	set	of	
experiments	the	slump’s	value	of	coal/wood	CAW	mix	was	
equal	 to	 control	 mix,	 also	 with	 modified	 w/c	 ratio	 CAW	
mix’s	 slump	 was	 equal	 to	 control	 mix,	 and	 only	 mixes	
with	 fluorescent	 waste	 glass	 suspension	 were	 performing	
better	workability	except	the	third	set	of	experiments	with	
plasticizer.	That	could	be	described	by	the	morphology	of	
CAW	grains	and	also	chemical	composition	of	old	mortar	
remained from previous studies (Kara 2012).

The optimal natural aggregate substitution level with 
CAW	 in	 concrete	 could	 be	 around	 100%	 with	 optimized	
w/c ratio and needed workability taking into account that 
compressive strength for concrete structural elements is 
important at the age of 7 days and 28 days. In comparison to 
control	mix	only	RW	and	RDRLS	mixes	could	competitive	
results but taking into account that structural elements 
compressive strength is in the range up to 50 MPa, the 
results	obtained	from	this	study	are	satisfied	for	all	mixes.	

Waste	 glass	 as	 powder	 ground	 to	 certain	 surface	
specific	 area	 in	 order	 to	 accelerate	 beneficial	 chemical	
reactions in concrete offers desired chemical composition 
and reactivity for use it as a supplementary cementitious 
material (SCM) for enhancing the chemical stability, pore 
system characteristics, moisture resistance and durability of 
concrete. As it was observed from present study, the waste 
glass	mixes	acted	different	from	coal/wood	ash	mixes,	but	
more	detailed	investigation	must	be	carried	out	in	this	field.	
The	next	step	could	be	the	use	of	waste	glass	as	cement	partial	
replacement	at	level	of	20-30%	in	mixes	with	CAW,	which	
could improve the performance characteristics of recycled 
aggregate	 concrete	 and	 also	 set	 of	 X-ray	 experiments	 in	
order to observe how calcium silicate hydrates are forming.

4. Conclusions

The	effect	of	CAW	on	compressive	strength	appears	
to	 be	 dependent	 on	 original	 concrete	 quality	 and	 mix	
proportions, water/cement ratio and workability. Recycled 
aggregates from demolished concrete are generally produced 
by crushing, screening and removing the contaminants 
by water cleaning, air-shifting and magnetic separation. 
The	 quality	 of	 such	 aggregate	 usually	 is	 lower	 due	 to	
remained amount of mortar on original aggregate grains. 
The	utilization	of	recycled	aggregates	in	structural	concrete	
should help to improve the environmental performance of 
concrete. According up-to-date state of research in the area 
of	recycled	aggregates	utilization	from	demolished	concrete	
in structural concrete is technically feasible but limited since 
it is not recommended to apply this kind of concrete for 
structural	elements	which	are	expected	to	have	high	stresses	
and deformations in service because the long-term behavior 

is not well-known yet and also it is not recommended due 
to its uncertain durability performance. In present study 
recycled aggregates from concrete specimens with known 
mix	composition	have	performed	good	mechanical	strength	
results.	 The	 best	 obtained	 result	 was	 for	 the	 mixes	 with	
waste	fluorescent	glass	CAW.

Substitution of natural aggregates can be one of 
possibilities	 to	 take	care	of	 landfills	and	increase	of	CO2 
emissions into the atmosphere in Latvia. There are not 
developed regulatory standards for recycled concrete use 
in construction in Latvia. It would be important to develop 
and implement the rules of the use of recycled concrete 
aggregates in structural concrete in Latvia after detailed 
research	in	this	field	will	be	carried	out.

Acknowledgements 

The	 financial	 support	 of	 the	 ERAF	 project	 
Nr. 2010/0286/2DP/2.1.1.1.0/10/APIA/VIAA/033 „High 
efficiency	nanoconcretes”	is	acknowledged.

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Received 2012 06 19 
Accepted after revision 2012 09 03 

Patricija KARA – Scientific	 researcher,	 Lecturer	 at	 Riga	Technical	 University,	 Institute	 of	 Materials	 and	 Structures,	
Professor Group of Building Materials and Products.
Main research area: reuse of industrial wastes and by-products, concrete micro structural behaviour, concrete fracture, 
concrete technology, ecological building materials.
Address:		16	Azenes	St.,	Riga	LV-1048,	Latvia.	 	 	
Tel.: +371 670 89243   
E-mail:  patricija.kara@rtu.lv  

Aleksandrs KORJAKINS – Professor at Riga Technical University, Institute of Materials and Structures. Chair of Professor 
Group of Building Materials and Products.
Main research area: building materials and structures, ecological building materials, reuse of industrial waste.
Address:		16	Azenes	St.,	Riga	LV-1048,	Latvia.	 	 		
Tel.:  +371 670 89248   
E-mail:  aleksandrs.korjakins@rtu.lv