JPH10131073A - Apparatus for recovering white water - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an apparatus for recovering white water capable of stable carrying out the treatment of the white water at a low cost. SOLUTION: This apparatus for recovering white water is capable of adding a flocculant from a device 1 for adding the flocculant to the white water, as necessary, adding a ζ potential regulator from a device 2 for adding the regulator thereto, then introducing the resultant white water into a solid-liquid separator 3, carrying out the treatment for separating the liquid from the solid, adding a slime controlling agent thereto with a device 5 for adding a slime controlling agent, sensing the turbinity with a turbidity meter 6 installed in the first water tank 4, inputting the sensed signal of the turbidity to a controller 20, controlling the device 1 for adding the flocculant and the device 2 for adding the ζ potential regulator with the controller 20 so as to provide a prescribed value or below of the sensed turgidity, introducing filtrate water from filtration equipment 7 into a second water tank 8, adding a slime controlling agent from a device 9 for adding the slime controlling agent thereto in the second water tank 8 and controlling the amounts of the slime controlling agents from the devices 5 and 9 for adding so that the amount of slimes sensed with a slime monitor 11 may be a prescribed value of below.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a white water recovery apparatus for treating white water generated in a paper making process so that the white water can be reused. More specifically, the present invention relates to a white water recovery apparatus that can stably perform a white water recovery operation.

[0002]

2. Description of the Related Art White water refers to processes such as washing, dilution, and dehydration in a pulp manufacturing process and wastewater such as drainage from a wire mesh of a paper machine. The white water contains various chemicals, fillers and other solid substances or various soluble substances in addition to the fibers.

[0003] Conventionally, white water has been subjected to a pressure floating treatment, a coagulation sedimentation treatment, and a disk filter treatment in order to recover the white water. After such a primary treatment, sand filtration is further performed.
A secondary treatment by filtration, such as fiber filtration, two-layer filtration, or filter medium filtration, is also performed.

[0004] Further, a slime control agent is also added to such primary treatment or secondary treatment water. As the inorganic slime control agent, sodium hypochlorite or the like is used. Various organic slime control agents (antibacterial agents) such as dibromonitrilopropionamide are used.

[0005]

The above prior art has the following problems.

(1) After the primary treatment of white water, two more
In the case where the secondary treatment is performed at a high level, if the quality of the primary treated water fluctuates, sufficient secondary treated water quality cannot be obtained. Generally, in the paper making process, white water having a high SS may be suddenly generated due to, for example, a paper breakage in a paper machine, and the primary treated water may also suddenly have a high SS.
When such deterioration of the primary treatment water quality occurs, the secondary treatment (filtration treatment) apparatus is clogged and the filtration state changes (volume filtration becomes surface filtration and the filtration capacity is reduced). And so on, and a stable filtration operation is hindered. In addition, backwashing is performed when the filtration device is clogged,
When the frequency of the backwash increases, not only does the operation efficiency of the apparatus decrease, but also the amount of backwash water unnecessarily increases.

(2) White water has a high BOD and COD, and slime is easily generated. For this reason, a slime control agent is added. However, when a large amount of the slime control agent is added, the slime control agent remains in the recovered water, causing a discoloration or the like to a product made using the recovered water. Conversely, if the amount of the slime control agent is too small, slime generation cannot be sufficiently suppressed. As described above, since it is necessary to control the addition amount so as not to affect the papermaking system while preventing the generation of slime, it is difficult to control the addition amount of the conventional slime control agent to an appropriate addition amount. there were.

An object of the present invention is to solve the above-mentioned conventional problems and to provide a white water recovery apparatus capable of performing white water treatment stably at low cost.

[0009]

According to the present invention, there is provided a white water recovery apparatus comprising: a first treatment means for adding a flocculant to white water and then separating the liquid and solid; and a slime control agent for effluent water from the first treatment means. And a second treatment means for solid-liquid separation after the addition of water, and the effluent of the second treatment means is used as recovered water.

In the white water recovery apparatus of the present invention,
The SS can be sufficiently removed by adding the flocculant to the white water in the first treatment means, performing solid-liquid separation, and then further adding the slime control agent in the second treatment means, and then performing solid-liquid separation. In addition, since the slime control agent is added to the effluent of the first treatment means,
Slime generation in the solid-liquid separation device of the second processing means can be suppressed.

In the present invention, there may be provided a third treatment means in which a slime control agent is added to the effluent of the second treatment means to make recovered water.

In the present invention, furthermore, turbidity detecting means for detecting the turbidity of the effluent of the first processing means, and the coagulant in the first processing means based on the detection value of the turbidity detecting means. It is preferable to provide a means for controlling the amount of addition.

Further, a slime detecting means for detecting a slime generation state in the recovered water is provided, and a slime control agent in at least one of the second and third processing means is provided based on the detection result of the slime detecting means. It is preferable to provide a means for controlling the amount of addition.

[0014]

FIG. 1 is a system diagram of a white water recovery apparatus according to an embodiment.

The white water is added to the coagulant from the coagulant adding device 1 and, if necessary, a zeta potential regulator is added from the coagulant 2 to the coagulant. It is processed. The separated solid is returned to the papermaking system. The liquid is introduced into the first water tank 4, where the slime control agent is added by the addition device 5. The turbidity meter 6 provided in the first water tank 4
Turbidity is detected.

The turbidity detection signal is input to a controller 20, which controls the flocculant adding device 1 and the zeta potential adjusting agent adding device 2 so that the detected turbidity becomes a predetermined value or less.

The effluent from the first water tank 4 is filtered by a filtration device 7. The solids separated by the filtration device 7 are discarded or collected.

The filtered water from the filtering device 7 is supplied to a second water tank 8
Where an organic slime control agent is added from the slime control agent adding device 9 as needed. The effluent of the second water tank 8 is supplied to the outflow line 1
By 0, it is sent to a papermaking system or a raw material system. A slime monitor 11 is provided on a bypass line 12 provided alongside the line 10, and a detection signal of the slime monitor 11 is input to a controller 21. Then, the amount of the slime control agent from the adding devices 5 and 9 is controlled so that the amount of the slime detected by the slime monitor 11 is equal to or less than a predetermined value.

As the coagulant added in the coagulant adding device 1, a polymer coagulant is preferable. The addition amount of the polymer flocculant is controlled by the controller 20, and is usually in the range of about 0.5 to 20 mg / L.

The coagulation effect is improved by adding a zeta potential regulator together with the coagulant. As the zeta potential regulator, polystyrene sulfonic acid or a salt thereof, dimethylamine-epichlorohydrin condensate, diisobutylene maleate or a salt thereof, or the like can be used. The amount of the zeta potential regulator added is also determined by the controller 20.
Is usually controlled by 0.5 to 50 mg
/ L.

As the solid-liquid separation device 3, a pressure flotation separation device is suitable, but a coagulation-sedimentation device, a disk filter or the like can also be used. From the solid-liquid separation device 3 to the first water tank 4
SS concentration in the water flowing into
It is preferably at most 0 ppm. This SS concentration is 1
When the concentration is 50 ppm or less, particularly 50 ppm or less, the formation of the mat-like SS layer in the filtration device 7 is small, stable operation is possible, and the frequency of backwashing is small.

Since the SS concentration is proportional to the turbidity, the relationship between the turbidity and the SS concentration is determined in advance, and the value of the turbidity meter 6 provided in the first water tank 4 is converted into the SS concentration. The turbidity meter 6 is preferably provided with a mechanism for periodically cleaning so as to remove stains on the sensor portion.
The turbidity meter 6 is preferably capable of continuously measuring turbidity.
Instead of providing the turbidity meter 6 in the first water tank 4, the turbidity meter 6 may be provided before or after the first water tank 4.

The turbidity detected by the turbidimeter 6 becomes extremely high (for example, more than 200 ppm) due to a sudden increase in SS of white water or the like.
When the water is raised, it is preferable that the water in the water tank 4 is not supplied to the filtration device 7 as it is, but is bypassed to a separately provided filter device or the like, and then supplied to the filtration device 7. Further, such high SS water may be sent from the water tank 4 to another wastewater treatment system so as not to be supplied to the filtration device 7.

Examples of the slime control agent added from the adding device 5 to the first water tank 4 include inorganic and organic slime control agents. Examples of the inorganic slime control agent include sodium hypochlorite, chlorine, chlorine dioxide, and hydrogen peroxide.

On the other hand, organic slime control agents include, for example, 2,2-dibromonitrilopropionamide (DBNPA), 5-chloro-2,4,6-trifluoroisophthalonitrile, 4,5-dichloro-1 , 2-Dithiol-3-one, 2,2-dibromo-2-nitroethanol, bis (1,4-bromoacetoxy) -2-butene, methylenebisthiocyanate (MBTC), 5-
Chloro-2-methyl-4-isothiazolin-3-one or a metal salt thereof, dimethoxycarbamate, benzyl bromoacetate and the like can be mentioned. These can be used singly or in combination of two or more. In addition, from the viewpoint of preventing the occurrence of resistant bacteria, the drugs used can be changed, for example, alternately used every 1 to 3 months.

The addition amount of the chlorine-based slime control agent among the inorganic slime control agents is controlled by a controller 21 described later, and the water concentration after the addition is 0.05 to 1 mg / L, particularly 0%, as the chlorine concentration. .1 to 0.5m
It is preferable to control to be g / L. On the other hand, the addition amount of the organic slime control agent is also controlled by the controller 21, but is generally 0.5 to 300 mg / L,
Preferably, it is about 1 to 50 mg / L.

By adding a slime control agent to the first water tank 4, the generation of slime in the water tank 4 and the filtration device 7 can be suppressed.

When a high-concentration slime control agent is added from the addition device 5, most of the slime control agent is consumed by the filtration device 7, so that the amount of addition from the addition devices 5 and 9 must be reduced to maintain the effect up to the treated water side. It must be very large. The addition amount of the slime control agent from the addition device 5 is limited to the amount required to prevent clogging of the filter medium, and the addition of the slime control agent separately from the addition device 9 to prevent the slime of the recovery system suppresses the consumption of the slime control agent. Preferred for.

As the filtration device 6, in addition to a filtration material filtration device (sand filtration device, two-layer filtration device) and a fiber filtration device, MF,
A membrane filtration device such as UF can also be used.

As the slime control agent added from the addition device 9 in the second water tank 8, the above-mentioned organic slime control agent (antibacterial agent) is suitable.

The organic slime control agent may be added continuously or intermittently.

When an inexpensive inorganic chlorine-based slime control agent is used, it is preferable to add it from the addition device 5 and add the organic slime control agent in the addition device 9. In this way, the concentration of residual chlorine in the effluent from the line 10 can be reduced, and problems due to chlorine in the papermaking process can be prevented. In addition, compared to the case where the organic slime control agent is used alone, the amount of organic slime added from the adding devices 5 and 9 can be reduced to, for example, about ２〜 to ６, and there is no effect on paper.

As the slime monitor 11, as shown in FIG. 2, a slime adhesion tester comprising a stationary outer cylinder 31 and a rotating inner cylinder 32 is suitable.

The outer cylinder 31 and the inner cylinder 32
When the sample water is continuously supplied between the two, the biofilm (slime) grows and adheres to the inner cylinder surface. A torque meter is attached to the rotating shaft 33 of the inner cylinder 32, and the amount of biofilm growth is continuously recorded by recording a torque that increases in accordance with the amount of biofilm attached through a torque transducer.

When the slime adheres to the surface of the inner cylinder 32, the torque for rotating the inner cylinder 32 increases. By measuring this torque (or a physical quantity corresponding thereto, for example, a motor current value), The amount of slime attached to the inner cylinder 32 can be detected,
The slime generation status of the water system can be detected.

In addition to the torque meter type slime monitor, a known differential pressure type slime monitor may be used.

As shown in FIG. 1, this slime monitor 11
Is installed in the bypass line 12, and by continuously monitoring the slime generation state, the dirt inside the white water treatment apparatus can be predicted during operation, and the dirt at the use point (shower line or the like) at the end of the treated water line 10 is predicted. be able to. Furthermore, by detecting subtle dirt on the monitor,
The signal is input to the controller 21 to be used for adjusting the amount of the slime control agent, thereby preventing a slime trouble from occurring.

[0038]

【Example】

Example 1 White water from a neutral papermaking machine (pH 7.8, 25-29
C) was processed according to the flow of FIG. The average SS concentration of this white water is 10 to 30 ppm, about 50% of the SS component is pulp fiber, and the remaining about 50% is inorganic SS.

A diallylammonium cationic polymer was used as the high molecular coagulant. The addition amount is 6
Is 1 ppm when the SS concentration obtained from the turbidity detected in the above is 50 ppm or less, and 2 when the SS concentration is 50 ppm or more.
After that, it was maintained at 2 ppm until it dropped to 30 ppm, and returned to 1 ppm when it became 30 ppm or less.

As the solid-liquid separator 3, a pressurized flotation separator was used.

As the turbidity meter 6, T-Spectrum Co., Ltd.
x Pro-T, WP-302 was used.

As the filtering device 7, a high-speed two-layer filter (L
V = 40 m / Hr, using a filter medium: anthracite having a particle size of 3 mm and sand having a particle size of 1.7 mm), and when the pressure difference between the outlet and the inlet of the filtration tower became 1800 mmAq or more, back washing was performed.
The slime monitor 11 includes a rotating inner cylinder 32 (SUS304 rotor) having a diameter of 65 mm and a stationary outer cylinder 31 having an inner diameter of 160 mm (water amount 3).
L) and the amount of inflow water is 9 L
/ Hr. A Brookfield torque meter (using a rotary viscometer RE500H manufactured by Toki Sangyo Co., Ltd.) was attached to the rotation axis of the inner cylinder 32, and the torque during the operation period was automatically recorded every hour via a controller. The rotation speed was set to 100 rpm, and the entire cylinder was immersed in a constant temperature water bath to maintain the temperature at 30 ° C.

Sodium hypochlorite is added from the adding device 5, and DBNPA and MBTC are added in a ratio of 4: 1 from the adding device 9.
Was added. The addition amount was controlled as follows.

Addition amount at normal time (when the detected torque of the slime monitor is 300 μN · m or less) Addition device 5: ₂ ppm asCl ₂ continuous addition (at this time, the residual chlorine concentration in the water tank 4 is 0.2 to 0.5 ppm. Addition device 9: 15 ppm three times a day for 15 minutes
When the detected torque of the slime monitor exceeds 300 μN · m Addition device 5: Increase the continuous addition amount to 3 ppm asCl ₂ Addition device 9: Increase the addition amount per operation to 30 ppm As a result, the average SS concentration 2 ~ 4 ppm of treated water was stably obtained, and no slime was generated for 30 days. The residual chlorine in this treated water is about 0.1
ppm, and no chlorine trouble occurred in the paper machine.

The frequency of backwashing of the filtration device 7 is 5 Hr on average.
Once every day.

In the turbidimeter 6, the sensor was cleaned with a wiper once every 30 minutes. Thereby, turbidity could always be detected with high accuracy.

COMPARATIVE EXAMPLE 1 The amount of flocculant added was not controlled based on the value detected by the turbidimeter 6,
The white water treatment was performed in the same manner as in Example 1 except that the coagulant was added at a constant rate of 1 ppm from the addition device 1, but the frequency of the backwash was once every 30 minutes, which was extremely large.
Further, when the SS concentration in the white water became 200 ppm or more, SS was formed in a mat shape on the surface of the filter medium of the filtration device 7. This mat-like SS could not be removed by backwashing, and became inoperable.

Comparative Example 2 Sodium hypochlorite was added at 2 ppm-asCl
₂ Inject a fixed amount, and add 15 ppm of an organic slime control agent (same as in Example 1) for 15 minutes
Infusion was performed three times a day. Otherwise, when white water was treated in the same manner as in Example 1, slime adhered in 15 days.

Example 2 In Example 1, an alarm was set so that the turbidity meter 6 could operate at 200 ppm or more,
When the concentration reached ppm or more, the supply of water to the filtration device 7 was stopped, and the water in the water tank 4 was sent to another wastewater treatment facility. Thereafter, when the turbidity returned to less than 200 ppm, the same operation as in Example 1 was performed. As a result, the filtration device 7 could be operated more stably.

Example 3 In Example 1, the turbidity measured by the turbidimeter 6 was 200 ppm.
In this case, the water in the water tank 4 was passed through a screen filter and then supplied to the filtration device 7. Thereby, the filtration device 7 could be operated very stably.

[0051]

As described above, according to the present invention, white water can be stably recovered. ADVANTAGE OF THE INVENTION According to this invention, the trouble by SS and slime of a solid-liquid separation means can be prevented reliably, and a collection | recovery processing driving | operation can be performed stably over a long period of time. Further, according to the present invention, it is possible to prevent generation of slime of recovered water and also to prevent chlorine trouble when the recovered water is reused in a papermaking process.

[Brief description of the drawings]

FIG. 1 is a system diagram of a white water recovery device according to an embodiment.

FIG. 2 is a sectional view of a slime monitor.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Coagulant addition apparatus 2 Zeta potential regulator addition apparatus 3 Solid-liquid separation apparatus 5, 9 Slime control agent addition apparatus 6 Turbidimeter 7 Filtration apparatus 11 Slime monitor

Claims (4)

[Claims] 1. A first treatment means for adding a flocculant to white water, followed by solid-liquid separation, and a second treatment means for adding a slime control agent to effluent of the first treatment means, followed by solid-liquid separation. A white water recovery apparatus comprising a processing means, and using effluent of the second processing means as recovered water. 2. The white water recovery apparatus according to claim 1, further comprising third processing means for adding a slime control agent to the effluent of the second processing means to obtain recovered water. 3. The turbidity detecting means according to claim 1, further comprising a turbidity detecting means for detecting turbidity of the effluent of the first processing means, and a first processing means based on a detection value of the turbidity detecting means. A means for controlling the amount of coagulant added in the step (a). 4. The slime control agent according to claim 1, further comprising a slime detecting means for detecting a slime generation state in the recovered water, based on a detection result of the slime detecting means. A white water collecting device, comprising: means for controlling the white water.