AP1_01.vp


1 Introduction
Nitrogen is a nutrient essential to all forms of life as a basic

building block of plant and animal protein. Nevertheless, too
much of it can be toxic. The presence of nitrogen excess in the
environment has caused serious distortions of the natural
nutrient cycle between the living world and the soil, water,
and atmosphere. Nitrogen in the form of nitrous oxide, nitric
oxide, nitrate, nitrite or ammonia/ammonium is soluble in
water and can end up in ground water and drinking water.
One of the best-documented and best-understood conse-
quences of human alterations of the nitrogen cycles is the
eutrophication of estuaries and coastal seas (Oenema and
Roest, 1998). According to the instruction of the European
Community Council (CCE) of 15 July 1980, the maxi-
mum permissible level of ammonium in drinking water is
0.5 mg l�1. The processes used for the removal of ammonium
ions from drinking waters include air stripping, nitrification,
breakpoint chlorination, and ion exchange. The properties
of synthetic and natural zeolites as ion exchangers for re-
moval of ammonium ions have been discussed in great de-
tail (Jörgensen, 1976; Gaspard and Martin, 1983; Hlavay
et al., 1983; Vokáčová, et al., 1986; Hódi et al., 1995; Booker
et al., 1996; Beler Baykal and Akca Guven, 1997; Cooney et
al., 1999). The behavior of the exchange and the quantities of
ammonium removed are very much dependent on the origin
of the material, the impurities contained, the counter ions,
as well as the pretreatment performed on the zeolite.

The objective of our work is to treat drinking water spiked
with NH4

+ (10 � 0.5, 5 � 0.5, and 2 � 0.5) mg l�1 with the use of
clinoptilolite and under pretreatments of the mineral.

2 Zeolites in drinking water treatment
Zeolites are natural minerals, which can be described

chemically as aluminum silicates. They are used for various
applications, e.g., ion exchange, molecular sieves, and air-

-drying. The simplified chemical composition and structure
of zeolites can be seen in Fig. 1.

In the regular structure of silicates a few places are occu-
pied by aluminum ions, and so an additional charge is caused.
This charge is compensated by other ions like sodium, potas-
sium or ammonia, which are reversibly fixed by interactions
and can easily be exchanged by other ions. The composition
of this structure leads to various forms of zeolites. Of all
these zeolite types, clinoptilolite has the best selectivity for
ammonia. Preparing clinoptilolite so that all exchange places
are filled with sodium ions results in a form with the best
selectivity for ammonia (Jörgensen et al. 1979; Oldenburg M.
and Sekoulov I., 1995).

3 Materials and methods
Physical description of the system

Fig. 2 consists of a column set with the following
characteristics:
Internal diameter = 20 mm, total height of column = 60 cm,
height of the bed of zeolite = 33 cm, 100 ml of material at
a volumetric flow rate of 8.7 ml min�1, which is equivalent
to 5.25 bed volumes (BV) per hour, particle-size of mate-
rial = 3–5 mm, mass of zeolite in column = 100 g. A nylon
screen supported the zeolite in the column.

©  Czech Technical University Publishing House http://ctn.cvut.cz/ap/ 41

Acta Polytechnica Vol. 41  No.1/2001

Clinoptilolite in Drinking Water Treatment
for Ammonia Removal

H. M. Abd El-Hady, A. Grünwald, K. Vlčková, J. Zeithammerová

In most countries today the removal of ammonium ions from drinking water has become almost a necessity. The natural zeolite clinoptilolite
is mined commercially in many parts of the world. It is a selective exchanger for the ammonium cation, and this has prompted its use in water
treatment, wastewater treatment, swimming pools and fish farming. The work described in this paper provides dynamic data on cation
exchange processes in clinoptilolite involving the NH4

+, Ca+2 and Mg+2 cations. We used material of natural origin – clinoptilolite from
Nižný Hrabovec in Slovakia (particle-size 3–5 mm). The breakthrough capacity was determined by dynamic laboratory investigations, and
we investigated the influence of thermal pretreatment of clinoptilolite and the concentration of regenerant solution (2, 5, and 10% NaCl).
The concentrations of ammonium ion inputs in the tap water that we used were 10, 5, and 2 mg NH4

+
l
�1 and down to levels below

0.5 mg NH4
+ l�1. The experimental results show that repeated pretreatment sufficiently improves the zeolite’s properties, and the structure

of clinoptilolite remains unchanged during the loading and regeneration cycles. Ammonium removal capacities were increased by
approximately 40 % and 20 % for heat-treated zeolite samples. There was no difference between the regenerates for 10% and 5% NaCl.
We conclude that the use of zeolite is an attractive and promising method for ammonium removal.

Keywords: clinoptilolite, zeolite, ion exchange, ammonia removal, drinking water.

Me
+n

Al SiSi
Me

n+
xAlnx Siy O2(nx+y)

Y/X > 1

Me
n+

^ K
+
, Ca

2+
, Na

+
, Mg

2+
, Fe

3+
, NH4

+

Fig. 1: Simplified chemical composition and structure of zeolites



Acta Polytechnica Vol. 41  No.1/2001

Analysis

All analyses were made according to standard methods
(APHA, see Greenberg et al., 1992). Ammonia was de-
termined by Nessler methods using a spectrophotometer
(Model Hach DR/2000). Calcium and magnesium were deter-
mined by the EDTA titrimetric method.

Specification of the material

Two materials were used for the investigation:
a) Natural clinoptilolite (clino. 1). Origin: Nižný Hrabovec,

Slovakia. The chemical composition is given as:

SiO2 Al2O3 Fe2O3 FeO TiO2 CaO MgO

69.77 % 12.24 % 2.2 % 0.14 % 0.45 % 1.68 % 1 %

Na2O K2O MnO P2O5 H2O Total

2.7 % 2.11 % 0.034 % 0.08 % 7.3 % 99.704 %

b) Activated clinoptilolite. The activation process was per-
formed by heating for two samples: the samples were
exposed to an elevated temperature of 400 °C for 6 h.
Before being heated, the first sample (clino. 2) (previously
used as natural clinoptilolite) was washed with distilled
water, while the second sample (clino. 3) was heated in its
natural form.

System operation parameters

The first experiment was carried out to see the exhaustion
performance of (clino. 1) using distilled water spiked at 10 mg
NH4

� l �1 concentration. Then we applied tap water contain-
ing Ca�2 = 60 mg l �1 and Mg�2 = 12 mg l �1. The concentra-
tions of ammonium input were 10, 5 and 2 mg NH4

+ l �1 as
(NH4Cl) and down to levels below 0.5 mg l

�1. Clino. 2 and
clino. 3 were applied only with tap water containing Ca�2,
Mg�2 and NH4

+.
In the regeneration phase, 2.0% NaCl at pH range

(11.5–12.5), at a volumetric flow rate of 8.7 ml min�1, which
is equivalent to 5.25 bed volumes (BV) per hour was investi-
gated for clino. 1 in the first experiment and then at 5%, 10%
NaCl for clino. 1. For clino. 2 and clino. 3, NaCl only was
spiked at 5 %. After regeneration, the excess Cl � was removed
from the clinoptilolite, with the use of distilled water. This

washing was repeated until visual tests with AgNO3 revealed
zero chloride.

4 Results and discussion

Breakthrough capacity and effects of activated
clinoptilolite

Within the scope of this work, the results from the first ex-
periment using distilled water for clino. 1 indicated that the
breakthrough capacity defined as 0.5 mg l �1 in NH4

� was
0.47 mol l �1 for NH4

� = 10 mg l �1 as shown in Table 1. Figs. 3,
4 and 5 and Table 2 show that, for tap water containing
calcium and magnesium ions, the breakthrough capacity were
0.038, 0.052, 0.058 mol l �1 for NH4

� = 10, 5, and 2 mg l �1.
For clino. 2 the values were 0.048, 0.063, 0.068 mol l �1 for

NH4
� = 10, 5, and 2 mg l �1, and for clino. 3 the values were

0.06, 0.063, 0.076 mol l �1, respectively. These values indicate
that tap water provides a lower breakthrough capacity than
distilled water, due to the presence of other ions, especially
ions with a polyvalent charge in water, such as Ca�2 and Mg�2.

42 ©  Czech Technical University Publishing House http://ctn.cvut.cz/ap/

Reservoir Regeneration

Peristaltic pump Valve

Service
Ion exchange

Resin column

Fig. 2: Laboratory column

Zeolite column - NH
4
Cl Feed

Breakthrough Curve

0

0.1

0.2

0.3

0.4

0.5

0.6

0 20 40 60 80 100 120

Bed Volume Passed

N
H

4
+

m
g

l-
1

Clino. 1 Clino. 2 Clino. 3

breakthrough level

Fig. 3: Breakthrough curves of ion exchange resin for a tap water con-
taining (NH4

+ = 10 mg/ l, Ca2+ = 60 mg/l, Mg2+ = 12 mg/ l)

Zeolite column - NH
4
Cl Feed

Breakthrough Curve

0

0.1

0.2

0.3

0.4

0.5

0.6

100 120 140 160 180 200 220 240 260 280 300

Bed Volume Passed

N
H

4
+

m
g

l-
1

Clino. 1 Clino. 2 Clino. 3

breakthrough level

Fig. 4: Breakthrough curves of ion exchange resin for a tap water con-
taining (NH4

+ = 5 mg/ l, Ca2+ = 60 mg/l, Mg2+ = 12 mg/ l)



These results reveal that thermal activation increases
clinoptilolite selectivity for ammonium ions. The results
shown in Fig. 6 indicate that the breakthrough capacities of a
thermally activated sample are on average roughly 20 %,
40 % for clino. 2 and clino. 3, respectively, higher than the
value for untreated clinoptilolite. In addition, these results in-
dicate that ammonium ions can be removed efficiency by the
zeolite, and the exchange capacity of zeolites depends on the
initial ammonia concentration at the column inlet.

Table 1: Important parameters measured during the experiment
using distilled water spiked with NH4

� inf. = 10 mg l�1

for clino. 1

Solution volume – L 50 61 72 82 88.5

NH4
� eff. – mg l�1 0.06 0.088 0.094 0.29 0.503

BV 500 610 720 820 885

Table 2: Important parameters measured during the experiment
using tap water spiked with ammonia

Materials Clino. 1 Clino. 2 Clino. 3

NH4
� inf

[mg l �1 ]
10 5 2 10 5 2 10 5 2

Volume
L

7.25 21 70 9 25 81 11.25 28 91

BV 72.5 210 700 90 250 810 112.5 280 910

Capacity
[mol l �1 ]

0.038 0.052 0.058 0.048 0.063 0.068 0.06 0.063 0.076

Comparing the results summarized in Figs. 7, 8, it can be
seen that the removal of calcium and magnesium at break-
through level of ammonia for clino. 2 and clino. 3 was lower
than for clino. 1 at all concentrations of ammonia, which
agrees with the selectivity rules for ionic exchange in un-
treated clinoptilolite zeolite. These results reveal that the
removal efficiency of calcium and magnesium for clino. 1 was
higher than for clino. 2 and clino. 3.

Regeneration effects

The result from the first regeneration using 2% NaCl
indicate that 140 BV of a NaCl solution is sufficient for ammo-
nium elution from clino. 1. The elution curves (Figs. 9, 10 and
Table 3) indicate that no difference between regeneration by
10% and 5% NaCl solution for clino. 1. 65 BV of a NaCl solu-
tion is sufficient for ammonium elution. On the other hand,
complete elution of ammonia from clino. 2 and clino. 3

©  Czech Technical University Publishing House http://ctn.cvut.cz/ap/ 43

Acta Polytechnica Vol. 41  No.1/2001

Zeolite column - NH
4
Cl Feed

Breakthrough Curve

0

0.1

0.2

0.3

0.4

0.5

0.6

500 540 580 620 660 700 740 780 820 860 900 940

Bed Volume Passed

N
H

4
+

m
g

l-
1

Clino. 1 Clino. 2 Clino. 3

breakthrough level

Fig. 5: Breakthrough curves of ion exchange resin for a tap water
containing (NH4

� = 2 mg/ l, Ca2� = 60 mg/ l,
Mg2� = 12 mg/ l)

Useful capacity of exchange

0

0.02

0.04

0.06

0.08

0.1

0 1 2 3 4 5 6 7 8 9 10 11 12

NH
4

+ = mg/l

m
o

l
l-

1

clino .1 clino .2 clino .3

Fig. 6: Exchange capacity

0

15

30

45

60

10 5 2

NH4
+

- mg l
-1

m
g

l-1

Clino. 1 Clino. 2 Clino. 3

Fig. 7: Comparison of calcium breakthrough of ion exchange
resin for a tap water containing (NH4

+, Ca2+= 60 mg/ l,
Mg2+= 12 mg/ l)

0

3

6

9

12

15

10 5 2

NH4
+ - mg l-1

m
g

l-
1

Clino. 1 Clino. 2 Clino. 3

Fig. 8: Comparison of magnesium breakthrough of ion exchange
resin for a tap water containing (NH4

+, Ca2+= 60 mg/l,
Mg2+= 12 mg/l)



44 ©  Czech Technical University Publishing House http://ctn.cvut.cz/ap/

Acta Polytechnica Vol. 41  No.1/2001

require 110 BV of using 5% NaCl solution. These results
reveal that clino. 1 is slightly more economical than clino. 2,
and clino. 3 and 5% NaCl should be used.

5 Conclusions
The experimental results indicate that ammonium ions

can be removed efficiency by zeolites. Pretreatment of the
zeolite considerably improves its ion exchange capacity, and
clino. 3 can be used for ammonia removal as a more economi-
cal exchanger than clino. 1 and clino. 2. Ammonium removal
capacities were increased by approximately 40 % and 20 % for
heat-treated zeolite samples. There was no difference be-
tween the regenerates for 10% and 5% NaCl. The removal
efficiency of calcium and magnesium for clino. 1 was higher
than for clino. 2 and clino. 3. We conclude that the use of

zeolite is an attractive and promising method for ammonium
removal.

References
[1] APHA: Standard methods for examination of water and waste

water. 18th Edition, 1992, Published by American Public
Health Association, Washington, USA

[2] Beler Baykal, B. and Akca Guven, D.: Performance of clin-
optilolite alone and in combination with sand filters for the
removal of ammonia peaks from domestic wastewater. Wat.
Sci. Technol., 1997, Vol. 35, No. 7, pp. 47–54

[3] Booker, N., Cooney, E. and Priestly, A.: Ammonia Removal
from Sewage Using Natural Australian Zeolite. Wat. Sci.
Technol., 1996, Vol. 34, No. 9, pp. 17–24

Clino. 1

NaCl 2% NaCl 5% NaCl 10%

Volume (ml) NH4
+ (mg l �1) BV Volume (ml) NH4

+ (mg l �1) BV Volume (ml) NH4
+
(mg l �1) BV

1000 24.1 10 1000 27.6 10 1000 659 10

5000 2.65 50 5000 1.08 50 6000 25 60

6000 0.098 60 6000 0.098 60 1000 0.98 100

6500 0.036 65 6500 0.04 65 14000 0.028 140

NaCl 5%

Clino. 2 Clino. 3

Volume (ml) NH4
+ (mg l �1) BV Volume (ml) NH4

+ (mg l �1) BV

1000 40.39 10 1000 23.77 10

6000 3.01 60 6000 2.66 60

10000 0.255 100 10000 0.266 100

11000 0.05 110 11000 0.04 110

Table 3: Elution of ammonia from the resins using NaCl

NaCl = 5%

0
10
20
30
40
50
60
70
80
90

100

0 20 40 60 80

Bed Volume Paseed

N
H

4
+

m
g

l-1

Clino.1 Clino. 2 Clino. 3

Fig. 9: Typical regeneration curves for elution of ammonia from
reins using NaCl = 5%

NaCl = 10%

0

25

50

75

100

125

0 20 40 60 80

Bed Volume Passed

N
H

4
+

m
g

l-1

Clino.1

Fig. 10: Typical regeneration curves for elution of ammonia from
reins using NaCl = 10%



©  Czech Technical University Publishing House http://ctn.cvut.cz/ap/ 45

Acta Polytechnica Vol. 41  No.1/2001

[4] Cooney, E., Booker, N., Shallcross, D. and Stevens, G.: Am-
monia Removal from Wastewater Using Natural Australian
Zeolite. I. Characterization of the Zeolite. Sep. Sci. Technol.,
1999, Vol. 34, No. 12, pp. 2307–2327

[5] Gaspard, M. and Martin, A.: Clinoptilolite in Drinking
Water treatment for NH4

+ Removal. Wat. Res., 1983,
Vol. 17, No. 3, pp. 279–288

[6] Hlavay, J., Vigh, Gy., Olaszi, V. and Inczédy, J.: Ammonia
and iron removal from drinking water with clinoptilolite tuff.
Zeolite 3, 1983, pp. 188–190

[7] Hódi, M., Polyák, K. and Hlavay, J.: Removal of pollutants
from drinking water by combined ion exchange and adsorption
methods. Envir. International, 1995, Vol. 21, No. 3,
pp. 325–331

[8] Jörgensen, S. E., Libor, O., Barkacs, K. and Kuna, L.:
Equilibrium and capacity data of clinoptilolite. Wat. Res.,
1979, Vol. 13, pp. 159–165

[9] Jörgensen, S. E.: Ammonia removal by use of clinoptilolite.
Wat. Res., 1976, Vol. 10, pp. 213–224

[10] Oenema, O. and Roest, C. W. J.: Nitrogen and phosphorus
losses from agriculture into surface waters: the effects of policies

and measures in the Netherlands. Wat. Sci. Technol., 1998,
Vol. 37, No. 2, pp. 19–26

[11] Vokáčová, M., Matejka, Z. and Ellášek, J.: Sorption of
Ammonium-Ion by Clinoptilolite and by Strongly Acidic Cation
Exchangers. Acta Hydrochim, 1986, Vol. 14, No. 6,
pp. 605–611

Hossam Monier Abd El-Hady
phone: +420 2 2435 4605
e-mail: hoss@fsv.cvut.cz

Prof. Ing. Alexander Grünwald, CSc.
phone: +420 2 2435 4638
e-mail: grunwald@fsv.cvut.cz

Ing. Karla Vlčková
Ing. Jitka Zeithammerová
Department of Sanitary Engineering
Czech Technical University in Prague
Faculty of Civil Engineering
Thákurova 7, 166 29 Praha 6, Czech Republic