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Lin, D.F., Lin, K.L., Hung, M.J., Luo, H.L. (2007) Petzet, S., Peplinski, B., Cornel, P. ( 2012) On wet
Sludge ash/hydrated lime on the geotechnical chemical phosphorus recovery from sewage
properties of soft soil. J. Hazard. Mater. 145 sludge ash by acidic or alkaline leaching and
(1–2), 58–64. an optimized combination of both. Water Res.
Mattenberger, H., Fraissler, G., Joller, M., Brun- 46, 3769–3780.
ner, T., Obernberger, I., Herk, P., Hermann, L. Pulger, V. – Peszmeg, G. – Kárpáti Á. (2006) A
(2010) Sewage sludge ash to phosphorus fer- szennyvíziszap-égetés gyakorlati megvalósítá-
tiliser (II): influences of ash and granulate type sa. Műszaki Információ / Környezetvédelem.
on heavy metal removal. Waste Manage. 30, (23-24) 74-86.
1622–1633. Smith, K.M., Fowler, G.D., Pullket, S., Graham,
Mininni, G, Dentel, S. (2013) Highlights of cur- N.J.D. (2009) Sewage sludge-based adsor-
rent legislation on sludge and bio-waste in EU bents: a review of their production, properties
member states and in the United States. Con- and use in water treatment applications. Water
férence Internationale « Gestion innovante des Res. 43, 2569–2594.
boues d’épuration a l’échelle européenne » Smol, M., Kulczycka, J., Henclik, A., Goraz-
Charleroi Espace Meeting Européen, 22 Oc- da, K., Wzorek , Z. (2015) The possible use of
tobre 2013. mininni@irsa.cnr.it, dentel@udel. sewage sludge ash (SSA) in the construction
edu industry as a way towards a circular economy.
Mininni, G.¸ Blanch, A. R., Lucena, F., Bersell, J. of Cleaner Production 95 45-54.
S. (2015) EU policy on sewage sludge utiliza- Suzuki, S., Tanaka, M., Kaneko, T. (1997) Glass–
tion and perspectives on new approaches of ceramic from sewage sludge ash. J. Mater. Sci.
sludge management. Environ Sci. Pollut. Res. 32, 1775–1779.
(2015) (22) 7361–7374. DOI 10.1007/s11356- Takahashi, M., Kato, S., Shima, H., Sarai, E.,
014-3132-0 Takao, I., Hatyakawa, S., Miyajiri, H. (2001)
Nanzer, S., Oberson, A., Berger, L., Berset, E., Technology for recovering phosphorus from
Hermann, L., Frossard, E. (2014) The plant avai- incinerated wastewater treatment sludge. Che-
lability of phosphorus from thermo-chemically mosphere 44, 23–29.
treated sewage sludge ashes as studied by 33P Tsai, C.C., Wang, K.S., Chiou, I.J. (2006) Effect
labeling techniques. Plant Soil 377, 439–456. of SiO –Al O –flux ratio change on the blo-
3
2
2
Pan, S.C., Lin, C.C., Tseng, D.H. (2003) Reusing ating characteristics of lightweight aggrega-
sewage sludge ash as adsorbent for copper te material produced from recycled sewage
removal from wastewater. Resour. Conserv. sludge. J. Hazard. Mater. B134, 87–93.
Recy. 39, 79–90. Vajda, S. (2012) A beforgatott jövő – Talajbioló-
Peszmeg, G. – Pulger, V. (2006) Szennyvíziszap giai és baktériumtrágyázási ismeretek minden-
termikus hasznosítása és áttételes hatásai. Mű- kinek. Phylazonit Kft. Nyíregyháza.
szaki Információ / Környezetvédelem. (23-24) Van de Velden, M., Dewil, R., Baeyens, J., Jos-
87-97. son, L., Lanssens, P. (2008) The distribution of
Petzet, S., Peplinski, B., Bodkhe, S.Y., Cornel, P. heavy metals during fluidized bed combus-
(2011) Recovery of phosphorus and aluminium tion of sludge (FBSC). J. Hazard. Mater. 151 (1),
from sewage sludge ash by a new wet chemi- 96–102.
cal elution process (SESAL-Phos-recovery pro- Vogel, C., Adam, C., Peplinski, B., Wellendorf,
cess). Water Sci. Technol. 64, 29–35. S. (2010) Chemical reactions during the pre-

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