NL9000878A - Water treatment to remove sulphide(s) - by oxidising in aerobic reactor having specified minimum sludge load - Google Patents

Abstract

Water contg. sulphides is purified by oxidising in a reactor using sludge contg. aerobic bacteria. The sludge load (w.r.t. the sulphide oxidising part of the sludge) is at least 10 mg sulphide per Mg N in the sludge per hr.. Pref. the sludge load is at least 20 mg (at least 35 mg) sulphide per mg N. The sludge is in the form of biofilms bound to a carrier. The O2 concn. in the reactor is 0.1-9.0 (4) mg/l. The sulphide concn. in the effluent is kept at 0.5-30 mg/l. The sulphide surface load is at least 10 g/sq. m. The sulphide load is at least 50 (at least 100) mg S/l.h. In a two-stage process sulphide is (partially) oxidised to S and then, in a second reactor S and remaining sulphide oxidised to sulphate. The first oxidn. pref. uses a sulphide load of at least 26 mg S/l.h. (at least 50) (100-1000) mg S/l.h. S cpds. may first be anaerobically reduced to sulphide. The S cpds. are esp. sulphates, sulphites or thiosulphate. Purified water may be recycled to keep the S content below 800 (below 350) mg/l during anaerobic treatment.

Description

Method for the purification of waste water containing sulphide

The invention relates to a method for purifying sulphide-containing waste water, wherein the sulphide is oxidized to elemental sulfur or sulphate.

The presence of sulfide in waste water has many adverse consequences, such as: - corrosive effect on concrete and steel, - high oxygen demand, which results in oxygen deficiency after discharge of the waste water into receiving water, resulting in pollution of the environment and / or high environmental taxes; - poisoning effect on humans and animals; - severe odors.

In aerobic wastewater treatment using a process that uses activated sludge, sulfide also has a negative impact on the treatment efficiency and on the sludge retention. This is partly due to the fact that sulphide-oxidizing filamentous bacteria, such as those of the genera Thiothrix and Beggiatoa, can develop in the installations used. These filamentous bacteria impede the proper functioning of the sludge separation, so that sludge leaches out. This has two undesirable consequences: a: reduction of the activity of the purification plant, resulting in less good purification; b: increase of the levy because the sludge that has been washed out increases the COD load.

A method for the removal of sulfide from waste water is known from Dutch patent application 88.01.009. Here, the sulfide present is mainly converted into elemental sulfur by sulfur-oxidizing bacteria with an oxygen deficiency.

However, it appears that, depending on the concentration of sulphide in the waste water and on the other characteristics of the waste water, the development of filamentous bacteria as described above is not yet sufficiently inhibited and therefore the efficiency of the aerobic purification installation is not optimal.

A method has now been found for the purification of sulphide-containing waste water, whereby the development of filamentous sulphide oxidizing bacteria is virtually prevented, while at the same time a very efficient removal of sulphide is achieved. This process is characterized in that a) in a first aerobic reactor at least part of the sulfide is converted into elemental sulfur, b) the liquid obtained in step a), which contains elemental sulfur and optionally still sulfide, is passed into a second aerobic reactor, in which sulfur and sulfide are converted into sulfate, and most of the organic material is removed.

It is surprising that by increasing the sulfide load of the first aerobic reactor, ie by increasing the sulfide concentration, shortening the treatment time and / or decreasing the treatment volume, both the efficiency of the sulfide removal itself and of the second aerobic purification of other contaminants are improved.

In particular, the method of the invention allows for improved sludge retention in the second aerobic purification. This is illustrated in Table A, which gives test results using a reactor as described in Dutch patent application 88.01.009 (for the conversion of sulfide to sulfur).

Table A

Result over 2 weeks COD yield Sludge leaching with sulfide conversion to sulfur 76 hardly without sulfide conversion 52 on a large scale

The variation of the process parameters on the efficiency of sulfide removal and on the growth of the filamentous bacteria is illustrated in Table A

Table B

Flow-through- Hydraulic Sulfide- Sulfide- Sulfide- Growth rate chemical concentration load concentration Thiothrix / (1 / h) residence influent (mg S ^ “/ lh) effluent Beggiatoa time (h) (mg S2_ / l) (mg S2” / l) 75 0.3 l40 525 15 1.3 i4o 105 25 1.5 13.3 l40 10.5 0.5 ++ 15 1.3 25 18.8 2.0 ++ 71 0.3 3, 0 10.5 0.0 ++

Table B shows that the hydraulic residence time separately and the sulphide concentration in the waste water separately do not directly determine the performance of the first aerobic treatment. In contrast, it appears that at a sulfide load of less than about 20 mg / S2 / lh, a significant growth of unwanted filamentous sulfur-oxidizing bacteria occurs. Therefore, the minimum sulfide loading in this method is at least 25 mg S / l.h. Preferably, the sulfide load is at least 50 mg S / l.h and particularly preferably at least 100 mg S / l.h. Generally, a sulfide load above 1000 mg S / l.h will not be applied because the throughput rates will then become unacceptable. Waste streams that are too concentrated will therefore preferably be diluted before purification.

The oxidation of sulfide can lead to elemental sulfur and / or sulfate, depending on the residence time and the oxygen concentration. In most cases, it is advantageous to oxidize the sulfide to sulfur, since it can be more easily removed by settling, centrifugation, flocculation or filtration. To this end, an excess of oxygen is used, as explained above.

The process according to the invention for purifying sulphide-containing waste water advantageously takes place in a two-stage reaction, in which the sulphide is converted in a first aerobic reactor of relatively small dimensions and with a high flow rate (residence time a few tens of minutes to a few hours), after which in an aerobic reactor of relatively large dimensions and with a long residence time (for example about 24 hours), the other oxidisable components are removed.

A device for separating elemental sulfur may be located between the two reactors. This creates a waste water stream that is virtually or completely free of sulfur compounds.

Claims (4)

Process for the purification of sulphide-containing waste water, wherein the sulphide is oxidized to elemental sulfur or sulphate, characterized in that a) in an aerobic first reactor, at least part of the sulphide is converted into elemental sulfur, b) the step a) obtained liquid, which contains elemental sulfur and optionally still sulfide, is passed into a second aerobic reactor, in which sulfur and sulfide are converted into sulfate, and most of the organic material is removed. 2. Process according to claim 1, characterized in that a sulfide load of at least 25 mg S / l.h is used in step a). Process according to claim 1 or 2, characterized in that a sulfide load of at least 50 mg S / l.h is used in step a). 4. Process according to claim 3, characterized in that a sulfide load of at least 100 mg S / l.h and at most 1000 mg S / l.h is used.