Fiziksel ve kimyasal olarak modifiye edilmiş proses atığının sentetik atıksudan ağır metal gideriminde başarısının araştırılması

Year 2020, Volume: 35 Issue: 1, 39 - 50, 25.10.2019

Muhammed Kamil Öden

https://doi.org/10.17341/gazimmfd.417806

Cited By: 2

Abstract

Bu çalışmanın amacı,
bor zenginleştirme tesisi çıkışından alınan posa atığının (BZA) ses ve asit ile
laboratuar ortamında modifiye edilerek (MBZA) nikel (Ni⁺²) ağır
metalinin adsorpsiyon sisteminde giderimine verimi araştırılmıştır. Deneysel
araştırma kesikli sistemle, farklı adsorban dozları (0,1-5 g/100 mL), farklı pH
(2-10), farklı temas süresi (0-150 dakika) ve farklı karıştırma hızlarında
(100, 200, 300, 400 rpm) gerçekleştirilmiştir. MBZA ait kimyasal özellikler ve
SEM görüntüleri belirlenmiştir. MBZA'nın nikel adsosorpsiyonu sırasında elde
edilen korelasyon katsayılarına göre Langmuir modeline daha uyumlu bulunmuştur.
Kinetik veriler arıtım sonucunda elde edilmiş olup MBZA için elde edilmiş olan
qmax değeri 16.01 mg/g’dir. 

Keywords

Nikel, Adsorpsiyon, Boz zenginleştirme Atığı, Kinetik, İsoterm

Investigation of the success of physical and chemically modified process waste in heavy metal removal from synthetic wastewater

Abstract

This study investigated
removal efficiency of nickel in adsorption system by using the process waste
obtained from the exit point of boron enrichment plant, modified with sound and
acid in laboratory. The experimental study was conducted in an intermittent
process by taking into account the criteria of different adsorbent dosages
(0,1-5 g/100 mL), pH (2-10), contact times (0-150 minutes) and mixing
speeds  (100, 200,300, 400 rpm). Chemical
properties and SEM images pertaining to modified boron enrichment waste (MBZA) were
specified. In nickel removal, it was observed that the obtained results were
found more concordant with Langmuir Isotherm models as evidenced by correlation
coefficients. Kinetics data were obtained from treatment results, and qmax
value obtained for MBZA were found as 16,01 mg/g.

Keywords

Nickel, Adsorption, Boron Enrichment Waste, Kinetic, Isotherm

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