KR20100038178A - Dissolution pot preventing activated carbon adsorption and activated carbon supply device using dissolution pot - Google Patents

Abstract

PURPOSE: A dissolver for preventing activated carbon from being fixed and a feeder of the activated carbon using the same are provided to uniformly mix powdered activated carbon and solution by making the solution fall along the inner wall of the activated charcoal dissolver. CONSTITUTION: An activated carbon dissolver mixes the activated carbon and water. The activated carbon dissolver includes a first influx unit(410) on the upper end of the dissolver. A first discharging part(430) of a cone type is included on the bottom end of the dissolver. A first storage(450) which saves water provisionally is formed along the circumference of the dissolver in the inner part of the activated carbon dissolver. The water flowing in from a second influx unit(420) is provisionally saved and flows uniformly along the inner wall of the activated carbon dissolver.

Description

Dissolved pot preventing activated carbon adsorption and activated carbon supply device using dissolution pot}

The present invention relates to an activated carbon dissolution tank and an activated carbon supply device, and more particularly, to an activated carbon dissolution tank and an activated carbon supply device using the same, in which powder activated carbon is not hardened therein.

Recently, due to severe pollution of the environment and water quality, it is difficult to remove pollutants by general water purification method, and it is used after high water purification process for drinking and using water. Water purification process has limitations in effectively controlling taste, odor, disinfection by-products, trace harmful organic substances, and the like.

In other words, contamination due to excessive use of pesticides and organic chemicals, odor due to mold odor due to eutrophication and chemical odor due to plant drainage, contamination with disinfection by-products generated during chlorine treatment, and anionic surfactants due to the use of synthetic detergents In order to remove contaminants such as residues, activated water purification using activated carbon is frequently used.

In particular, activated carbon is used not only to remove taste, smell or color, but also to remove carcinogens such as chlorine disinfection by-products such as THM (trihalomethane), benzene (Benzene) and toluene. Its scope of use is gradually expanding.

There is a porous structure with high adsorption performance inside the activated carbon made by carbonizing coconut shells, coal, wood, etc., and these harmful pores are removed using a myriad of pores. Typical activated carbons have a myriad of pores with a diameter of 0.01-100,000 nm and a relatively large internal surface area of 800-1,200 m ³ per gram.

Granular activated carbon, powdered activated carbon, biologically activated carbon, and the like may be used as a method of water purification using activated carbon, and a water purification process using powdered activated carbon is currently widely used.

As such, in order to purify water using activated carbon, a large amount of activated carbon must be stored in silos, etc. The stored activated carbon combines with moisture in the air to be entangled with each other or aggregated in severe cases to form agglomerates, and activated carbon is smooth. It cannot be supplied in a timely manner and causes serious obstacles to the operation of the water purification plant.

Therefore, various conventional techniques have been used to prevent the solidification of activated carbon or an apparatus for automatically and constantly supplying activated carbon stored in silos, but many problems have arisen.

In addition to the problem that the powder is blown when the activated carbon is stored in the activated carbon storage device, when the activated carbon is stored for a long time, the activated carbon is hardened or aggregated inside the silo or the dissolution tank so that the activated carbon cannot be supplied smoothly. This irregularly supplied hole phenomenon caused a problem that it was impossible to automatically and constantly supply the powdered activated carbon.

Accordingly, in order to prevent the activated carbon from being solidified inside the silo or the dissolution tank, a method of installing a separate rotating body or the like to prevent the activated carbon from being hardened was used.

However, using such a method requires not only excessive cost due to the installation and maintenance of a separate rotor, but there is a problem in that even though the rotor is used, there is still activated carbon that is hardened therein and must be removed again. .

This is a temporary solution that does not solve the root cause of the powdered activated carbon solidifying itself if it is left for a long time with moisture in the air, especially when the weather is cold in winter, the temperature difference between the silo and the silo is large. As the moisture condenses on the silo inner wall and condensation occurs, the moisture is absorbed by the powdered activated carbon and prevents the powdered activated carbon from being discharged to the lower part of the silo.

Therefore, in order to prevent the occurrence of moisture inside the silo due to condensation phenomenon, a separate thermostat is installed on the outside or inside of the silo to use the activated carbon supply device. It can not be prevented, and also there is a problem that the installation and maintenance costs of the thermostat additionally occurs.

In the activated carbon dissolution tank where the powdered activated carbon and water are mixed, the moisture content of the powdered activated carbon is higher, and the phenomenon of sticking to the inner wall of the dissolution tank occurs more frequently, and fine water droplets generated while supplying moisture are adsorbed to the activated carbon inlet. Since the phenomenon of blocking the connection receiving the activated carbon occurs frequently, the normal operation of the device was not possible, and the inconvenience of having to periodically clean the inside at a separate cost.

In addition, as sediment accumulates on the bottom of the dissolution tank, the capacity of the dissolution tank becomes relatively small, and when the combination of the water flowing into the dissolution tank and the discharge of the discharge pump is changed, the mixed liquid flows out of the dissolution tank, thereby preventing the operation of the whole water treatment plant. Since it has to be stopped, it causes inconvenience in use and great economic loss.

An object of the present invention for solving the above problems,

After installing the passage of activated carbon and the passage of water into the melting tank, the water is temporarily stored, and then vacuum pressure (negative pressure) is formed inside the dissolving tank through the ejector connected to the lower part of the dissolving tank. It is intended to provide an activated carbon dissolution tank and an activated carbon supply apparatus using the same, by constantly flowing down, thereby preventing the sticking and agglomeration of the mixed liquid and supplying activated carbon constantly.

The configuration of the present invention for achieving the above object,

In the activated carbon dissolution tank for mixing the activated carbon and water, the activated carbon dissolution tank is formed in a cone shape having a first inlet through which activated carbon can be introduced at the upper end, and a first discharge unit through which the mixed liquid can be discharged. The inside of the upper end of the activated carbon dissolving tank is formed with a first storage unit capable of temporarily storing water along a circumference, and the water flowing from the second inlet may be temporarily stored along the inner wall of the activated carbon dissolving tank. It is characterized by that.

In addition, the activated carbon dissolution tank is characterized in that the second storage portion is formed in a conical shape surrounding the lower end to temporarily store a mixture of activated carbon and water discharged from the first discharge portion.

In addition, the upper end of the activated carbon dissolution tank is characterized in that the air vent for filtering the powder of activated carbon is formed.

In addition, the present invention activated carbon supply apparatus is a silo for storing activated carbon, an air inlet pipe for supplying dry air, activated carbon storage tank consisting of a plurality of air pads connected to the air inlet pipe to supply dry air into the silo, Bin activator coupled to the lower portion of the activated carbon storage tank for smoothly supplying activated carbon, activated carbon inlet through which activated carbon flows from the empty activator, a sliding gate valve, a metering hopper for measuring and constantly supplying the weight and volume of activated carbon, the metering Activated carbon outlet for discharging activated carbon downward from the center of the hopper to discharge activated carbon, servo motor for controlling the supply of activated carbon, air control nozzle for adjusting the air pressure of the metering hopper and activated carbon outlet, air vent for filtering activated carbon powder Feeder consisting of, with the feeder on the top And a first inlet through which activated carbon received from the first gas inlet is formed, and a first discharge part through which a mixed solution can be discharged is formed at a lower end thereof, and water may be temporarily stored along the periphery inside the upper end. A first liquid storage unit is formed, and the mixed liquid inlet to which the activated carbon dissolving tank and the mixed liquid supplied from the activated carbon dissolving tank are introduced to allow the water flowing from the second inlet to temporarily flow along the inner wall of the activated carbon dissolving tank, And an ejector configured to reduce the pressure of the mixed liquid, a nozzle connected to the end of the reducer and mixed with water, and a diffuser configured to lower the pressure of the mixed liquid discharged by being connected to the end of the nozzle.

In addition, the activated carbon dissolution tank is characterized in that the second storage portion is formed in a conical shape surrounding the lower end to temporarily store a mixture of activated carbon and water discharged from the first discharge portion.

In addition, the upper end of the activated carbon dissolution tank is characterized in that the air vent for filtering the powder of activated carbon is formed.

In addition, the lower cone (Cone) and the upper shell (Shell) of the activated carbon storage tank is characterized in that a plurality of air pads are attached at regular intervals concentrically.

In addition, one air inlet pipe is attached to the upper shell of the activated carbon storage tank, and two air inlet pipes are attached to the lower cone.

In addition, the air pads attached to the outside of the lower cone of the activated carbon storage tank is attached to each of the eight angles made of 45 ° angle, each of the air pads attached to the inside is formed of an angle of 90 °, characterized in that the four attached It is done.

In addition, the air pads attached to the upper shell of the activated carbon storage tank is characterized in that 4 to 12 are attached to each.

The effect of the present invention having the configuration as described above,

In order to mix the powdered activated carbon and the melted water, the powdered activated carbon and the melted water were mixed with the activated carbon dissolution tank by the agitator and the motor by the rotational force by the impeller. Although the maintenance and repair costs continue to be consumed, in the present invention, by forming a first storage unit for storing molten water primarily so that the dissolved water flows down the inner wall of the activated carbon dissolution tank so that the powdered activated carbon and the dissolved water are constantly mixed. The advantage is that initial installation costs are saved and maintenance and repair costs are not required.

In addition, even when the powdered activated carbon and the dissolved water are mixed by the continuous rotation of the conventional impeller, the precipitates are accumulated and accumulated in the place where the impeller does not reach the rotational force, and the combination of the amount of the dissolved water flowing into the dissolution tank and the amount of the mixed liquid discharged by the pump If this is different, the mixed liquid and the dissolved water flows out of the activated carbon dissolution tank, there is an inconvenience and economic loss to stop the operation of the whole water purification facility and repair, but in the present invention, the dissolved water flows uniformly along the entire inner wall of the activated carbon dissolution tank In addition, the powder activated carbon is mixed to form a vacuum pressure (negative pressure) inside the dissolution tank through an ejector connected to the lower part of the dissolution tank so that the mixed liquid flows uniformly along the dissolution tank. I can prevent the overflow phenomenon Not only is it easy to maintain water purification facilities, but economic benefits can also be achieved.

In addition, when the molten water is supplied to the activated carbon dissolution tank, a phenomenon in which fine water droplets are adsorbed to the activated carbon inlet and reacts with the fine powder of the activated carbon falling from the feeder to block the activated carbon inlet often occurs, but in the present invention, it is introduced from the second inlet. Dissolved water naturally flows through the inner wall of the activated carbon dissolution tank to form a water film over the inner wall of the first reservoir, and forms a vacuum pressure (negative pressure) inside the dissolution tank through an ejector connected to the lower part of the dissolution tank, thereby dissolving the dissolved water and the mixed liquid to the lower portion of the dissolution tank. Since it can continue to move, because the fine water droplets are combined with the activated carbon inlet does not occur, there is no maintenance and maintenance costs, there is an advantage that can use the same function for a longer period of time.

In addition, the present invention has a second storage portion formed of a conical shape surrounding the lower end of the activated carbon dissolution tank for temporarily storing a mixture of powdered activated carbon and dissolved water discharged from the first discharge portion, the mixture of powdered activated carbon and dissolved water It is more convenient and safer because not only can be made easier, but also a buffering function of the mixed liquid supplied to the ejector.

Further, in the present invention, an air vent for filtering the powder of activated carbon is formed at the upper end of the activated carbon dissolution tank, so that the powder of powdered activated carbon supplied to the first inlet portion can be prevented from being blown and fixed to any area of the activated carbon dissolution tank. It does not require maintenance and repair costs, and has the advantage of supplying activated carbon constantly and safely.

In addition, in the present invention, since the air pads are connected to the lower cone and the upper shell of the activated carbon storage tank at regular intervals in a concentric manner and dry air can be supplied from the compressor, Not only can it prevent sticking, but even if condensation occurs due to extreme temperature differences, it does not need to install a separate thermal insulation device to prevent condensation in the activated carbon storage tank by evaporating moisture contained in activated carbon and discharging it to the upper bag filter. There is an advantage that long-term storage of powdered activated carbon in the activated carbon storage tank installed outdoors.

1 is a schematic view showing an activated carbon supply apparatus according to the present invention.
2 is a front view of an activated carbon storage tank used in the activated carbon supply apparatus according to the present invention.
3A is a cross-sectional view taken along line AA of FIG. 2.
Figure 3b is a detailed view showing a connection state of the air pad used in the present invention.
4 is a front view showing a feeder used in the activated carbon supply apparatus according to the present invention.
5 is a front view showing an activated carbon dissolution tank used in the activated carbon supply apparatus according to the present invention.
6 is a cross-sectional view and a partially enlarged view showing the interior of the activated carbon dissolution tank used in the activated carbon supply apparatus according to the present invention.
7 is a cross-sectional view showing an ejector used in the activated carbon supply apparatus according to the present invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 is a schematic view showing an activated carbon supply apparatus according to the present invention. In general, activated carbon supply apparatus is used in a water purification facility for purifying contaminated water, activated carbon storage tank 100 for storing the activated carbon to supply powdered activated carbon, bin for discharging the activated carbon constantly from the activated carbon storage tank 100 Activator 200 (Bin Activator), the feeder 300 (Feeder) for constantly supplying the activated carbon discharged from the empty activator 200 (Feeder), for mixing the powdered activated carbon discharged from the feeder 300 with dissolved water Activated carbon dissolving tank 400, connected to the lower portion of the activated carbon dissolving tank 400 to form a vacuum pressure (negative pressure) in the interior of the activated carbon dissolving tank 400 so that the mixed liquid flows constantly along the inside of the dissolving tank and the activated carbon dissolving tank ( It consists of an ejector 500 (Ejector) for injecting the mixed liquid discharged from 400 to the outside.

As shown in FIG. 2, the activated carbon storage tank 100 is connected to the silo 110 for storing activated carbon, an air inlet pipe 120 for supplying dry air, and the air inlet pipe 120. It consists of a plurality of air pads 130 for supplying dry air to the inside, the tank lorry transported by a vehicle or the like is connected to supply powdered activated carbon, the activated carbon storage tank from the tank through the air transfer means using the air ( 100) can automatically transfer the powdered activated carbon, it is faster and more economical because it can reduce the labor cost and management cost than if the human is artificially transferred to the activated carbon.

In addition, a dust collector such as a bag filter is connected to the activated carbon storage tank 100 to filter the powder of activated carbon sucked and conveyed by the air transfer means, and the collected activated carbon is returned to the activated carbon storage tank 100. Can be self-cleaning while dosing. Therefore, it is possible to prevent the dust or fly dust generated when transporting the powdered activated carbon to the atmosphere to pollute the surrounding environment.

An empty activator 200 and a vibration motor are attached to the lower end of the activated carbon storage tank 100 to solve the phenomenon of cavitation or bridge phenomenon in which powdered activated carbon discharged from the activated carbon storage tank 100 is stagnant. It is possible to smoothly supply the powdered activated carbon stored in the), and to prevent the powdered activated carbon from being discharged only one or part thereof.

A feeder 300 for supplying powdered activated carbon constantly is connected to a lower end of the empty activator 200, and a weight feeder for supplying activated carbon by measuring a weight according to a method of supplying activated carbon, and activated carbon Various methods may be used, such as a loss-in weight feeder for supplying activated carbon by measuring decreasing weight, and a screw feeder for supplying activated carbon by constantly rotating the screw.

The feeder 300 used as an embodiment of the activated carbon supply apparatus according to the present invention as shown in FIG. 4 includes an activated carbon inlet 310, a slide gate valve 320, through which activated carbon flows from the empty activator 200. Weighing hopper 330 to measure the weight and volume of activated carbon and supply it constantly, Activated carbon outlet 340 extending to one side from the center of the hopper 330 to discharge the activated carbon to the bottom, Servo for controlling the supply of activated carbon The motor 350, the metering hopper 330 and the activated carbon outlet 340, the air adjusting nozzle 360 for adjusting the pressure of the air, and the activated carbon powder to filter the air vent 370.

The slide gate valve 320, which maintains or temporarily blocks the flow of activated carbon flowing from the activated carbon inlet 310, can be used during maintenance and repair of the apparatus, and can be directly controlled by human operation. Or it can be adjusted automatically by setting.

Rotary valves and the like may be further attached to the lower end of the slide gate valve 320 to automatically supply activated carbon according to the remaining amount of powdered activated carbon in the metering hopper 330 installed at the lower portion.

The metering hopper 330 has a cylindrical shape, and an electronic balance or sensor is attached along the outer circumference to measure the weight of the activated carbon stored in the metering hopper 330 to adjust the supply amount of the activated carbon, or Activated carbon may be supplied by continuously measuring the loss of activated carbon in the metering hopper 330 by a volume control method.

An activated carbon outlet 340 is formed at the lower end of the metering hopper 330 for discharging activated carbon. The powder activated carbon is discharged to a discharge port formed primarily at the lower part of the metering hopper 330. The activated carbon is discharged to the center of the center 330, that is, the activated carbon outlet 340 which is secondly formed extending from one outlet of the metering hopper 330.

As a method of moving the activated carbon from the outlet of the metering hopper 330 to the activated carbon outlet 340, there is also a method of adjusting the supply of activated carbon through rotation by the servo motor 350 as described above. There is also a method of pushing out constantly using the rotational force, it is also possible to use a method of pushing out constantly through the spring pressure or hydraulic pressure.

In the case of the metering hopper used in the prior art, when pressure is generated in the activated carbon reservoir or the metering hopper, a flushing phenomenon occurs in the powdered activated carbon, and when the flushing phenomenon occurs, the powder flows like a liquid, so that the minute gaps of the respective devices Activated carbon is also leaked out between, and it is difficult to control the supply of activated carbon, and the powdered activated carbon delivered from the upper part is discharged directly to the primary outlet formed at the center of the metering hopper, which makes it difficult to control and maintain the activated carbon supply device.

However, as described above, when the activated carbon outlet 340 is formed to extend to one side from the central outlet of the metering hopper 330 to be secondary (in two stages), even if a pressure and a flushing phenomenon applied from the upper side occur, the powder activated carbon is Not only is it not directly discharged to the bottom, there is an advantage that the supply of activated carbon can be more smoothly controlled through the secondary control device.

In addition, an air control nozzle 360 is connected between the metering hopper 330 and the activated carbon outlet 340 to discharge the pressure of the powder activated carbon and air present in the metering hopper 330 and the activated carbon outlet 340. By controlling the pressure between the powdered activated carbon is to prevent the phenomenon that the activated carbon is not excessively discharged at all or not at all, it is possible to adjust the activated carbon supply more smoothly.

In addition, an air vent 370 is formed at an upper end of the metering hopper 330 to remove dust generated when powdered activated carbon is added or discharged.

5 is a front view showing an activated carbon dissolution tank 400 used in the activated carbon supply apparatus according to the present invention, Figure 6 is a cross-sectional view and a partial enlarged view showing the interior of the activated carbon dissolution tank 400 used in the activated carbon supply apparatus according to the present invention. to be.

Activated carbon dissolution tank 400 for mixing the activated carbon and water according to the present invention is formed with a first inlet 410 through which the activated carbon can be introduced, the first discharge portion 430 that can be discharged to the mixed liquid at the bottom Is formed in a conical shape, the inside of the upper end of the activated carbon dissolving tank 400 is formed with a first storage unit 450 that can be temporarily stored along the circumference, from the second inlet 420 After the incoming water is temporarily stored, a vacuum pressure (negative pressure) is formed in the activated carbon dissolving tank 400 through an ejector 500 connected to the lower portion of the activated carbon dissolving tank 400 so that the mixed liquid flows uniformly along the inside of the dissolving tank. Characterized in that.

Conventionally, a large-capacity dissolution tank was required to mix the powdered activated carbon and the dissolved water, as well as the activated carbon dissolution tank by using an agitator and a motor in the activated carbon dissolution tank to prevent the adhering and sticking of the powdered activated carbon. Because of the mixing, not only the initial installation cost is excessively consumed, but there is a problem that the maintenance and repair costs are continuously consumed over time.

In addition, even when the powder activated carbon and the dissolved water are mixed by the continuous rotation of the conventional impeller, deposits accumulate and accumulate at corners where the impeller does not reach the rotational force, and thus the amount of the dissolved water flowing into the dissolution tank and the mixed liquid discharged by the pump. If the combination of amounts is different, the mixed liquid and dissolved water flows out of the activated carbon dissolution tank, causing inconvenience and economic loss to stop the whole operation and repair.

In addition, when supplying the dissolved water to the conventional activated carbon dissolution tank, the fine water droplets generated by the pressure imbalance and friction caused by the melted water is adsorbed to the activated carbon inlet and combined with the fine powder of activated carbon falling from the feeder to continue to be stacked on the activated carbon inlet side. There was a problem that often occurs a phenomenon that blocks some or all of the activated carbon inlet.

Activated carbon dissolution tank 400 according to the present invention is powder activated carbon is introduced into the first inlet 410 from the top through the feeder 300, dissolved water from the second inlet 420 connected to the side is activated carbon and Dissolved water is mixed, and the first inlet 450 is formed inside the dissolution tank to which the second inlet 420 is connected.

That is, the first storage unit 450 is formed along the inner circumference of the activated carbon dissolution tank 400 with a predetermined thickness, and the inner side of the first storage unit 450 is higher than the outer side so that the melted water can flow out. It is formed small and is spaced apart from the top by a certain distance.

Therefore, when the molten water flows into the first storage unit 450 and rises to the inner wall height, the molten water flows into the space separated from the upper portion, and the overflowed molten water flows down the inner wall of the activated carbon dissolution tank 400. Will flow. Accordingly, by allowing the powder activated carbon introduced from the first inlet 410 to be constantly mixed with the dissolved water, there is an advantage that the initial installation cost is saved and maintenance and repair costs are not required compared to the conventional dissolution tank. .

In the present embodiment, the height of the inner wall forming the first storage part 450 is uniformly formed along the circumference of the activated carbon dissolving tank 400 to make the space spaced apart from the upper portion of the activated carbon dissolving tank 400. At the same time, the melted water was allowed to flow down at any time, but for the smoother mixing of the powdered activated carbon and the melted water, a portion of the inner wall of the first storage part 450 was made smaller so as to form an inclined surface. By allowing the melted water to flow in a spiral shape in the desired direction, it can be mixed more quickly and easily without a rotor blade or impeller.

In addition, conventionally used activated carbon dissolution tanks and impellers are not used, and pumps for discharging the mixed liquid are not used, and powdered activated carbon is mixed while the dissolved water is constantly flowing along the entire inner wall of the activated carbon dissolution tank 400, and is connected to the lower portion. Since it is automatically transferred by the vacuum pressure applied to the ejector 500, it is possible to reduce the installation cost, and there is no fear of depositing sediment, and it is possible to prevent the phenomenon that the mixed liquid and the melted water flows, thereby making it easy to maintain the water purification facility. Not only that, but also economic benefits can be achieved.

Furthermore, in the present invention, since the melted water flowing from the second inlet 420 naturally flows over the inner wall of the first storage unit 450 and flows through the inner wall of the activated carbon dissolution tank 400 to form a water film, fine water droplets are generated. Since it does not occur because the phenomenon that the first inlet 410 is prevented from sticking to the activated carbon flowing into the first inlet 410 does not occur, the maintenance and repair cost does not occur, and use the same function for a longer period of time There is an advantage that it can.

In addition, in the present invention, the second storage unit 460 is formed in a conical shape surrounding the lower end of the activated carbon dissolution tank 400 to temporarily store a mixture of powdered activated carbon and dissolved water discharged from the first discharge unit 430. Since it is formed, it is possible to not only make the mixing of the powdered activated carbon and the dissolved water more easy, but also to buffer the mixed liquid supplied to the ejector 500, which is more convenient and safe.

In the present invention, the air vent 470 for filtering the powder of activated carbon is formed at the upper end of the activated carbon dissolution tank 400, the powder of powdered activated carbon supplied to the first inlet 410 is blown activated carbon dissolution tank 400 Since it can be prevented from adhering to any area of the maintenance and repair costs are not required, there is an advantage that can be supplied in a constant and safe activated carbon.

7 is a cross-sectional view showing the ejector 500 used in the activated carbon supply apparatus according to the present invention. The ejector 500 is connected to the mixed liquid inlet 510 into which the mixed liquid supplied from the activated carbon dissolution tank 400 flows, a reducer 520 for lowering the pressure of the mixed liquid, and a nozzle mixed with water at the end of the reducer 520. 530, the diffuser 540 is connected to the end of the nozzle 530 to lower the pressure of the mixed liquid discharged.

As described above, unlike the conventional method of discharging the mixed liquid using a pump, the mixed liquid is introduced into the mixed liquid inlet 510 connected to the second discharge part 440 of the activated carbon dissolution tank 400, The mixed liquid passes through the reducer 520 and a certain amount of pressure is lowered. Thereafter, the end of the reducer 520 is connected to be in contact with a part of the nozzle 530 for discharging high pressure water, and the mixed liquid and water are mixed once again, through the diffuser 540 connected to the end of the nozzle 530. The pressure of the final mixed liquor is lowered.

Therefore, not only a separate device such as a pump is required, but also the nozzle 530 and the diffuser 540 are operated by using a pressure difference between the inlet and the outlet of the ejector 500. No more power is needed, and by using the vacuum pressure generated in the nozzle 530 as described above, the liquid mixture discharged from the activated carbon dissolution tank 400 can be more easily and easily discharged, thereby saving energy, maintaining and Management costs can be reduced.

In addition, the activated carbon storage tank 100 as shown in Figure 2 is an activated carbon storage silo 110 (Silo), dry air supply is formed integrally of the upper shell (Shell) made of a cylindrical shape and the lower cone (Cone) made of a cone Air inlet pipe 120 for supplying dry air to the silo 110 from the outside connected to the device and a plurality of air connected to the air inlet pipe 120 to supply the dry air into the silo 110 Pad 130 is made.

The powder activated carbon storage tank 100 determines the size of the powder activated carbon in consideration of the amount of powder activated carbon input and the storage period, and is used at a capacity of about 100 m ³ or less or 300 m ³ or less. In addition, powder activated carbon, which is introduced for the first time, may not be kept in a state that does not completely contain moisture, so powdered activated carbon having a drying loss of 5% is used.

In this process, according to the conventionally used activated carbon storage tank, if stored for a long time with a large amount of powder activated carbon contained therein, the phenomenon that the activated carbon is often fixed while containing more water vapor in the air, as well as In the lower cone of the activated carbon storage tank, smooth discharge does not occur due to the self-load of the powdered activated carbon, as well as a bridge phenomenon occurs, thus preventing the water purifier from performing its main function and continuing maintenance and repair costs. .

In order to solve this problem, a vibrator or an air pad is attached to the lower cone of the activated carbon storage tank. Such a vibrator or air pad was used to provide fluidization to the oil powder stored in the silo to solve the obstacle of activated carbon discharge due to the bridge phenomenon.

In other words, the activated carbon stored in the silo is compacted by its own load to solve the problem of not being discharged smoothly, to prevent the cavitation phenomenon, and to increase the water content of the powdered activated carbon inside the silo to prevent the powdered activated carbon from agglomerating. It would have been.

However, as in the summer and the rainy season, the moisture content of the air is increased to increase the moisture content of the powdered activated carbon, or the temperature difference between the inside and the outside of the activated carbon storage silo is large, such as at dawn, so that condensation may occur on the inner surface of the silo. When the hygroscopic powdered activated carbon contains moisture, a phenomenon occurs that the activated carbon storage silo is fixed to the inner surface of the activated carbon storage silo, but only by attaching a vibrator or an air pad to the lower cone portion of the conventional activated carbon storage tank, The fixation phenomenon of the upper shell portion could not be prevented or eliminated.

Accordingly, the silo used in the conventional activated carbon supply device has a separate thermal insulation facility outside the silo to prevent condensation caused by the temperature difference between the activated carbon having moisture retention and moisturizing and external air and the solidification of the powdered activated carbon. Installation and maintenance costs continue to be incurred.

According to the activated carbon storage silo 110 according to the present invention, even if the above condensation occurs without using a separate thermal insulation device, it is possible to prevent sticking of activated carbon.

That is, the air inlet pipe 120 and the air pad 130 are installed not only in the lower cone of the activated carbon storage silo 110 but also in the upper shell portion, so that 99.9% or more of moisture is removed. It is injected into the 110 to remove the moisture in the silo 110.

Firstly, the moisture evaporated by the dry air flowing into the air pad 130 installed in the lower cone portion of the activated carbon storage silo 110 is sent up to the upper portion of the silo 110, and the activated carbon storage silo secondly ( Moisture raised from the bottom by the dry air flowing into the air pad 130 installed in the upper shell portion of the 110 may be discharged to the outside of the silo 110.

Therefore, condensation is prevented even without installing a separate thermostat, which prevents the solidification of the powdered activated carbon, as well as the powdered activated carbon in the activated carbon storage tank 100 installed outdoors for a long time without deformation. It can be stored and has the advantage of reducing the cost of the thermostat.

Silo capacity Air pad use number Air usage (per EA) Lower Cone Upper shell l / sec ~ 100 m ³ 12 6 ~ 8 6 ~ 300 m ³ 18 10-12 6

As shown in Table 1, the number of air pads 130 required for the activated carbon storage silo 110 may be variously set according to the capacity of the activated carbon storage silo 110. According to various embodiments of the activated carbon supply apparatus of the present invention, when the capacity of the silo 110 is 100 m ³ or less, 12 air pads 130 are attached to the lower cone, and about 6 to 8 air pads 130 are attached to the upper shell. It is preferable to attach and use, and when the capacity of the silo 110 is 300 m ³ or less, 18 air pads 130 are attached to the lower cone, and about 10 to 12 air pads 130 are attached to the upper shell. It is preferable to attach and use.

In addition, when supplying dry air to the activated carbon storage silo 110, it is preferable to supply dry air from which 99.9% of moisture has been removed. In order to supply dry air as described above, a precooler is sucked by sucking an external atmosphere. By cooling to a temperature close to the dew point temperature, by using a dry dehumidifier to produce a high-temperature low-humidity dry air by a dry dehumidification method it can be supplied to the silo 110 through the blower 110, the relative humidity close to 0%. .

Supplying the dry air as described above to the upper and lower portions of the activated carbon storage tank 100 can significantly reduce the water contained in the powdered activated carbon. When stored inside the silo without using the pad, the loss on drying increased to about 11%, and the solidification of powdered activated carbon easily occurred. If condensation occurs frequently on the silo, the loss on drying is further increased.

However, according to an embodiment of the present invention in which 12 air pads 130 are installed in the lower cone of the activated carbon storage tank 100 and 4 air pads 130 are installed in the upper shell, activated carbon having a drying loss of 5% After 6 months of storage, the sample was taken and the loss of drying was measured. As a result, the loss of drying was maintained at 0.4%.

Therefore, as in the present invention, by supplying dry air, the drying loss of the powdered activated carbon stored in the silo 110 can be drastically lowered, thereby preventing the solidification phenomenon in the silo 110 and smoothing the powdered activated carbon. As the supply can be maintained, it is easy to maintain and manage water purification facilities.

On the other hand, as shown in Figure 3a, according to an embodiment of the present invention, the air pads 130 attached to the outside of the lower cone of the activated carbon storage tank 100 are each formed at an angle of 45 ° is attached to eight Preferably, the air pads 130 attached to the inner side are preferably formed at four angles of 90 ° each. According to such a configuration, the moisture remaining in the silo 110 is not only easy to supply dry air to the activated carbon storage tank 100 but also to supply dry air at regular intervals and angles as will be described later. It can be removed and it is easy to supply powdered activated carbon to the bottom.

Further, as shown in Figure 3b, the air pad 130 is connected to the solenoid valve by tying the two into one tube. As such a tube, various kinds of tubes such as a copper tube, a copper tube, a stainless tube, or a PVC tube may be used. In addition, the open / close time of the solenoid valve may be controlled through a time control box, and the open and close time of the solenoid valve may be adjusted by adjusting a pulse signal in the time control box.

In the case of the air pad 130 attached to the lower cone of the activated carbon storage silo 110, the open time of the solenoid valve may be adjusted to about 3 to 6 seconds and the close time to about 2 seconds. If the continuous air is continuously supplied, the pressure of the dry air is filled inside the activated carbon storage silo 110, and the drying loss of activated carbon may be deteriorated. Therefore, the open time and the close time within an appropriate range. Can be adjusted.

That is, according to an exemplary embodiment as shown in FIG. 3A, six solenoid valves are connected by connecting two twelve air pads 130 two by two, and the solenoid valves are numbered 1 to 6 by the time control box. Continuously open / close sequentially to inject dry air.

Opening / closing all the air pads 130 at once by adjusting all solenoid valves increases the amount of dry air that must be supplied at one time, and the installation cost increases because the capacity of the compressor to supply air must increase. Too much.

In addition, when each solenoid valve is sequentially opened and closed as described above, a weak rotation phenomenon occurs inside the powder activated carbon, so that discharge by activated carbon itself can be more smoothly discharged, and at the same time, the powder activated carbon is cavitation. It is more efficient to prevent the phenomenon, and it is easier to remove moisture of the powdered activated carbon due to condensation.

The open / close process of the air pad 130 as described above has been described using only the one connected to the lower cone of the silo 110 as an example, but the overall of the air pad 130 connected to the upper shell of the silo 110 is described. The operation process is also operated as described above, which is more effective in smoothly discharging the powdered activated carbon and removing moisture in the silo 110.

In addition, by discharging the moisture raised through the lower cone and the upper shell of the activated carbon storage silo 110 to the outside through a bag filter installed on the top of the silo 110, the silo does not need to be equipped with a separate thermal insulation device for preventing condensation ( 110) The powder activated carbon stored therein can be stored for a long time.

The present invention described above is not limited to the above-described embodiment and the accompanying drawings, and it is common in the art that various substitutions, modifications, and changes can be made without departing from the technical spirit of the present invention. It will be evident to those who have knowledge of.

100: activated carbon reservoir 200: Bin Activator
300: feeder 400: activated carbon dissolution tank
500: ejector
110: silo 120: air inlet pipe
130: air pad 310: activated carbon inlet
320: slide gate valve 330: metering hopper
340: activated carbon discharge port 350: Servo Motor
360: air adjusting nozzle 370: air vent
410: first inlet 420: second inlet
430: the first discharge unit 440: the second discharge unit
450: first storage unit 460: second storage unit
470: Air Vent 510: Mixed Liquid Inlet
520: Reducer 530: Nozzle
540 Diffuser

Claims (10)

In the activated carbon dissolution tank 400 for mixing the activated carbon and water,
The activated carbon dissolution tank 400 has a conical shape in which a first inlet 410 through which activated carbon can be introduced is formed at an upper end thereof, and a first outlet 430 through which a mixed solution can be discharged is formed at a lower end thereof. ,
Inside the upper end of the activated carbon dissolving tank 400, a first storage part 450 is formed to temporarily store water along a circumference, and the water flowing from the second inlet part 420 is temporarily stored and then activated carbon. Activated carbon dissolution tank 400, characterized in that to flow constantly along the inner wall of the dissolution tank 400.
The method of claim 1,
The activated carbon dissolution tank 400 is formed in a conical shape surrounding the lower end of the second storage unit 460 for temporarily storing a mixture of activated carbon and water discharged from the first discharge portion 430 is characterized in that the formed Activated carbon dissolving tank 400.
The method according to claim 1 or 2,
Activated carbon dissolution tank 400, characterized in that the air vent (470) for filtering the powder of activated carbon is formed on the upper end of the activated carbon dissolution tank (400).
Silos 110 for storing activated carbon, air inlet pipes 120 for supplying dry air, and a plurality of air pads 130 connected to the air inlet pipes 120 for supplying dry air into the silo 110. Activated carbon storage tank 100 consisting of;
An empty activator 200 coupled to a lower portion of the activated carbon storage tank 100 to smoothly supply activated carbon;
Activated carbon inlet 310, the slide gate valve 320, the measuring hopper 330 to measure the weight and volume of the activated carbon from the empty activator 200, and constantly supplying the center of the measuring hopper 330 Activated carbon outlet 340 extending from one side to discharge the activated carbon to the lower side, the servo motor 350 for adjusting the activated carbon supply, the air conditioning to adjust the pressure of the air of the metering hopper 330 and the activated carbon outlet 340 A feeder 300 composed of a nozzle 360 and an air vent 370 for filtering activated carbon powder;
The upper inlet 410 is formed in the upper end of the activated carbon supplied from the feeder 300, the first discharge portion 430 is formed in a conical shape is formed in which the mixed liquid can be discharged The inside of the upper end is formed with a first storage unit 450 which can temporarily store water along the circumference, and the water flowing from the second inlet 420 is temporarily stored and then of the activated carbon dissolution tank 400. Activated carbon dissolution tank 400 to be constantly flow along the inner wall and
The mixed liquid inlet 510 into which the mixed liquid supplied from the activated carbon dissolution tank 400 flows, a reducer 520 for lowering the pressure of the mixed liquid, a nozzle 530 connected to the end of the reducer 520 and mixed with water, and the nozzle Activated carbon supply apparatus comprising an ejector (500) consisting of a diffuser (540) for lowering the pressure of the mixed liquid discharged in connection with the end of the (530).
The method of claim 4, wherein
The activated carbon dissolution tank 400 is formed in a conical shape surrounding the lower end of the second storage unit 460 for temporarily storing a mixture of activated carbon and water discharged from the first discharge portion 430 is characterized in that the formed Activated carbon supply device.
The method according to claim 4 or 5,
Activated carbon supply apparatus, characterized in that the air vent (470) for filtering the powder of activated carbon is formed on the upper end of the activated carbon dissolution tank (400).
The method of claim 6,
Activated carbon supply apparatus, characterized in that the lower cone (Cone) and the upper shell (Shell) of the activated carbon storage tank 100 has a plurality of air pads 130 are attached at regular intervals concentrically.
The method of claim 7, wherein
Activated carbon supply apparatus, characterized in that one air inlet pipe 120 is attached to the upper shell of the activated carbon storage tank 100, and two air inlet pipes 120 are attached to the lower cone.
The method of claim 8,
Eight air pads 130 attached to the outer side of the lower cone of the activated carbon storage tank 100 are each attached to form an angle of 45 °, the air pads 130 attached to the inside each make an angle of 90 ° Activated carbon supply apparatus, characterized in that four attached.
The method of claim 9,
Activated carbon supply apparatus, characterized in that the air pad 130 attached to the upper shell of the activated carbon storage tank 100 is attached to each of four to twelve.

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