JP2013010073A - Method and device for waste water treatment - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a waste water treatment method and a device therefor capable of treating waste water containing heavy metal and ammonia and fully reducing the heavy metal concentration highly and at low cost without adding a flocculating agent thereto.SOLUTION: The waste water treatment method includes an ammonia removing process for adding an alkaline agent to the waste water Wcontaining heavy metal and ammonia, and for volatilizing and removing the ammonia, and a membrane separation process for membrane-separating the waste water Win which ammonia is volatilized and removed. The waste water treatment device 1 includes an ammonia removing means 20 for adding the alkaline agent to the waste water Wcontaining the heavy metal and ammonia and volatilizing and removing the ammonia, and a membrane separation means 30 for membrane-separating the waste water Win which the ammonia is volatilized and removed.

Description

  The present invention relates to a wastewater treatment method and treatment apparatus for treating wastewater containing heavy metals.

  Conventionally, plating wastewater discharged from an electrolytic plating process includes heavy metals such as copper, chromium, zinc, nickel, tin, lead, iron, and cadmium. For this reason, wastewater containing heavy metals is usually discharged after processing such as removal of heavy metals from the viewpoint of environmental considerations.

For example, the following method has been proposed as a method for treating wastewater containing heavy metals.
In Patent Document 1, as a method for removing a plurality of trace components such as iron, manganese, silica, and fluorine in wastewater at once, aluminum sulfate (flocculating agent) and an oxidizing agent are added to wastewater stored in a treatment tank. A method for membrane filtration of solid matter generated by a separation membrane filter immersed in a treatment tank is disclosed.
Patent Document 2 discloses a method for treating sludge containing low-concentration heavy metals such as copper to improve the sludge cohesiveness by oxidizing with an oxidizing agent after insolubilizing with a sulfurizing agent. ing.

In recent years, electroless plating such as electroless nickel plating and acidic zinc plating have been widely performed.
However, when treating the wastewater discharged from the electroless plating process or the acidic zinc plating process, it is difficult to reduce the heavy metal concentration in the wastewater.
This is because ammonia is often added to the plating bath as a stabilizer or pH adjuster in the electroless plating process or acidic zinc plating process, but plating is performed using a plating bath to which ammonia is added. In this case, it is considered that ammonia is also contained in the wastewater.

Patent Document 3 discloses a method for removing ammonia from wastewater by wet oxidation using air or oxygen as an oxidizing agent as a method for treating wastewater containing ammonia.
Patent Document 4 discloses a method for decomposing ammonia by adding nitrite to water and reacting it with a catalyst under heating conditions as a method for treating water containing ammoniacal nitrogen and a metal salt. .

JP 2010-36180 A JP 2007-69068 A Japanese Patent Publication No.59-19757 Japanese Patent No. 3644050

However, since the method described in Patent Document 1 adds a flocculant, the drug cost increases. Furthermore, since sludge is generated when the flocculant is added, there is a cost for disposal of the sludge. In addition, when ammonia is contained in the wastewater, it has been difficult to sufficiently reduce the heavy metal concentration.
Although the method described in Patent Document 2 can improve the cohesiveness of the generated sludge, it is difficult to sufficiently reduce the heavy metal concentration when the wastewater contains ammonia. In addition, in order to sufficiently reduce the concentration of heavy metals in wastewater, it is necessary to add a large amount of a sulfurizing agent and a flocculant. However, the cost of chemicals increases and the amount of sludge generated increases the disposal cost of sludge. Or

In the method described in Patent Document 3, it is necessary to use high-temperature and high-pressure conditions in order to decompose ammonia. Therefore, even if the method described in Patent Document 3 is applied to wastewater containing heavy metals and ammonia, the amount of energy consumed for the treatment increases and costs increase.
In the method described in Patent Document 4, although ammonia is removed, it is necessary to add nitrite, so that a new nitrogen contamination source is added to the wastewater. Moreover, even if the method described in Patent Document 4 is applied to wastewater containing heavy metals and ammonia, it is not easy to obtain a sufficient treatment effect.

  The present invention has been made in view of the above circumstances, and wastewater containing heavy metals and ammonia can be treated at a low cost and highly without adding a flocculant, and the concentration of heavy metals can be sufficiently reduced. A processing method and a processing apparatus are provided.

As a result of intensive studies, the present inventors have become difficult to treat wastewater containing heavy metals and ammonia. If ammonia is contained in the wastewater, the heavy metal forms ammonia and an ammine complex and is stable in the wastewater. It was thought that this was due to the fact that the heavy metal was not easily insolubilized even when a sulfiding agent or a flocculant was added. In addition, when nitrite is added as described in Patent Document 4, nitrous acid and heavy metal may form a complex, and it is considered that the heavy metal is hardly insolubilized.
Therefore, the present invention has been completed based on the idea that if ammonia is removed before removing heavy metals in the wastewater, the heavy metals cannot maintain the form of the complex and can be easily removed from the wastewater.

That is, the method for treating wastewater of the present invention is a method for treating wastewater containing heavy metals and ammonia, wherein an alkaline agent is added to the wastewater to volatilize and remove ammonia, and the wastewater from which ammonia has been volatilized and removed is formed into a membrane. And a membrane separation step for separating.
The ammonia removal step is preferably performed by aeration of waste water.
Furthermore, it is preferable to have an oxidation treatment step for oxidizing the wastewater from which ammonia has been volatilized and removed between the ammonia removal step and the membrane separation step.
Moreover, it is preferable to have the precipitation separation process of carrying out precipitation separation of the heavy metal in the wastewater which volatilized and removed ammonia between the said ammonia removal process and a membrane separation process.
Furthermore, it is preferable to have an oxidation treatment step for oxidizing the wastewater from which ammonia has been volatilized and a precipitation separation step for precipitating and separating heavy metals in the oxidized wastewater between the ammonia removal step and the membrane separation step. .
Moreover, between the said ammonia removal process and a membrane separation process, it has the precipitation separation process which carries out precipitation separation of the heavy metal in the wastewater which volatilized and removed ammonia, and the oxidation treatment process which oxidizes the wastewater which carried out precipitation separation of the heavy metal Is preferred.
Furthermore, it is preferable that the oxidation treatment step is performed by adding at least one oxidizing agent selected from the group consisting of hypochlorous acid, chlorous acid, perchloric acid, and salts thereof.

Further, the wastewater treatment apparatus of the present invention is a wastewater treatment apparatus containing heavy metals and ammonia, wherein an alkaline agent is added to the wastewater to volatilize and remove the ammonia, and the wastewater from which the ammonia has been volatilized and removed is formed into a membrane. And a membrane separation means for separating.
Moreover, it is preferable that the said ammonia removal means is equipped with the aeration means to aerate wastewater.
Furthermore, it is preferable to provide an oxidation treatment means for oxidizing the wastewater before membrane separation from which ammonia has been volatilized and removed.
Moreover, it is preferable to provide precipitation separation means for precipitating and separating heavy metals in the wastewater before membrane separation from which ammonia has been volatilized and removed.
Furthermore, oxidation treatment means for oxidizing the wastewater before membrane separation from which ammonia has been removed by volatilization, and heavy metals in wastewater after oxidation treatment and before membrane separation, or heavy metals in wastewater before oxidation treatment from which ammonia has been volatilized and removed are precipitated. It is preferable to provide a precipitation separation means for separation.
Further, it is preferable that an oxidation treatment means, a precipitation separation means, and a membrane separation means are provided in this order downstream of the ammonia removal means.

  According to the wastewater treatment method and treatment apparatus of the present invention, wastewater containing heavy metals and ammonia can be treated at a low cost and highly without adding a flocculant, and the concentration of heavy metals can be sufficiently reduced.

It is a schematic block diagram which shows an example of the wastewater processing apparatus of this invention. It is a schematic block diagram which shows the other example of the wastewater processing apparatus of this invention. It is a schematic block diagram which shows the other example of the wastewater processing apparatus of this invention. It is a schematic block diagram which shows the other example of the wastewater processing apparatus of this invention. It is a schematic block diagram which shows the other example of the wastewater processing apparatus of this invention. It is a schematic block diagram which shows the other example of the wastewater processing apparatus of this invention. It is a schematic block diagram which shows the other example of the wastewater processing apparatus of this invention.

Hereinafter, the present invention will be described in detail.
[Wastewater treatment equipment]
FIG. 1 is a schematic configuration diagram showing an example of a wastewater treatment apparatus of the present invention. The wastewater treatment apparatus 1 in this example includes a storage unit 10 that temporarily stores the wastewater W ₀ , an ammonia removal unit 20, a membrane separation unit 30, and a pH adjustment unit 40 in order from the upstream side. ing.
2-7, the same code | symbol is attached | subjected to the same component as FIG. 1, and the description is abbreviate | omitted.

<Waste water>
The waste water W ₀ to be treated in the present invention is a waste liquid (treated water) generated from a metal surface treatment factory such as a plating factory, and contains heavy metals and ammonia. Heavy metals are likely to form ammine complexes with ammonia, and as a result, are considered to be stably dissolved in wastewater.
Examples of heavy metals include chromium, copper, zinc, cadmium, nickel, mercury, lead, and iron. These heavy metals may be contained alone, but are usually contained in a state where a plurality of heavy metals are mixed.
On the other hand, ammonia includes an ammonium salt.

In the wastewater W ₀ , in addition to heavy metals and ammonia, cleaning components, surfactants, Lewis acids, and complex forming compounds other than ammonia (for example, citric acid, gluconic acid, oxalic acid, tartaric acid, succinic acid, Cyanide and salts thereof, EDTA, ethylenediamine, triethanolamine, etc.) may be contained. Hereinafter, complex-forming compounds other than ammonia are referred to as “other complex-forming compounds”.

<Storage means>
The storage means 10 is a means for temporarily storing waste water W ₀ generated from a metal surface treatment factory or the like.
The storage means 10 includes a storage tank 11. The storage tank 11 is not particularly limited as long as it can store the waste water W _0.

<Ammonia removal means>
The ammonia removing means 20 is a means for adding an alkali agent and volatilizing and removing ammonia in the waste water W ₀ by a method such as stripping treatment or heat treatment.
Here, the stripping process is a process in which impurities to be treated are brought into gas-liquid contact with a liquid such as air or water vapor (that is, the liquid to be treated is aerated), and impurities are introduced from the liquid phase to the gas phase. It is a process of removing impurities from the liquid to be treated by moving it.
By the way, when the impurities are volatilized and removed from the wastewater, it is difficult to remove the ionized molecules. Therefore, it is necessary to adjust the pH to change to a free state. When removing ammonia from wastewater by stripping treatment (ammonia stripping treatment) or heat treatment, as shown in the following formula, an alkaline agent is added to the wastewater to make it alkaline, and the ammonia component contained in the wastewater A certain ammonium ion (NH ₄ ⁺ ) and a hydroxide ion (OH ⁻ ) are reacted to release the generated ammonia gas (NH ₃ ) into the atmosphere.
NH ₄ ⁺ (ionization state) + OH ⁻ → NH ₃ (free state) + H ₂ O

The ammonia removing unit 20 shown in FIG. 1 is a unit that volatilizes and removes ammonia by a stripping process. In the present invention, the ammonia removing means when the ammonia is volatilized and removed by stripping treatment may be referred to as “stripping means”.
The ammonia removing means (stripping means) 20 shown in FIG. 1 includes a stripping tank 21 for storing waste water W ₀ sent from the storage means 10 and an alkali agent addition for adding an alkali agent to the waste water W ₀ in the stripping tank 21. It provided with means 22, the water gauge 23 for inspecting the quality of waste water W ₀ in the stripping tank 21, and a diffuser means 24 for aerating the waste water W ₀ in the stripping vessel 21.

The stripping tank 21 is not particularly limited as long as it can store the waste water W ₀ , but is preferably made of a material that is not easily deteriorated by an alkaline agent.
The alkali agent adding means 22 is not particularly limited as long as an alkali agent can be added.

The water quality meter 23 inspects the water quality of the waste water W ₀ in the stripping tank 21. By checking the water quality, it is possible to grasp the excess and deficiency of the added amount of the alkaline agent.
Examples of the water quality meter 23 include an ammonium ion concentration meter, an alkaline agent concentration meter, and a pH meter.
In addition, although the ammonia removal means (stripping means) 20 of this example is provided with one water quality meter 23, it may be provided with a plurality of types of water quality meters according to the water quality inspection method.

The air diffuser 24 aerates the waste water W ₀ in the stripping tank 21. The air diffuser 24 is provided at the bottom of the stripping tank 21 and diffuses the air supplied from the blower B1 into the stripping tank 21. Thus, continuously or intermittently diffuser air bubbles from the air diffuser means 24 is released from the surface through the liquid of the waste water W _0. At this time, the wastewater W ₀ and the air are in gas-liquid contact, and ammonia gas (NH ₃ ) moves from the liquid phase to the gas phase and is released into the atmosphere.

The ammonia in the waste water W ₀ is volatilized and removed by the ammonia removing means (stripping means) 20. As a result, the heavy metal cannot maintain the form of a complex with ammonia and is ionized. Furthermore, since the waste water W ₀ in the stripping tank 21 is alkaline at this point by the addition of an alkaline agent, the heavy metal becomes a hardly soluble hydroxide (insolubilized product) and precipitates from the waste water W ₀ .

<Membrane separation means>
The membrane separation means 30 is means for separating the waste water W ₀ from which ammonia has been volatilized and removed by the ammonia removal means (stripping means) 20 into filtered water W ₁ and membrane separation concentrated water W ₂ .
The membrane separation means 30 in this example is a system in which pressure is applied by a pressure pump P1 and includes a filtration membrane 31.
Examples of the filtration membrane 31 include a hollow fiber membrane, a flat membrane, a tubular membrane, and a monolith type membrane. A hollow fiber membrane is preferable because of its high volume filling rate.
When a hollow fiber membrane is used as the filtration membrane 31, examples of the material include cellulose, polyolefin, polysulfone, polyvinylidene fluoride (PVDF), and polytetrafluoroethylene (PTFE).
When a monolith type membrane is used as the filtration membrane 31, a ceramic membrane can be used.

The average pore diameter of the micropores formed in the filtration membrane 31 is generally an average pore size of 0.001 to 0.1 μm for a membrane called an ultrafiltration membrane, and an average pore size of 0.1 to 1 μm for a membrane commonly called a microfiltration membrane. In the present invention, these films are preferably used.
In addition, since the particle diameter of the insolubilized heavy metal produced by volatilizing and removing ammonia from the wastewater ₀ is generally 0.1 to 100 μm, the average pore diameter of the fine pores of the filtration membrane 31 is 0.03 μm or more. It is preferable that When the average pore diameter is less than 0.03 μm, the pressure required for membrane separation increases, and the operating energy becomes excessive. On the other hand, the average pore diameter of the fine pores of the filtration membrane 31 is preferably 3 μm or less. When the average pore diameter exceeds 3 μm, the proportion of particles of insolubilized heavy metal leaking to the secondary side (in the filtered water W ₁ ) of the filtration membrane 31 increases, and the metal concentration in the filtered water W ₁ tends to increase. .

The membrane separation means 30 separates the waste water W ₀ into filtered water W ₁ from which insolubilized substances have been removed and membrane separation concentrated water W ₂ from which insolubilized substances have been concentrated.
The filtered water W ₁ is transferred to pH adjusting means 40 described later, and pH is adjusted. On the other hand, membrane separation concentrated water W ₂ is typically dehydrated by the dehydration means (not shown), it is treated as industrial wastes such as dehydrated cake.

<PH adjusting means>
The pH adjusting means 40 is a means for adjusting the pH of the filtered water W ₁ membrane-separated by the membrane separating means 30 to a pH suitable for discharge to a river or the like. The pH-adjusted filtered water W ₁ is treated. It is discharged as water _{W 3.}
Incidentally, the film since the sufficiently remove the insolubles by separation means 30, heavy metals and neutralize the pH of the filtered water W ₁ there is no fear of remelting.

The pH adjusting means 40 includes a pH adjusting tank 41, a pH meter (not shown), an acid addition device and an alkali addition device (both not shown).
The pH adjusting tank 41 is not particularly limited as long as it can store the filtered water W _1. Further, the pH meter, the acid addition device, and the alkali addition device are not particularly limited as long as they are used for pH adjustment.

<Effect>
As mentioned above, if wastewater containing heavy metals contains ammonia, the heavy metals form ammonia and an ammine complex and are stably dissolved in the wastewater, which makes it difficult to treat the wastewater. It is believed that there is.
However, according to the wastewater treatment apparatus 1 of the present invention, the ammonia removal means (stripping means) 20 is provided on the upstream side of the membrane separation means 30, so that the wastewater W ₀ is subjected to membrane separation after the ammonia is volatilized and removed. Is done. That is, ammonia in the waste water W _0, so is volatilized and removed from the wastewater W ₀ before the membrane separation, the heavy metal will not be able to maintain the form of a complex, ionized. Further, since the waste water W ₀ in the stripping tank 21 is alkaline at this point, the heavy metal becomes a hardly soluble hydroxide (insolubilized material) and is precipitated from the waste water W ₀ . As described above, the wastewater treatment apparatus 1 of the present invention is capable of highly treating the wastewater W ₀ because the insolubilization of heavy metal by ammonia is hardly inhibited and the heavy metal insolubilized by the membrane separation means 30 can be membrane-separated. The heavy metal concentration in the water W ₃ can be sufficiently reduced.

Further, the wastewater treatment apparatus 1 of the present invention can sufficiently insolubilize heavy metals while volatilizing and removing ammonia in the wastewater W ₀ by the ammonia removing means (stripping means) 20 without adding a flocculant. In addition, since it is not necessary to add an insolubilizing agent to insolubilize heavy metals, the cost of medicine can be reduced. Moreover, energy is not consumed excessively.

Processing apparatus 1 of the waste water of the present invention is an apparatus for processing waste water W ₀ containing heavy metals and ammonia, in particular or an electroless plating process such as electroless nickel plating, treating the waste water discharged from the acidic zinc plating process It is suitable for doing.

<Other embodiments>
The wastewater treatment apparatus of the present invention is not limited to the wastewater treatment apparatus 1 shown in FIG. In the processing apparatus 1 of the waste water shown in FIG. 1 for example, is provided with the pH adjustment unit 40, if the pH at which the pH of the filtered water W ₁ is suitable for discharge into rivers or the like, not provided with a pH adjusting means 40 May be.

Further, the wastewater treatment apparatus 1 shown in FIG. 1 includes the full-volume type membrane separation means 30, but may be a cross-flow type membrane separation means 30 as shown in FIG. 2.
In the wastewater treatment apparatus 2 shown in FIG. 2, a part of the membrane separation concentrated water W ₂ separated by the membrane separation means 30 is returned to the stripping tank 21 of the preceding ammonia removal means (stripping means) 20. However, a part of the membrane separation concentrated water W ₂ may be returned to the storage tank 11 of the storage means 10.

The membrane separation means 30 provided in the wastewater treatment apparatuses 1 and 2 shown in FIGS. 1 and 2 are both pressurized, but the membrane separation means 30 may be of an immersion type as shown in FIG.
Membrane separation means 30 of the processor 3 of waste water shown in Figure 3, a membrane separation tank 32 for storing the waste water W ₀ sent from the ammonia removal unit (stripping section) 20, film provided in the membrane in the separation tank 32 A module 33 and an air diffuser 34 for cleaning the membrane are provided. A suction pump P2 is connected to the membrane module 33, and a blower B2 is connected to the air diffuser 34.

Examples of the membrane module 33 include normal membrane modules used for separation operations such as water treatment. In the membrane module 33, the waste water W ₀ in the membrane separation tank 32 is suction filtered through the pores of the filtration membrane of the membrane module 33 by the suction pump P 2, whereby the waste water W ₀ is filtered with the filtrate W ₁ and the membrane separation concentrated water W. ₂ and separated.
On the other hand, the air diffuser 34 is provided below the membrane module 33 and diffuses the air sent from the blower B2 into the membrane separation tank 32. Thus, continuously or intermittently diffuser air bubbles from the air diffuser means 34, through the liquid of the waste water W ₀ reaches a membrane module 33, then, is discharged from the water surface. At this time, the filtration membrane is washed.
A part of the membrane separation concentrated water W ₂ separated by the membrane separation means 30 may be returned to the stripping tank 21 or the storage tank 11.

(Oxidation treatment means)
Also, waste water treatment apparatus of the present invention, for example, as shown in FIG. 4, between the ammonia removal unit (stripping section) 20 and the membrane separation means 30, an oxidation treatment of waste water W ₀ ammoniated volatiles removed It is preferable to provide an oxidation treatment means 50.
When the waste water W ₀ contains other complex-forming compounds, the oxidation treatment means 50 oxidizes the waste water W ₀ to decompose the other complex-forming compounds. Further, when the ammonia removal means (stripping means) 20 in the previous stage cannot completely remove ammonia, the ammonia remaining in the waste water W ₀ is also decomposed by the oxidation treatment means 50. As a result, since the heavy metal in the waste water W ₀ is more easily insolubilized, the insoluble matter is easily separated by the membrane separation means 30 at the subsequent stage, and the heavy metal concentration in the treated water W ₃ can be further reduced. In addition, since the insolubilized material becomes coarse by oxidizing the wastewater W ₀ , the filtration membrane 31 of the membrane separation means 30 is not easily clogged with the insolubilized material, and the membrane separation means 30 can be operated stably for a long period of time. Is possible.

The oxidation treatment means 50 of the wastewater treatment apparatus 4 shown in FIG. 4 includes an oxidation tank 51 that accumulates waste water W ₀ sent from the ammonia removal means (stripping means) 20, and an oxidant in the waste water W ₀ in the oxidation tank 51. Is provided with an oxidant addition means 52 for adding water and a water quality meter 53 for inspecting the water quality of the waste water W ₀ in the oxidation tank 51.

The oxidation tank 51 is not particularly limited as long as it can store the wastewater W ₀ , but is preferably made of a material that is not easily deteriorated by the oxidizing agent.
The oxidizing agent adding means 52 is not particularly limited as long as an oxidizing agent can be added.
The water quality meter 53 inspects the water quality of the waste water W ₀ in the oxidation tank 51. By examining the water quality, it is possible to grasp the excess and deficiency of the added amount of the oxidant, and in particular, it is effective for suppressing the excessive addition of the oxidant.
Examples of the water quality meter 53 include an oxidation-reduction potentiometer and an oxidant concentration meter. It is also possible to use a densitometer for measuring the concentrations of ammonia and other complex forming compounds in place of or in combination with these electrometers and densitometers. However, a densitometer for measuring the concentration of another complex-forming compound is used when treating waste water W ₀ containing another complex-forming compound capable of measuring the concentration.
In addition, although the oxidation treatment means 50 of this example is provided with one water quality meter 53, it may be provided with a plurality of types of water quality meters according to the water quality inspection method.

Moreover, although the wastewater treatment apparatus 4 shown in FIG. 4 is provided with the same thing as the wastewater treatment apparatus 1 shown in FIG. 1 as the membrane separation means 30, of the wastewater treatment apparatuses 2 and 3 shown in FIG. The same as the membrane separation means 30 may be used.
In addition, in the oxidation treatment means 50, when a chlorine-based oxidant is added from the oxidant addition means 52, an odor component such as chlorine gas or chloramine due to ammonia oxidation may be generated. Therefore, it is desirable to appropriately install gas recovery means according to the generated concentration.

(Precipitation separation means)
In addition, as shown in FIG. 5, for example, the wastewater treatment apparatus of the present invention removes heavy metals in wastewater W ₀ from which ammonia is volatilized and removed between ammonia removing means (stripping means) 20 and membrane separating means 30. It is preferable to provide precipitation separation means 60 for separating the precipitate.
Precipitation separation means of the processing device 5 of the waste water shown in Fig. 5 60 includes a settling tank 61 for storing the waste water W ₀ sent from the ammonia removal unit (stripping section) 20.
The structure of the precipitation tank 61 is not particularly limited, and an effective surface area may be increased by installing an inclined plate inside the precipitation tank 61.
Moreover, what is necessary is just to set suitably about the volume of the sedimentation tank 61 according to the solid content density | concentration of a process target liquid, and the magnitude | size of process target particle | grains (insoluble matter of heavy metal).

The waste water W ₀ is separated into the supernatant liquid W ₄ and the precipitated concentrated water W ₅ by the precipitation separation means 60.
The supernatant liquid W ₄ is transferred to the subsequent membrane separation means 30 and further membrane-separated into filtered water W ₁ and membrane separation concentrated water W ₂ . The supernatant W ₄ contains fine heavy metal insolubilized material that has not been completely removed by the precipitate separating means 60, but the fine insoluble material is removed by the membrane separating means 30.
On the other hand, precipitated the concentrate W ₅ is usually dehydrated by the dehydration means (not shown), it is treated as industrial wastes such as dehydrated cake.

If the precipitation separation means 60 is provided between the ammonia removal means (stripping means) 20 and the membrane separation means 30 as in the wastewater treatment apparatus 5 shown in FIG. In addition, most of the heavy metals in the waste water W ₀ insolubilized in the ammonia removing means (stripping means) 20 can be removed from the waste water W ₀ . Accordingly, since the amount of particles removed by the membrane separation means 30 is reduced, the burden on the membrane separation means 30 is reduced, and a more stable filtration operation can be continued.
The wastewater treatment apparatus 5 shown in FIG. 5 includes the same membrane separation means 30 as the treatment apparatus 1 shown in FIG. 1, but the membrane separation of the wastewater treatment apparatuses 2 and 3 shown in FIGS. The same means 30 may be used.

In addition, the wastewater treatment apparatus of the present invention may include both the oxidation treatment means and the precipitation separation means in parallel between the ammonia removal means and the membrane separation means. When both the oxidation treatment means and the precipitation separation means are provided, the order of these installations is not particularly limited, and a precipitation separation means for precipitating and separating heavy metals in the wastewater after the oxidation treatment may be installed downstream of the oxidation treatment means. And the precipitation separation means which carries out precipitation separation of the heavy metal in the wastewater before the oxidation process which volatilized and removed ammonia from the upstream of an oxidation treatment means may be installed.
By the way, particles of insolubilized heavy metal produced in the ammonia removing means tend to be fine, and when a precipitation separating means is provided, the precipitation rate may be slow. When the sedimentation rate is slow, it may be necessary to take measures such as increasing the size of the sedimentation tank.
However, if an oxidation treatment means, a precipitation separation means, and a membrane separation means are sequentially provided downstream of the ammonia removal means, the heavy metal insolubilized material coarsened by the oxidation treatment means can be precipitated and separated by the precipitation separation means. Therefore, the precipitation rate can be increased, and heavy metals can be precipitated in a short time in the precipitation separation means. Moreover, it is not necessary to enlarge the sedimentation tank.

1-5, the ammonia removal means (stripping means) 20 and the membrane separation means are independent of each other. For example, as shown in FIG. The membrane separation tank 32 may also be used as a stripping tank.
That is, in the wastewater treatment apparatus 6 shown in FIG. 6, the alkaline agent addition means 22 of the ammonia removal means (stripping means) 20, the water quality meter 23, and the aeration means 24 are composed of a membrane separation tank of the membrane separation means 30. 32. Further, the membrane separation tank 32 of the wastewater treatment apparatus 6 shown in FIG. 6 also serves as the oxidation tank of the oxidation treatment means 50, and the oxidizing agent addition means 52 of the oxidation treatment means 50 and the water quality meter 53 are also included in the membrane separation tank 32. Is provided. Furthermore, the membrane separation tank 32 may also serve as a precipitation tank for precipitation separation means.
The membrane separation means 30 in this example includes a membrane module 33 similar to the membrane separation means 30 shown in FIG.

In the case of the wastewater treatment apparatus 6 shown in FIG. 6, the membrane separation tank 32 also serves as a stripping tank, an oxidation tank, and, if necessary, a settling tank, so that the apparatus configuration is simplified.
Further, for example, as in the wastewater treatment apparatus 7 shown in FIG. 7, the air diffusion means 34 of the membrane separation means 30 may be used as the air diffusion means of the ammonia removing means (stripping means) 20, and the apparatus configuration is Furthermore, it becomes simple.

  The ammonia removal means 20 of the wastewater treatment apparatuses 1 to 7 shown in FIGS. 1 to 7 described above is means for stripping and removing ammonia by stripping treatment (stripping means). A means for volatilizing and removing ammonia (heat treatment means) may be used. Since the heat treatment is usually performed at room temperature (23 ° C.) or higher, when a heat treatment means is used as the ammonia removing means 20, a heating for heating the wastewater instead of the aeration means 24 provided in the stripping means 20. It is preferable to provide a heating means for heating the means or waste water.

In this way, the wastewater treatment apparatus of the present invention can treat wastewater at a low cost and high degree without adding a coagulation means for coagulating an insolubilized material by adding a flocculant to the wastewater, and reducing the heavy metal concentration. Although it can be sufficiently reduced, an aggregating means may be provided if necessary. However, the smaller the amount of the flocculant added to the waste water by the flocculating means, the more the chemical cost can be reduced and the sludge amount generated can be reduced, so that the sludge disposal cost can also be reduced. Moreover, it can suppress that the film | membrane of a membrane filtration means obstruct | occludes. Therefore, when the target treated water quality can be achieved without the aggregation means, it is preferable not to provide the aggregation means.
In the case where the coagulation means is provided, the installation location is between the ammonia removal means and the membrane separation means, and in the case where the oxidation treatment means is provided, the position is between the oxidation treatment means and the membrane separation means, and the precipitation separation means is provided. In some cases, it is between the ammonia removing means and the precipitation separating means. In the case where the precipitation separating means is provided downstream of the oxidation treating means, it is between the oxidation treating means and the precipitation separating means.

Further, in the wastewater treatment apparatus of the present invention, the wastewater becomes alkaline by adding an alkaline agent in the ammonia removing means, even without providing an insolubilizing means for insolubilizing heavy metals by adding an insolubilizing agent to the wastewater. For this reason, heavy metals in wastewater are insolubilized and wastewater can be treated at a high level, but if necessary, insolubilization means may be provided. However, the smaller the amount of the insolubilizing agent added to the waste water by the insolubilizing means, the lower the drug cost. Therefore, when the target treated water quality can be achieved without the insolubilizing means, it is preferable not to provide the insolubilizing means.
In the case where the insolubilizing means is provided, the installation location is between the ammonia removing means and the membrane separation means, and in the case where the oxidation treatment means is provided, between the oxidation treatment means and the membrane separation means, and the precipitation separation means is provided. In some cases, it is between the ammonia removing means and the precipitation separating means. In the case where the precipitation separating means is provided downstream of the oxidation treating means, it is between the oxidation treating means and the precipitation separating means.

[Wastewater treatment method]
The wastewater treatment method of the present invention includes an ammonia removal step in which an alkaline agent is added to wastewater and ammonia is volatilized and removed by a method such as stripping treatment or heat treatment, and a membrane separation step in which wastewater from which ammonia has been volatilized and removed is subjected to membrane separation. Have
Hereinafter, an example of the wastewater treatment method of the present invention will be specifically described using the wastewater treatment apparatus 1 shown in FIG.
In the present invention, the ammonia removing step in which ammonia is volatilized and removed by stripping treatment may be referred to as “stripping step”.

<Ammonia removal process (stripping process)>
First, the waste water W ₀ is temporarily stored in the storage tank 11 of the storage means 10.
Then, the waste water W ₀ stored in the storage tank 11 and transferred to the stripping vessel 21 of ammonia removal means (stripping section) 20, by adding an alkali agent from alkaline agent addition means 22, the ammonia in the waste water W ₀ Volatilization is removed by stripping.
Sodium hydroxide, sodium carbonate, calcium hydroxide, magnesium hydroxide, etc. are used as the alkaline agent used in the ammonia removal step (stripping step). Among these, sodium hydroxide is preferable because sludge generation can be reduced.

The amount of the alkali agent added may be set as appropriate depending on the ammonia concentration of the wastewater W ₀ and the type of heavy metal to be removed. However, since ammonia is basic, the ammonia volatilization removal efficiency tends to increase as the pH increases. is there. Therefore, it is preferable to adjust the addition amount of the alkaline agent so that the pH of the waste water W ₀ is 10 to 11.
The alkali agent may be added using the water quality meter 23 while monitoring the ammonium ion concentration, the alkali agent concentration, the pH of the wastewater W ₀ , and the like.

Further, when the stripping process, the air that has been blown from the blower B1 is air diffusion by the air diffuser unit 24 to the stripping tank 21, aerating the waste water W _0, ammonia gas (NH ₃₎ into the atmosphere Release.
In general, the amount of air diffused per unit waste water volume (aeration volume) is required to be 3,000 (m ³ -air) / (m ³ -waste water) or more. However, since it varies depending on the ammonia concentration, the target treated water quality, and the performance of the air diffuser 24, an appropriate amount may be set.

Further, since ammonia is volatile, the ammonia removal efficiency by the stripping treatment is easily affected by the water temperature, and the ammonia removal efficiency tends to be higher as the water temperature is higher. Therefore, it is preferable that the temperature of the waste water W ₀ in the stripping tank is higher.

Ammonia in the wastewater W ₀ is volatilized and removed by the ammonia removal step (stripping step). As a result, the heavy metal cannot maintain the form of a complex with ammonia and is ionized. Furthermore, since the waste water W ₀ in the stripping tank 21 is alkaline due to the addition of the alkaline agent at this time, the heavy metal becomes a hardly soluble hydroxide (insolubilized material) and is precipitated from the waste water W ₀ .

<Membrane separation process>
In the membrane separation step, the waste water W ₀ from which ammonia has been volatilized and removed in the ammonia removal step (stripping step) is transferred to the membrane separation means 30, and the filtered water W _{1 from} which the insoluble matter has been removed by the filtration membrane 31 and the insolubilized matter film is separated into a concentrated membrane separation concentrated water W _2.
Filtered water W ₁ may be pH adjusted by the pH adjustment step described below as required. On the other hand, membrane separation concentrated water W ₂ is usually dehydrated, it is treated as industrial wastes such as dehydrated cake.

<PH adjustment step>
In pH adjustment step, transferring the filtered water _{W 1} to pH adjustment tank 41 of the pH adjusting means 40, the pH of the filtered water _{W 1} is adjusted to pH suitable for discharge into rivers. Since the alkaline agent is added in the ammonia removal step (stripping step), the filtered water W ₁ is often alkaline and should be neutralized. The filtered water W ₁ whose pH has been adjusted is discharged as treated water W ₃ .
In the pH adjustment step, an acid such as hydrochloric acid, sulfuric acid, carbon dioxide is used as a pH adjuster for neutralization. When an excessive amount of acid is added in the pH adjustment process, an alkali such as sodium hydroxide, sodium carbonate, calcium hydroxide, magnesium hydroxide or the like is added as a pH adjuster, and the pH is adjusted again to be in a neutral region. adjust.
Incidentally, since the sufficiently remove the insolubles by membrane separation process, heavy metals and neutralize the pH of the filtered water W ₁ there is no possibility to re-dissolve.

<Effect>
As mentioned above, if wastewater containing heavy metals contains ammonia, the heavy metals form ammonia and an ammine complex and are stably dissolved in the wastewater, which makes it difficult to treat the wastewater. It is believed that there is.
However, according to the wastewater treatment method of the present invention, the ammonia removal step (stripping step) is performed before the membrane separation step, so the wastewater W ₀ is membrane-separated after the ammonia is volatilized and removed. That is, ammonia in the waste water W _0, so is volatilized and removed from the wastewater W ₀ before the membrane separation, the heavy metal will not be able to maintain the form of a complex, ionized. Further, since the waste water W ₀ from which ammonia has been volatilized and removed is alkaline at this point, the heavy metal becomes a hardly soluble hydroxide (insolubilized material) and precipitates from the waste water W ₀ . Thus, if the method of processing waste water of the present invention, hardly obstructed insolubilization of heavy metals with ammonia, since the heavy metals insoluble by membrane separation step can be membrane separation, can be processed highly wastewater W _0, treated water W The heavy metal concentration in ₃ can be sufficiently reduced.

Moreover, according to the wastewater treatment method of the present invention, heavy metals can be sufficiently insolubilized while volatilizing and removing ammonia in the wastewater W ₀ by an ammonia removal step (stripping step) without adding a flocculant. In addition, since it is not necessary to add an insolubilizing agent to insolubilize heavy metals, the cost of medicine can be reduced. Moreover, energy is not consumed excessively.

The wastewater treatment method of the present invention is a method for treating wastewater W ₀ containing heavy metals and ammonia, and in particular, treats wastewater discharged from an electroless plating process such as electroless nickel plating or an acidic zinc plating process. It is suitable for.

<Other embodiments>
The wastewater treatment method of the present invention is not limited to the method described above. For example, in the above-described method, it performs the pH adjustment step after the membrane separation step, if the pH at which the pH of the filtered water W ₁ is suitable for discharge into rivers or the like, pH adjustment step may not be performed.

Further, in the above-described method, the method using the whole-volume type membrane separation means 30 as shown in FIG. 1 is exemplified as the membrane separation method in the membrane separation step. For example, a cross-flow type membrane as shown in FIG. Separation means 30 or immersion type membrane separation means 30 as shown in FIG. 3 may be used.
The full-volume type membrane separation means 30 shown in FIG. 1 and the cross-flow type membrane separation means 30 shown in FIG. 2 employ a pressure type, and the primary side of the membrane is high with the filtration membrane 31 sealed in a container. Can be pressurized with pressure. Therefore, the membrane can be separated with a high permeation flux, and the required membrane area can be reduced. However, when the insolubilized substance concentration (turbidity concentration) of the liquid to be treated is high, the filtration membrane 31 tends to be clogged. Therefore, it is preferable to carry out when the insolubilized substance concentration of the liquid to be treated is low.
On the other hand, the immersion-type membrane separation means 30 shown in FIG. 3 performs filtration by immersing the membrane module 33 in the liquid to be treated and setting the secondary side of the membrane to a negative pressure. Therefore, although the permeation flux is lower than that of the pressurization type, membrane separation can be performed without clogging the filtration membrane even if the concentration of insolubilized material is high.

(Oxidation process)
In addition, the wastewater treatment method of the present invention uses, for example, the treatment device 4 shown in FIG. 4 to oxidize wastewater from which ammonia has been volatilized and removed between the ammonia removal step (stripping step) and the membrane separation step. It is preferable to have a processing step. In the oxidation treatment step, the waste water W ₀ from which ammonia has been removed by volatilization is transferred to the oxidation tank 51 of the oxidation treatment means 50, and an oxidant is added from the oxidant addition means 52 to oxidize the waste water W ₀ .
If the waste water W ₀ contains other complexing compounds, by oxidizing the waste water W _0, other complex forming compound is decomposed by oxidation treatment step. Further, when the ammonia cannot be completely removed in the preceding ammonia removal step (stripping step), the ammonia remaining in the wastewater W ₀ is also decomposed by the oxidation treatment step. As a result, since the heavy metal in the waste water W ₀ is more easily insolubilized, the insoluble matter is easily separated in the subsequent membrane separation step, and the heavy metal concentration in the treated water W ₃ can be further reduced. In addition, since the insolubilized heavy metal is coarsened by oxidizing the waste water W ₀ , the filtration membrane 31 is not easily clogged with the insolubilized material in the membrane separation step, and the membrane separation step can be performed stably over a long period of time. It is.

Examples of the oxidizing agent used in the oxidation treatment step include hypochlorous acid, chlorous acid, perchloric acid or salts thereof, and hydrogen peroxide. Among these, hypochlorous acid, chlorous acid, perchloric acid or a salt thereof, or a mixed solution thereof is preferable, and a sodium hypochlorite solution is particularly preferable from the viewpoints of handleability and availability.
If hypochlorous acid, chlorous acid, perchloric acid or a salt thereof, or a mixed solution thereof is used as an oxidizing agent, the oxidation reaction easily proceeds quickly, and the overall processing speed can be increased. In addition, since the decomposition efficiency of other complex-forming compounds having a chelating action such as EDTA and tartaric acid is high, the inhibition of aggregation of insolubilized materials by other complex-forming compounds can be prevented, and the insolubilization of heavy metals can be made more efficient. And the insolubilized material can be made coarser.

In particular, when sodium hypochlorite or a solution thereof is used as an oxidizing agent, the particle diameter of the heavy metal insolubilized product tends to increase. When the particle size of the insolubilized material is larger, the pores of the filtration membrane can be suppressed from being blocked in the membrane separation step, and the membrane flux can be maintained high.
Furthermore, when the waste water W ₀ is waste water containing nickel as a heavy metal such as electroless nickel plating waste water, dissolved nickel ions are converted into nickel oxyhydroxide (NiO (OH) by adding an oxidizing agent such as sodium hypochlorite. )) Oxidized. Since nickel oxyhydroxide generally has a lower solubility than nickel hydroxide (Ni (OH) ₂ ), sodium hypochlorite or a solution thereof is an oxidizing agent when performing advanced wastewater treatment. Is particularly preferred.

The addition of the oxidizing agent to the waste water W _0, in addition to or complex forming compound contained in the wastewater W _0, the ammonia could not be removed in the ammonia removal process (stripping step) by the purpose of the oxidation treatment In addition, excessive addition of an oxidizing agent results in excessive consumption of chemicals. Moreover, when an oxidizing agent is added excessively, there exists a possibility that the filtration membrane used at a membrane separation process may be oxidized with the remaining oxidizing agent. In addition, when an oxidizing agent is excessively added, the amount of sludge that is finally generated tends to increase.
From the above, when the oxidation treatment process that all oxidizing other complex-forming compounds and ammonia contained in the waste water W _0, it is desirable to stop the addition of the oxidizing agent to the waste water W _0, the excessive addition It is good to control.
Examples of the method for detecting the end point of addition of the oxidant include a method of monitoring the oxidation-reduction potential using the water quality meter 53, monitoring of the oxidant concentration, and monitoring the concentration of other complex-forming compounds and ammonia.

Monitoring of redox potential;
If other complex-forming compounds and ammonia remain in the wastewater W ₀ , the added oxidizing agent is consumed by an oxidation-reduction reaction with the other complex-forming compounds and ammonia. While the oxidant is consumed by oxidation of other complex-forming compounds and ammonia, the redox potential of the wastewater W ₀ is low, and other complex-forming compounds and ammonia that can be oxidatively decomposed are all oxidized to leave the oxidant. oxidation-reduction potential of waste water W ₀ is higher.
Therefore, if the oxidation-reduction potential of the wastewater W ₀ in the oxidation tank 51 is monitored by the water quality meter (oxidation-reduction potentiometer) 53, another complex capable of oxidative decomposition in the wastewater W ₀ when the oxidation-reduction potential increases. It can be easily determined that all of the forming compound and ammonia have been oxidized, and the addition of the oxidizing agent may be stopped at this point.

Monitoring of oxidant concentration;
If other complex-forming compounds and ammonia remain in the wastewater W ₀ , the added oxidizing agent is consumed. That is, in the process of continuously adding the oxidizing agent, the oxidizing agent concentration is low and remains substantially constant while other complex-forming compounds to be oxidized and ammonia remain.
Therefore, if the concentration of the oxidizing agent in the oxidation tank 51 is monitored by the water quality meter (oxidizing agent concentration meter) 53, when the oxidizing agent concentration increases, other complex-forming compounds that can be oxidatively decomposed in the wastewater W ₀ It can be easily determined that all the ammonia has been oxidized, and the addition of the oxidizing agent should be stopped at this point.
When hypochlorous acid, chlorous acid, perchloric acid, or a salt thereof is used as the oxidant, the oxidant concentration can also be obtained by measuring the residual chlorine concentration.

Monitoring the concentration of other complexing compounds and ammonia;
Other complex forming compound and ammonia in the waste water W ₀ continuously monitored, these concentrations may be terminated by adding oxidizing agent at the time of the drop well. Note that the method of monitoring the concentration of another complex-forming compound can be applied when the other complex-forming compound is a substance that can be monitored with a water quality meter.

  Among the above-described methods for detecting the end point of addition of the oxidant, the oxidation-reduction potentiometer used as the water quality meter 53 is preferably monitored by the oxidation-reduction potential because it is easy to use. The redox potential can be monitored continuously (continuous measurement), while the oxidant concentration and other complex-forming compounds and ammonia concentrations can be monitored batchwise (measured by taking samples at regular intervals). ), The oxidation-reduction potential monitoring can detect the oxidant addition end point more instantaneously than the other methods.

When the end point of the addition of the oxidizing agent is detected by monitoring the oxidation-reduction potential, the following is preferable.
That is, it is preferable to measure in advance the oxidation-reduction potential at the timing when the oxidant concentration increases (the addition of oxidant becomes excessive). Thereby, since the value of the oxidation-reduction potential measured in advance can be used as a criterion, it is possible to more easily determine the timing of stopping the addition of the oxidizing agent.

However, it is difficult to determine whether or not the addition amount of the oxidant is insufficient in the monitoring of the oxidation-reduction potential or the oxidant concentration. In such a case, the amount of oxidant necessary to oxidize all other complex-forming compounds and ammonia from the concentration of other complex-forming compounds and ammonia in the wastewater W ₀ is predicted, and the predicted amount Add a larger amount of oxidizing agent. Then, if it is determined that the oxidizing agent is excessive by monitoring the oxidation-reduction potential or monitoring the oxidizing agent concentration, the addition of the oxidizing agent may be stopped or the addition amount may be reduced.

In the above-described method, the oxidant addition method is exemplified as the oxidation treatment method in the oxidation treatment step. However, for example, an ozone oxidation method, a photocatalytic method, a biological oxidation method, or the like may be used. However, from the viewpoint of simplicity of control and reaction rate, an oxidizing agent addition method is preferable as the oxidation treatment method.
In addition, when an oxidant addition method using a chlorine-based oxidant is employed as an oxidation treatment method, odorous components such as chlorine gas or chloramine due to ammonia oxidation are generated, so gas recovery can be performed according to the generated concentration. It is desirable to do it.

(Precipitation separation process)
Furthermore, the wastewater treatment method of the present invention uses, for example, the wastewater treatment apparatus 5 shown in FIG. 5, and wastewater W ₀ in which ammonia is volatilized and removed between the ammonia removal step (stripping step) and the membrane separation step. It is preferable to have a precipitation separation step of separating and separating heavy metals.
In the precipitation separation step, the waste water W ₀ from which ammonia has been removed by volatilization is transferred to the precipitation tank 61 of the precipitation separation means 60 to precipitate the heavy metal insolubilized material, which is separated into the supernatant W ₄ and the precipitated concentrated water W ₅ .
The supernatant W ₄ is transferred to a membrane separation step, and further membrane-separated into filtered water W ₁ and membrane separation concentrated water W ₂ . Although the supernatant W ₄ is insolubles fine heavy metals have not been fully precipitated removed there by precipitation separation process, fine insolubles by membrane separation step is removed.
On the other hand, precipitated the concentrate W ₅ is usually dehydrated, it is treated as industrial wastes such as dehydrated cake.

  If a precipitation separation step is performed between the ammonia removal step (stripping step) and the membrane separation step, the heavy metals in the wastewater insolubilized in the ammonia removal step (stripping step) before the membrane separation in the membrane separation step. Most of it can be removed from wastewater. Therefore, since the amount of particles to be removed in the membrane separation step is reduced, the burden on the filtration membrane is reduced, and a more stable filtration operation can be continued.

Moreover, the wastewater treatment method of the present invention may have both an oxidation treatment step and a precipitation separation step between the ammonia removal step (stripping step) and the membrane separation step. In the case of having both an oxidation treatment step and a precipitation separation step, the order of implementation thereof is not particularly limited, and a precipitation separation step for separating and separating heavy metals in wastewater oxidized after the oxidation treatment step may be performed, You may perform the oxidation process process which oxidizes the wastewater which carried out precipitation separation of the heavy metal after the precipitation separation process.
By the way, the heavy metal insolubilized particles generated in the ammonia removal step (stripping step) tend to be fine, and when the precipitation separation step is performed, the precipitation rate may be slow. When the sedimentation rate is slow, it may be necessary to take measures such as increasing the size of the sedimentation tank.
However, if the oxidation treatment step and the precipitation separation step of precipitating and separating heavy metals in the oxidized wastewater are performed between the ammonia removal step (stripping step) and the membrane separation step, the oxidation treatment step causes coarsening. The heavy metal insolubilized material can be separated by precipitation in the precipitation separation step. Therefore, the precipitation rate can be increased, and heavy metals can be precipitated in a short time in the precipitation separation step, so there is no need to increase the size of the precipitation tank.

In the wastewater treatment method described above, as shown in FIGS. 1 to 5, each process is performed by continuously flowing wastewater W ₀ to each means. For example, the wastewater treatment apparatus 6 shown in FIG. 6 is used. Each step may be performed as follows.
That is, after transferred from the reservoir 11 to waste water W ₀ in the membrane separation tank 32, after stopping the supply of waste water W _0, the alkaline agent an alkali agent addition means 22 to the waste water W ₀ in the membrane separation tank 32 is added The ammonia in the waste water W ₀ is volatilized and removed while the waste water W ₀ is aerated using the air diffuser 24 (ammonia removal step (stripping step)).
At water gauge 23 monitoring the like pH of the ammonia concentration and wastewater W ₀ in the waste water W _0, after ammonia was confirmed that all the components were sufficiently removed from the waste water W _0, adding an oxidizing agent from the oxidizing agent addition means 52 Then, the waste water W ₀ is oxidized (oxidation process).
Then, after detecting the completion of the addition point of the oxidizing agent in water meter 53, and suction filtered through a pore of a filtration membrane wastewater W ₀ a membrane module 33 of the suction pump P2 is operated by membrane separation tank 32 Thus, the waste water W ₀ is separated into filtered water W ₁ and membrane separation concentrated water W ₂ (membrane separation step). At this time, the air supplied from the blower B2 is diffused from the aeration means 34 into the membrane separation tank 32 to wash the filtration membrane.
Next, the filtered water W ₁ is transferred to the pH adjusting tank 41 of the pH adjusting means 40, the pH of the filtered water W ₁ is adjusted to a pH suitable for discharge to a river or the like, and discharged as treated water W ₃ (pH adjusting step). ).
After a series of processes is finished, again transferred from the reservoir 11 to waste water W ₀ in the membrane separation tank 32, repeating the same process.

A part of the membrane separation concentrated water W ₂ separated by the membrane separation means 30 may be returned to the membrane separation tank 32 or the storage tank 11.
Further, in the oxidation treatment step, the oxidation treatment may be performed by adding an oxidizing agent while aeration of the wastewater W ₀ using the air diffuser 24. If the oxidation treatment is performed while aerating the wastewater W ₀ , the oxidant is easily diffused uniformly into the waste water W ₀ , and the oxidation treatment can be performed more efficiently.

Further, after the ammonia removal step (stripping step) and before the oxidation treatment step, the aeration from the aeration means 24 is stopped to stop the aeration of the waste water W ₀ and generated in the ammonia removal step (stripping step). it insolubilized of heavy metal may be precipitated in the membrane separation tank 32, after the oxidation treatment step, and before the membrane separation step, stop aeration of waste water W ₀ to stop air diffusion from the air diffuser means 24, The insolubilized heavy metal in the wastewater subjected to oxidation treatment may be precipitated in the membrane separation tank 32 (precipitation separation step). In particular, it is preferable to perform a precipitation separation step after the oxidation treatment step.
In the case where the precipitation separation step is performed, it is preferable to stop the aeration from the aeration means 34 and perform the membrane separation in the membrane separation step. In this case, after separating all the waste water W ₀ in the membrane separation tank 32 into the filtered water W ₁ and the membrane separation concentrated water W ₂ by the membrane separation step, the insoluble matter precipitated in the membrane separation tank 32 is removed, Further, a cleaning liquid such as water is put into the membrane separation tank 32, and the blower B2 is operated to clean the filtration membrane.

  Further, for example, the wastewater treatment apparatus 7 shown in FIG. 7 may be used, and the air diffuser 34 of the membrane separator 30 may be used in the ammonia removal step (stripping step).

The ammonia removal step of the wastewater treatment method described above is a step of stripping off ammonia by stripping treatment (stripping step). As the ammonia removal step, for example, a step of volatilizing and removing ammonia by heat treatment (heat treatment step) ).
The heat treatment temperature in the heat treatment step is generally higher than the outside air temperature (room temperature), and the temperature is more preferably 25 to 50 ° C. In the heat treatment step, an alkaline agent is added to the wastewater to generate free ammonia, and then the wastewater is heated or heated to a predetermined heat treatment temperature.

Thus, according to the wastewater treatment method of the present invention, wastewater can be treated at a high level without adding a flocculant to the wastewater and the concentration of heavy metals can be sufficiently reduced. May be. However, the smaller the amount of the flocculant added, the lower the cost of chemicals and the amount of sludge that can be generated, so that the disposal cost of sludge can also be reduced. Moreover, it can suppress that the film | membrane of a membrane filtration means obstruct | occludes. Therefore, it is preferable not to add the flocculant when the target treated water quality can be achieved without adding the flocculant.
Examples of the flocculant include inorganic flocculants such as polyaluminum chloride (PAC) and aluminum sulfate, and polymer flocculants such as polyacrylamide flocculants.
In addition, when adding the flocculant, the timing of adding the flocculant is between the ammonia removal step and the membrane separation step, and when performing the oxidation treatment step, it is between the oxidation treatment step and the membrane separation step. When performing a separation process, it is between an ammonia removal process and a precipitation separation process, and when performing a precipitation separation process after an oxidation treatment process, it is between an oxidation treatment process and a precipitation separation process.

Further, according to the wastewater treatment method of the present invention, even if no insolubilizing agent is added to the wastewater, the wastewater becomes alkaline by adding an alkaline agent in the ammonia removal step, so that heavy metals in the wastewater are insolubilized. The waste water can be treated at a high level, but if necessary, an insolubilizing agent may be added to carry out the insolubilization treatment. However, the smaller the amount of insolubilizing agent added, the lower the drug cost. Therefore, it is preferable not to add the insolubilizing agent when the target treated water quality can be achieved without providing the insolubilizing means.
As a method of insolubilization treatment, there are a hydroxide method using a hydroxylating agent (alkali agent) and a sulfide method using a sulfiding agent. In the case of the sulfide method, hydrogen sulfide may be generated, and therefore the hydroxide method is preferable as the insolubilization treatment.

The hydroxide method is a method in which a hydroxylating agent (hydroxide ion) and a target metal are reacted and precipitated as a metal hydroxide having low solubility.
Examples of the hydroxylating agent include the alkali agents exemplified in the description of the ammonia removing step.

On the other hand, the sulfide method is a method in which a sulfiding agent (sulfide ion) and a target metal are reacted and precipitated as a metal sulfide having low solubility.
As the sulfiding agent, sodium sulfide, hydrogen sulfide, or the like is used.

When insolubilization is performed by a hydroxide method, heavy metals have different pH ranges where the solubility is lowest depending on each metal species. Therefore, in the present invention, the pH of the wastewater may be adjusted as appropriate depending on the type of heavy metal to be removed.
However, since the pH of the wastewater in the ammonia removal step is preferably 10 to 11, if the pH suitable for insolubilization is out of this range, the pH of the wastewater is once adjusted to 10 to 11 in the ammonia removal step. After removing ammonia, it is desirable to adjust the pH to be suitable for insolubilization and promote insolubilization of heavy metals again.

  In addition, when adding the insolubilizing agent, the timing of adding the flocculant is between the ammonia removal step and the membrane separation step, and when performing the oxidation treatment step, it is between the oxidation treatment step and the membrane separation step. When performing a separation process, it is between an ammonia removal process and a precipitation separation process, and when performing a precipitation separation process after an oxidation treatment process, it is between an oxidation treatment process and a precipitation separation process.

  Hereinafter, the present invention will be specifically described by way of examples, but the present invention is not limited thereto.

[Example 1]
As waste water, nickel-containing waste water discharged from the electroless nickel plating process was used. The nickel concentration in the wastewater was 1900 mg / L, and the ammonia concentration was 880 mg / L as the ammonia nitrogen (NH ₃ -N) concentration. Moreover, the pH of waste water was 4.6.
The pH of the waste water was adjusted to 10 by adding a 10 mol / L sodium hydroxide (NaOH) solution as an alkaline agent to 500 mL of the nickel-containing waste water.
After stirring this wastewater for 5 minutes, aeration was performed at 25 ° C. for 5 hours, and ammonia stripping treatment was performed to volatilize and remove ammonia, and nickel insolubilized product was generated (ammonia removal step (stripping step)).
Next, the waste water from which ammonia was volatilized and removed was subjected to membrane separation into filtered water and membrane-separated concentrated water using a polyvinylidene fluoride hollow fiber membrane (manufactured by Mitsubishi Rayon Co., Ltd., “Sterapore SADF”, nominal pore size 0.4 μm). (Membrane separation step), and waste water was treated.
The concentration of nickel (Ni) and ammonia nitrogen (NH ₃ —N) in the obtained filtered water was measured. The results are shown in Table 1.

[Example 2]
Except for aeration, the wastewater was treated in the same manner as in Example 1 except that it was left at 25 ° C. for 5 hours, and the concentrations of nickel and ammonia nitrogen in the filtrate were measured. These results are shown in Table 1.

[Comparative Example 1]
Except that sodium hydroxide was not added, wastewater was treated in the same manner as in Example 1, and the concentrations of nickel and ammonia nitrogen in the filtered water were measured. These results are shown in Table 1.

As is apparent from Table 1, in Examples 1 and 2, the concentrations of nickel and ammonia nitrogen in the filtered water were both low, and nickel could be sufficiently removed. In particular, in Example 1 in which ammonia was volatilized and removed by stripping treatment, the nickel concentration in the filtered water was significantly reduced compared to Example 2 in which ammonia was volatilized and removed by heat treatment, and nickel can be removed more effectively. did it.
On the other hand, in the case of Comparative Example 1 in which aeration was performed without adding sodium hydroxide, the nickel concentration in the filtered water was higher than in Examples 1 and 2, and nickel could not be sufficiently removed. Moreover, since the density | concentration of ammonia nitrogen in filtered water was high, it was shown that ammonia was not fully removed.

[Example 3]
As waste water, nickel-containing waste water discharged from the electroless nickel plating process was used. The nickel concentration in the wastewater was 1720 mg / L, and the ammonia concentration was 880 mg / L as ammonia nitrogen (NH ₃ -N) concentration. Moreover, the pH of waste water was 4.6.
To 1000 mL of the nickel-containing wastewater, a 10 mol / L sodium hydroxide (NaOH) solution was added as an alkali agent to adjust the pH of the wastewater to 11.
After stirring this wastewater for 5 minutes, aeration was performed at 25 ° C. for 2 hours, and ammonia stripping treatment was performed to volatilize and remove the ammonia and to produce an insolubilized nickel (ammonia removal step (stripping step)).
Sampling is performed before adding the sodium hydroxide solution and every hour after the start of aeration, and using a hollow fiber membrane made of polyvinylidene fluoride (Mitsubishi Rayon Co., Ltd., “Sterapore SADF”, nominal pore size 0.4 μm) The membrane was separated into filtered water and membrane-separated concentrated water, and the concentrations of nickel (Ni) and ammonia nitrogen (NH ₃ -N) in the filtered water were measured. The results are shown in Table 2.

Further, 30 mL of a sodium hypochlorite (NaClO) solution (effective chlorine concentration: 12% by mass) was added as an oxidant to the wastewater after 2 hours had passed from the start of aeration, and the mixture was stirred for 5 minutes for oxidation treatment.
The particle distribution was measured for the waste water before the addition of the sodium hypochlorite solution and the nickel insolubilized material contained in the waste water after the addition of the sodium hypochlorite solution and stirring for 5 minutes. The measurement was performed using a laser diffraction / scattering particle size distribution measuring apparatus (“LA-920” manufactured by Horiba, Ltd.), and the particle size was measured based on the volume and the frequency distribution. Table 3 shows the mode diameter (particle diameter having the largest appearance ratio).
Further, the waste water after the addition of the sodium hypochlorite solution was filtered using a hollow fiber membrane made of polyvinylidene fluoride (manufactured by Mitsubishi Rayon Co., Ltd., “STELLAPORE SADF”, nominal pore size 0.4 μm). The membrane was separated into separated and concentrated water, and the concentration of ammonia nitrogen (NH ₃ -N) in the filtered water was measured. The results are shown in Table 3.

As is clear from Table 2, it was shown that the concentration of nickel and ammonia nitrogen in the filtrate was reduced by adding sodium hydroxide to the wastewater.
Further, as is apparent from Table 3, by adding sodium hydroxide and adding a sodium hypochlorite solution to the waste water after stripping treatment, nickel insolubilized material may become coarse. Indicated. Moreover, since the density | concentration of ammonia nitrogen in filtered water was reduced compared with before adding a sodium hypochlorite solution, it was shown that ammonia was decomposed | disassembled by the sodium hypochlorite solution.

1, 2, 3, 4, 5, 6, 7 Wastewater treatment apparatus 10 Storage means 20 Ammonia removal means (stripping means)
24 Aeration means 30 Membrane separation means 40 pH adjustment means 50 Oxidation treatment means 60 Precipitation separation means W ₀ waste water W ₁ filtered water W ₂ membrane separation concentrated water W ₃ treated water W ₄ supernatant liquid W ₅ precipitation concentrated water

Claims (13)

A method for treating wastewater containing heavy metals and ammonia,
A method for treating wastewater, comprising: an ammonia removing step of adding an alkaline agent to wastewater to volatilize and remove ammonia; and a membrane separation step of membrane-separating wastewater from which ammonia has been volatilized and removed.   The wastewater treatment method according to claim 1, wherein the ammonia removal step is performed by aeration of wastewater.   The wastewater treatment method according to claim 1 or 2, further comprising an oxidation treatment step of oxidizing the wastewater from which ammonia has been volatilized and removed, between the ammonia removal step and the membrane separation step.   The wastewater treatment method according to claim 1 or 2, further comprising a precipitation separation step of precipitating and separating heavy metals in wastewater from which ammonia has been volatilized and removed, between the ammonia removal step and the membrane separation step.   Between the ammonia removal step and the membrane separation step, there is an oxidation treatment step of oxidizing waste water from which ammonia has been volatilized and a precipitation separation step of precipitating and separating heavy metals in the wastewater subjected to oxidation treatment. The wastewater treatment method according to 2.   Between the ammonia removal step and the membrane separation step, there is a precipitation separation step for precipitating and separating heavy metals in waste water from which ammonia has been volatilized and removed, and an oxidation treatment step for oxidizing the waste water from which heavy metals have been separated by precipitation. A method for treating wastewater according to 1 or 2.   7. The method according to claim 3, wherein the oxidation treatment step is performed by addition of at least one oxidizing agent selected from the group consisting of hypochlorous acid, chlorous acid, perchloric acid, and salts thereof. The wastewater treatment method according to claim 1. An apparatus for treating wastewater containing heavy metals and ammonia,
A wastewater treatment apparatus comprising ammonia removal means for volatilizing and removing ammonia by adding an alkaline agent to wastewater, and membrane separation means for membrane-separating wastewater from which ammonia has been volatilized and removed.   The wastewater treatment apparatus according to claim 8, wherein the ammonia removing unit includes an aeration unit for aeration of the wastewater.   The wastewater treatment apparatus according to claim 8 or 9, further comprising an oxidation treatment means for oxidizing the wastewater before membrane separation from which ammonia has been volatilized and removed.   The wastewater treatment apparatus according to claim 8 or 9, further comprising precipitation separation means for precipitating and separating heavy metals in wastewater before membrane separation from which ammonia has been volatilized and removed.   Oxidation treatment means for oxidizing wastewater before membrane separation from which ammonia has been removed by volatilization, and heavy metals in wastewater after oxidation treatment and before membrane separation, or heavy metals in wastewater before oxidation treatment from which ammonia has been removed by volatilization are precipitated and separated The wastewater treatment apparatus according to claim 8 or 9, further comprising a precipitation separation means.   The wastewater treatment apparatus according to claim 12, comprising an oxidation treatment means, a precipitation separation means, and a membrane separation means in order downstream of the ammonia removal means.

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