DE2410007A1 - TREATMENT METHODS FOR WATER WITH ACTIVATED CARBON - Google Patents

Description

T 49 298

Applicant: Chiyoda Kako Kensetsu Kabushiki Kaisha

1580 Tsuruinicho, Tsururni, -Yokohama, Kanagawa / Japan

Treatment process for water with activated carbon

The invention relates to a method for the continuous treatment of water, in which a fluidized bed or used a fluidized bed using activated carbon with diameters in the range between 200 and 1500 microns will.

Various methods of water treatment using activated carbon are known. For example are a process in which clean water using so-called powdered carbon, the is less than 150 microns, is deodorized, and a process in which waste water using a stationary bed containing relatively coarsely ground, 1000 to 4000 microns, activated carbon, is practical used.

Due to the large surface area and the fast The adsorption rate shows a rapid rate of powdery carbon used in the known processes Effect. This property is used, for example, for the treatment of polluted water in a water purification plant used. However, these known methods encounter some difficulties in eliminating the used ones Activated carbon. Recently, devices have been developed to regenerate used powdered carbon, the

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ORIGINAL INSPECTED

However, the loss of regeneration is very great. To an environmental pollution To prevent this, the used activated charcoal can be burned. However, this is not only very difficult, but there is an additional problem that dust is formed. Since it is also common practice to use adsorption carry out by a settling separation process, the known processes have the further disadvantage that large clarifiers are required.

On the other hand, the use of coarse-grained coal for water treatment has increased because regeneration is easier wanted to take advantage of. However, since the adsorption rate of such coarse-grained coal is slow, it requires a long time to reach equilibrium adsorption for BOD or COD.

The invention is a method for treating water, which is characterized in that activated carbon with a fairly broad size range between 200 and 1500 microns is used, and this makes it possible to use the Advantages of the rapid action of powdered coal and the regenerability of coarse-grained coal combined. In addition, activated carbon with the size range mentioned can form a fluidized bed when it comes into contact with water, which flows at any rate suitable for water treatment. The inventive Diameter range between 200 and 1500 microns does not include activated carbon, the diameter distribution of which is in between, but any type of activated carbon whose grain size is within this range. The activated carbon can be any activated carbon, and it can be made from, for example, coconut shell charcoal, charcoal, and pitch and it can be of any shape, for example, it can be brittle, granular, or spherical. The appropriate type and shape can be selected depending on the goal of treatment. The bulk densities of these three different ones Types of activated carbon are slightly different:

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They are 0.4 to 0.55 g / ccm for coconut shell charcoal and charcoal and 0.55-0.65 g / cc for activated charcoal made from pitch and for pitch, respectively. Activated carbon from pitch with a greater bulk density is somewhat more preferred for the fluidized bed.

When treating water, contact or contact with water occurs through the apparent surface area the activated carbon and the smaller the diameter of the activated carbon is, the greater the rate of adsorption. It is also known that the amount of compounds adsorbed and the value of equilibrium adsorption does not vary greatly with the diameter of the activated carbon. The usage of activated carbon with a fast adsorption rate enables a reduction in the size of the Adsorption systems, while the costs and the area required for their construction are reduced.

It has been found that activated carbon larger than 200 microns in diameter is regenerable. It can be regenerated in approximately the same yields as coarse-grained activated carbon, but using the same regeneration process as the latter. Activated carbon, having a diameter greater than 200 microns, C is regenerated at 600 to 900 ^0, where one can use any of the known indirect heating method for fluidized beds, a method with more muffle and a Rotationskilnverfahren and wherein the regeneration yields are about 95 to 98%. In contrast, the regeneration yields of so-called pulverulent coal, which is smaller than 200 microns, are very low and lie between 80 and 90%, since the coal is easily entrained by the regeneration gases or is essentially consumed by water-gas reaction or combustion due to the large surface area and the small grain size. An investigation of the relationship between the grain size and the rate of adsorption of activated carbon has shown that the COD is an equilibrium

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adsorption achieved in about 20 minutes to 1 hour when treated with activated carbon between 200 and 1500 microns, as opposed to 3 to 5 hours or even longer if the activated carbon is in the range between 1500 and 3000 microns lies (see. Fig. 1).

Because powdered, granular activated carbon is used the water treatment with a stationary layer, thereby increasing the pressure drop, in the present invention not economical. It is therefore preferable to carry out adsorption according to a fluidized bed method. It exists a big difference in water resistance between a fluidized bed and a stationary bed, as in The following is explained using activated carbon between 250 and 600 microns with water loads of 10, 15 and 20 m / h.

Water load pressure drop

stung, m / h fluidized bed, mm H ₂ O stationary bed,

mm H ₂ O

10 56 1400

15 42 2200

20 30 3000

It is easily seen from the above values that the pressure drop causes the stationary layer to be unfavorable in terms of energy for the water pump with which the raw water is pumped, and in terms of on the pressure resistance of the adsorption column.

Of the activated carbon having a grain size of 200 to 1500 microns required in the present invention Activated carbon with a grain size in the range of 800 to 1500 microns are used in a stationary layer, depending on the level of water pollution. On the other hand, activated carbon should preferably be between 200 and 800 microns in a fluidized bed, as its use in a stationary bed requires that the bed be made up Activated carbon to a large extent, due to the strong pressure

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waste, must be reduced, resulting in a large filter area results. If one takes into account the adsorption activity, the regeneration yield and other conditions, which occur when using the fluidized bed, the grain sizes of the activated carbon in the present invention are im Range between 250 and 800 microns' most suitable. Man can use fluidized beds of any type; you can have multiple stages continuously, single-stage continuous or work in a rudimentary manner. You can also work in countercurrent or in cocurrent. However, in In practice, countercurrent operation is preferred, since the COD of the recovered activated carbon is adsorbed until it is in equilibrium with the COD concentration of the raw water stands. Compared with this, the adsorption is carried out until a state of equilibrium is reached with the COD concentration of the treated water, which is good for working in the DC applies. If activated carbon with a size smaller than 200 microns is used in a fluidized bed, so The terminal velocity in the system is so low that it is impossible to control the flow velocity of the water increase. This makes it necessary to increase the size of the adsorption column, which in turn has a larger area requires.

The following are the relationships between the grain size and the final speed or the limit speed for Activated charcoal shown on a pitch basis.

Grain size (microns) final speed (m / h)

200 15

500 110

1000 240

1500 350

In practical operation, when using 200 micron activated carbon, the terminal velocity is 15 m / h, so that a water flow rate from 8 to 10 m / h is suitable.

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As a regeneration process, a regeneration -The fluidized bed type method is preferred for the powdered-granular activated carbon according to the invention, although, as mentioned above, this is not intended to be a limitation. Typical regeneration methods include those that in Japanese Patent Application No. 47-64678, and those in which a rotary kiln or a multi-pot furnace is used.

Figure 2 is a flow sheet illustrating one embodiment of the water treatment process of the present invention. Raw water 5 is from the bottom of the adsorption column 1 with the activated carbon through the fluidized bed 2 of activated carbon passed and withdrawn from the top of the column as treated water 4. Activated carbon is introduced at the top of the column and the used activated carbon is removed from the bottom of the column and fed into the regeneration column 3. The regeneration column contains a desorption section and an activation section. The activated carbon regenerated with steam 6 in the regeneration column is circulated back into the adsorption column.

In the case of the water treatment method according to the invention, there is no danger in contrast to a system with a stationary system Layer that the adsorption layer by solids in the water that is treated, if any, becomes clogged. Of course, a part of such solids that adhere to the surface of the activated carbon is removed with it, and this makes the regeneration of the used activated carbon more difficult. It is therefore desirable to get the solids through to remove a pretreatment. The pretreatment to remove such suspended solids can be carried out by ordinary Filtration, flocculation precipitation or air flotation. If there is a lot of oil, so it is desirable to carry out the treatment in an oil separator or a coalescer. In case of For waste water with a high COD or high BOD, it is desirable to carry out a treatment in devices with activated sludge.

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to lead. One can also combine any of these pretreatments, depending on the condition of the water being treated shall be.

The following examples illustrate the invention without it to restrict. Furthermore, comparative examples are given in which the use of activated carbon is explained, whose size is outside the grain size ranges defined according to the invention, both fluidized beds and stationary layers are used.

example 1

Waste water from a petroleum refining plant was mixed with powdery, granular activated carbon with a diameter in the range between 250 and 500 microns. The specific The mass weight and the specific surface area of the activated carbon used were 0.65 and 970 m / g, respectively.

The adsorption column contains eight stages with fluidized beds, through which the water for the treatment is passed at a speed of 30 t / h and a speed of 13 m / h will. The activated carbon is circulated at a rate of 15 kg / h.

As a result, the COD value in the raw water increases to 80 ppm 13 ppm decreased. ' The residence time of the water in the adsorption column is about 20 minutes.

The activated carbon is regenerated in two-stage fluidized layers. The temperature is 350 ° C in the desorption section and 800 ° C in the activation section, the residence time in the latter being 40 minutes. Activation takes place using steam. The regeneration loss is about 3%

Comparative example 1

(1) The same waste water as used in Example 1 was tried using To treat powdered coal below 150 microns in fluidized beds. Even with a hydraulic load of At 5 m / h the interface at the fluidized bed was unclear and an entrainment of activated carbon powder was observed. Of the The COD value of the treated water was 32 ppm.

(2) The same water used in Example 1 was treated with activated carbon over 1500 microns The flow rate in the fluidized bed was 150 m / h, while the residence time was 20 minutes. The COD value of the treated water was 35 ppm.

Comparative example 2

The same waste water was produced using activated carbon with the same diameter as in Example 1 treated in a stationary shift. The hydraulic load and the residence time of the water were 13 m / h and 20 minutes . The quality of the treated water did not differ much from that of Example 1, as in listed below:

COD of the raw water 80 ppm COD of the treated water 15 ppm

However, the pressure drop in the layer of activated carbon is 1900 mmHpO compared to 47 mmHpO in the fluidized bed.

Comparative example 3

The same waste water as used in Example 1 was treated by a stationary layer process using activated carbon ranging in size from 2000 to 2500 microns. It took 1.5 hours of residence time in the adsorption column in this process to produce water of the same quality as that obtained in Example 1 . -

Brief description of the drawings:

In Fig. 1, the relationship between the grain size and the adsorption rate of the activated carbon is shown. In Fig. 2 is a flow sheet showing an embodiment of the water treatment process according to the present invention is shown. In Fig. 2, the reference symbols have the following meanings:

1 denotes the adsorption column with the activated carbon

2 a fluidized bed made of activated carbon

3 a regeneration column

4 treated water

5 raw water

6 steam

Patent claims:

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0 9 8 3 9/0 9 0 p

Claims (2)

Patent to s ρ riiche 1. method of treating water with activated carbon, characterized in that there is an adsorption fluidized bed of powdered, granular activated carbon with a diameter used in the range between 200 and 1500 microns. 2. The method according to claim 1, characterized in that powdered, granular activated carbon with a diameter used in the range between 250 and 800 microns. 3 · Method according to one or more of claims 1 to 2, characterized in that the adsorption fluidized bed is a fluidized bed of the "solid-liquid countercurrent" - Kind of used. 409839/0906