DE102022102849A1 - Process for waste water purification - Google Patents

Abstract

In a process for waste water purification, the pH value in the waste water is adjusted to a value of at least 6 in a first step, whereupon iron(II) is metered in in a next step, with hydrogen peroxide being added in the same step or in a subsequent step, to cause a reaction of ferrous iron to ferric iron, which precipitates as iron hydroxide in the form of flakes.

Description

The invention relates to a method for waste water purification.

In the WO 99/21801 A1 describes a process for wastewater treatment based on the Fenton reaction. Here, the wastewater is adjusted to a pH between 2 and 4 and iron(II) sulfate heptahydrate and hydrogen peroxide are added to the wastewater at a temperature of 10° to 30°C. A flocculant is then added, causing sediment to settle in the mixture. The water cleaned from the sediments can then be discharged.

The U.S. 8,663,478 B2 discloses a process for treating waste water containing colloidal contaminants in dissolved or suspended form. The effluent is treated in a treatment plant where the effluent is first contacted with ferrous sulphate and hydrogen peroxide in an oxidation zone. In a subsequent flocculation step, a flocculation additive and a bulking agent of insoluble granular material are introduced, after which a sludge and bulking mixture is separated in a sedimentation area in the lower section of the sedimentation area. Part of the sludge is returned to the oxidation area.

The object of the invention is to clean waste water in an efficient manner.

This object is achieved according to the invention with the features of claim 1. The subclaims indicate appropriate developments.

With the aid of the method according to the invention, waste water can be cleaned using Fenton oxidation, in which divalent iron (iron(II)), which is present in the form of a salt, is metered into the waste water, the divalent iron being converted to trivalent iron with the addition of hydrogen peroxide ( Iron(III)) oxidized. This forms OH radicals with a strong oxidative effect, which oxidize non-specifically water components, in particular dissolved organic carbon compounds (Dissolved Organic Carbon - DOC). The trivalent iron precipitates as iron hydroxide in the form of flakes. The hydrogen peroxide reacts to form water and oxygen.

In the process according to the invention, the pH value in the waste water is adjusted to a value of at least 6 (six) before the divalent iron is metered in. This only slightly acidic environment is sufficient to initiate the desired Fenton oxidation. Accordingly, at a pH of less than 7, only a relatively small amount of acid needs to be added to set the desired pH. Any subsequent neutralization of the waste water that may be required can also be carried out by adding a correspondingly reduced amount of lye. At the almost neutral pH of at least 6, the iron(II) is still dissolved. By increasing the electrical potential, iron(III) is formed, which precipitates as Fe(OH) ₃ in this pH range and forms flakes, in particular micro-flakes.

The pH value in the waste water is adjusted in particular to a value between 6 and 8 in order to bring about the reaction of iron(II) to iron(III). It can be expedient to set a pH that is greater than or equal to 6 and less than or equal to 7, and preferably has a value of less than 7. However, the process can also be carried out at a pH in the basic range between 7 and 8.

In a further advantageous embodiment, the iron(II) is metered in in the form of a salt, for example in the form of iron chloride FeCl ₃ and/or iron sulfate FeSO ₄ , optionally in combination with potassium permanganate KMnO ₄ . The ferrous salt can be present either as a dilute solution or in solid form and discharged into the waste water. It may be sufficient to add the ferrous salt only in the form of iron chloride or only in the form of iron sulfate or as a combination of iron chloride and iron sulfate. Optionally, the iron chloride and/or the iron sulfate can be mixed with potassium permanganate.

According to a further advantageous embodiment, the process runs at a maximum temperature of 35°C. It may be sufficient to carry out the process at a temperature of not more than 30°C or not more than 25°C or not more than 20°C or at any temperatures between the aforementioned temperature values. These temperatures are sufficient to carry out the Fenton oxidation. Accordingly, the waste water to be cleaned does not have to be heated, or only slightly so.

The boundary conditions mentioned above allow the process to be carried out at a volume flow of the waste water of, for example, 50 m ³ /h or more, so that it can be used on an industrial scale.

According to a further advantageous embodiment, in a further step, which follows the reaction of iron(II) to form iron(III) and the flocculation of the iron hydroxide in the form of flakes, a flocculation aid is metered in, whereby the iron hydroxide flakes form macroflakes accumulate. A polymer can be used as a flocculant.

If necessary, the pH value in the waste water is increased with or after the dosing of flocculant by adding lye. In addition, sludge, which is returned from a subsequent sludge separation, can be added to the wastewater with or after the dosing of flocculant. In the sludge separation, the accumulating sludge is separated, for example by sedimentation or flotation. The addition of sludge supports flocculation. Preferably, only a portion of the sludge produced in the sludge separation is recycled and mixed with the waste water.

The process is suitable for cleaning untreated waste water with an organic load (Dissolved Organic Carbon - DOC) of at least 20 mg/l. The organic load can be reduced by 90%, for example, using the process.

The untreated wastewater can contain suspended solids (SS) in the range of 20 mg/l to 50 mg/l, which the process reduces by, for example, 90%.

The invention also relates to a device for carrying out the method described above. The device has a pre-reactor into which the untreated waste water is introduced, a flocculation chamber downstream of the pre-reactor and a sludge separation chamber which adjoins the flocculation chamber.

If necessary, acid to set a pH of less than 7, iron(II) and hydrogen peroxide can be fed to the prereactor with the introduced untreated waste water, whereupon the iron(II) oxidizes to iron(III) in the prereactor. The OH radicals that are formed oxidize non-specific substances in the water in the waste water, in particular dissolved organic carbon compounds DOC. The trivalent iron precipitates as iron hydroxide in the form of flakes. The hydrogen peroxide reacts partially or completely to form water and oxygen.

The waste water pretreated in the pre-reactor is then fed into the flocculation chamber, into which a flocculation aid, in particular a polymer, is introduced. The sludge separation chamber is connected to the flocculation chamber via a return duct, part of the sludge being returned from the sludge separation chamber into the flocculation chamber via the return duct.

The resulting sludge is separated in the sludge separation chamber, preferably by sedimentation or by flotation. The cleaned wastewater can then be used as clear run-off or processed further.

Further advantages and expedient embodiments can be found in the further claims, the description of the figures and the drawing, in which a device for waste water treatment with a pre-reactor, flocculation chamber and sludge separation chamber is shown.

In the 1 The device 1 shown for waste water treatment comprises a pre-reactor 2, a flocculation chamber 3 and a sludge separation chamber 4, through which the waste water flows in succession and in which the waste water is subjected to various treatment steps.

The untreated waste water is introduced into the pre-reactor 2 according to arrow 5, acid being added immediately after introduction via a metering line 6 to set a pH of preferably less than seven, in particular a pH of six, of the waste water. Following this, iron(II) in the form of a salt, for example in the form of iron chloride FeCl ₃ and/or iron sulfate FeSO ₄ , optionally in combination with potassium permanganate KMnO ₄ , is metered into the waste water in the pre-reactor 2 via a further metering line 7 . The iron(II) salt, which is either in the form of a dilute solution or in solid form, reacts to form iron(III), which in this pH range precipitates as iron hydroxide Fe(OH) ₃ and forms microflakes.

After the iron(II) salt has been introduced, hydrogen peroxide H ₂ O ₂ can also be added via line 7, as a result of which OH radicals with a strong oxidative effect are formed, via which the water constituents are oxidized non-specifically, in particular dissolved organic carbon compounds (dissolved organic carbon - DOC). The hydrogen peroxide reacts to form water and oxygen.

The process runs at a temperature between 20°C and a maximum of 35°C, so that the waste water usually does not need to be heated.

The pre-reactor 2 is equipped with an agitator 8 for better mixing of the waste water with the added substances.

Following the pre-reactor 2, the waste water passes via a line 9 into the flocculation chamber 3, into which a flocculation aid, in particular a polymer, is metered via a metering line 10. With the addition of the flocculant, the iron hydroxide micro-flakes accumulate into macro-flakes.

In the flocculation chamber 3 there is also a further dosing line 11, via which the pH value in the waste water is increased either at the same time as the dosing of flocculants or after the dosing of flocculants by adding caustic.

The flocculation chamber 3 is also equipped with an agitator 12 which, when actuated, mixes the materials and substances in the flocculation chamber 3 .

A return duct 13 which branches from the sludge separation chamber 4 and via which part of the sludge which is separated in the sludge separation chamber 4 is returned to the flocculation chamber 3 opens into the line 9 . The sludge supports the flocculation in the flocculation chamber 3.

The flocculation chamber 3 is connected to the following sludge separation chamber 4 via an inflow area 14 with double direction deflection. Sludge is separated from the waste water that has entered the sludge separation chamber 4 via the inflow area 14 by the sludge being deposited by sedimentation. With the help of a sludge scraper 15, the settled sludge is pushed towards the center into a sludge funnel 16, through which the sludge is discharged. The sludge can be discharged via a discharge line 18 branching at the bottom of the sludge hopper 16 . The cleaned waste water is passed through a lamella clarifier 19 and discharged as clear water through a line 17 .

QUOTES INCLUDED IN DESCRIPTION

This list of documents cited by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent Literature Cited

• WO 9921801 A1 [0002]
• US8663478B2 [0003]

Claims (11)

Process for waste water purification, in which the pH value in the waste water is adjusted to a value of at least 6 in a first step, whereupon iron(II) is metered in in a next step, with hydrogen peroxide being added in the same step or in a subsequent step, to cause a reaction of ferrous iron to ferric iron, which precipitates as iron hydroxide in the form of flakes. procedure after claim 1 , characterized in that the process takes place at a maximum temperature of 35°C. procedure after claim 1 or 2 , characterized in that the pH value in the waste water is adjusted to a value between 6 and 8 in order to effect the reaction of ferrous iron to ferric iron. Procedure according to one of Claims 1 until 3 , characterized in that iron(II) is added in the form of a salt, for example in the form of iron chloride FeCl ₃ and/or iron sulfate FeSO ₄ , optionally in combination with potassium permanganate KMnO ₄ . Procedure according to one of Claims 1 until 4 , characterized in that in a further step a flocculant is metered in and the iron hydroxide flakes accumulate to form macro flakes. Proceedings claim 5 , characterized in that the pH value in the waste water is increased with or after the dosing of flocculant by adding lye. Proceedings claim 5 or 6 , characterized in that the waste water with or after the dosing of flocculant sludge is added, which is recycled from a subsequent sludge separation. Procedure according to one of Claims 1 until 7 , characterized in that the process is carried out at a volume flow of the waste water of at least 50 m ³ / h. Procedure according to one of Claims 1 until 8th , characterized in that the process is carried out with an organic load (DOC) of the untreated waste water of at least 20 mg/l. Device for carrying out the method according to one of Claims 1 until 9 , with a pre-reactor (2) into which the untreated waste water (5) can be introduced, with the pre-reactor (2) optionally being able to be supplied with acid to set a pH of less than 7, iron(II) and hydrogen peroxide, with a flocculation chamber ( 3) into which the pretreated waste water from the pre-reactor (2) can be introduced, with a flocculation aid being able to be supplied to the flocculation chamber (3), and with a sludge separation chamber (4) to which the further treated waste water from the flocculation chamber (3) can be supplied. contraption claim 10 , characterized in that the sludge separation chamber (4) is connected to the flocculation chamber (3) via a return duct (13), sludge being able to be returned to the flocculation chamber (3) via the return duct (13).