KR20200053433A - Sludge drying apparatus of scrubber for treating exhaust gas of ship - Google Patents

Abstract

The present invention relates to a sludge drying apparatus for a scrubber for treating exhaust gas of a ship. According to one embodiment of the present invention, the sludge drying apparatus for a scrubber for treating exhaust gas of a ship comprises: a vacuum chamber which receives sludge discharged from a water treatment system for treating sludge included in polluted water discharged from a scrubber for treating exhaust gas from a ship, and subjects the received sludge to a vacuum treatment; a vacuum pump which discharges gas inside the vacuum chamber; and a cold trim which is disposed between the vacuum chamber and the vacuum pump, and separates moisture and dried gas from the gas discharged from the vacuum chamber, wherein the vacuum chamber may subject the sludge introduced therein to a vacuum treatment, separate the sludge from gas containing moisture, and discharge the dried sludge separated from the moisture to the outside. According to the present invention, the sludge drying apparatus dries sludge on the ship before discharging the sludge and thus can prevent the sludge from being released to the outside while removing moisture from the sludge, and furthermore, can prevent polluted water from recirculating.

Description

SLUDGE DRYING APPARATUS OF SCRUBBER FOR TREATING EXHAUST GAS OF SHIP}

The present invention relates to a sludge drying apparatus for a scrubber for exhaust gas treatment of a ship, and more specifically, a sludge drying apparatus for a scrubber for exhaust gas treatment of a ship capable of drying and discharging sludge generated in a scrubber of a ship. It is about.

Ships use heavy fuel oil (HFO) to reduce the cost of fuel, which can contain more than 3.5% sulfur. These heavy oils have low viscosity, low volatility, and low flammability, and heavy oils contain large amounts of impurities such as moisture and solids. Therefore, heavy oil cannot be used as it is, and water and other impurities contained in heavy oil are removed using a heater, centrifuge, and homogenizer, and then the fuel of the ship is used.

In the process of processing heavy oil, sludge included in heavy oil is generated, and the sludge contains sulfur oxides. Sulfur oxide is a major air pollutant, which causes acid rain or acts on the mucous membranes of the human body, causing respiratory diseases. In addition, in the case of particulate matter, it penetrates into the alveoli of a person and is a direct cause of various respiratory diseases and serves to decrease immune function.

However, conventionally, sludge generated from a scrubber for treating heavy oil in a ship is stored in a sludge tank and disposed of through land unloading. In this way, the sludge stored in the sludge tank includes some washing water, and thus includes a process of removing the washing water by heating when it is disposed of. At this time, there is a problem that causes secondary environmental pollution in the process of removing the washing water. Moreover, there is a problem in that the cost according to weight increases due to the washing water contained in the sludge tank.

In addition, since the conventional sludge tank is stored in a ship, when the ship enters the port, there is a problem that the sludge tank filled with sludge is unloaded and an empty sludge tank is installed on the ship.

Republic of Korea Registered Patent No. 10-1895897 (2018.08.31)

The problem to be solved by the present invention is to provide a sludge drying apparatus for a scrubber for exhaust gas treatment of a ship that can prevent environmental pollution and reduce costs by removing a gas containing a part of the washing water and contaminated water vapor contained in the sludge. Is to do.

The apparatus for sludge drying of a scrubber for treating exhaust gas of a ship according to an embodiment of the present invention is water treated to treat sludge contained in contaminated water discharged from a scrubber for treating exhaust gas of a ship A vacuum chamber in which sludge discharged from a water treatment system flows in and vacuums the introduced sludge; A vacuum pump that discharges gas from inside the vacuum chamber; It is disposed between the vacuum chamber and the vacuum pump, and includes a cold trim that separates the dried gas from the moisture discharged from the gas discharged from the vacuum chamber, and the vacuum chamber processes the sludge introduced into the vacuum chamber to remove moisture. The contained gas and sludge are separated, and the dried sludge separated from moisture can be discharged to the outside.

It may further include a buffer tank for temporarily storing the sludge discharged from the water treatment system and supplying the stored sludge to the vacuum chamber.

It is disposed between the buffer tank and the vacuum chamber, it may further include a control valve for adjusting the amount accommodated in the vacuum chamber.

The cold trim supplies moisture separated from the gas discharged from the vacuum chamber to the water treatment system, and the dried gas separated from the cold trim can be supplied to the scrubber through the vacuum pump.

A blower for transferring the dried gas discharged from the vacuum pump to the scrubber may be further included.

A condensate tank for condensing and storing the moisture separated from the cold trim; And a water pump supplying condensate stored in the condensate tank to the water treatment system.

The condensate supplied from the water pump to the water treatment system may be supplied to the water treatment system through a pipe through which contaminated water is discharged from the scrubber to the water treatment system.

It is disposed between the vacuum chamber and the cold trim, and may further include a control valve for blocking gas from being discharged from the vacuum chamber to the cold trim to stabilize the vacuum state of the vacuum chamber.

When the vacuum degree of the vacuum chamber is increased, the control valve may be opened and closed so that the vacuum degree is increased step by step.

The vacuum pump may be controlled to be operated so that the vacuum degree of the vacuum chamber is maintained for a predetermined time.

A heater for preventing the inside of the vacuum chamber from freezing may be installed in the vacuum chamber.

According to the present invention, since the sludge is dried and discharged in a ship, it is possible to prevent the sludge from being discharged to the outside in the process of removing moisture from the sludge, and also to prevent recirculation of contaminated water.

In addition, when removing moisture, a vacuum is formed to remove moisture, and it is possible to remove moisture from the sludge in an environmentally friendly manner by controlling so that no internal icing occurs in the vacuum process.

Moreover, as in the prior art, when the vessel enters the port, the sludge tank can be compressed and discharged from the sludge drying apparatus without the need to replace the empty sludge tank, thereby facilitating the treatment of sludge. .

1 is a schematic block diagram showing a sludge drying apparatus for a scrubber for exhaust gas treatment of a ship according to an embodiment of the present invention.
2 is an exemplary view showing a sludge drying apparatus for a scrubber for exhaust gas treatment of a ship according to an embodiment of the present invention.

With reference to the accompanying drawings, a preferred embodiment of the present invention will be described in more detail.

1 is a schematic block diagram showing a sludge drying apparatus for a scrubber for exhaust gas treatment of a ship according to an embodiment of the present invention.

Referring to Figure 1, the sludge drying apparatus 100 according to an embodiment of the present invention, an apparatus for drying the sludge by vacuum drying the sludge discharged from the water treatment system (230) of the ship to be.

In this embodiment, the sludge supplied to the sludge drying apparatus 100 is discharged from the water treatment device 200 of the ship. Sludge from the ship is supplied with the exhaust gas discharged from the engine 210 to a scrubber (220), and purifies the exhaust gas from the scrubber 220 to discharge polluted water to the water treatment system 230. At this time, the water treatment system 230 treats contaminated water to discharge fresh water and sludge. Fresh water may be supplied from the water treatment system 230 to a water monitoring system 240, and may be supplied to the scrubber 220 from the water management system 240.

The scrubber 220 is a water treatment device 200 for purifying exhaust gas discharged from the engine 210 of the ship, that is, the turbocharger, flowing the exhaust gas of the ship from bottom to top and spraying fresh water from above to disperse sulfuric acid from the exhaust gas Cargo (SOx) and particulates (PM) are filtered and purified.

The water treatment system 230 is a device for purifying contaminated water discharged from the scrubber 220 of the ship. At this time, the water treatment system 230 may be neutralized by adding sodium hydroxide (NaOH) having alkalinity to acidic contaminated water containing sulfur oxides, and purifying it by putting it in a centrifuge. Then, it is introduced into a centrifuge to separate contaminated water from fresh water and sludge, and the fresh water is discharged to the water management system 240, and the sludge is discharged to the sludge drying apparatus 100.

The water management system 240 manages fresh water supplied to the scrubber 220. At this time, the water management system 240 may be supplied with sea water along with fresh water, and manages states of turbidity, UV absorbance, temperature, and salinity with respect to the supplied water.

Therefore, the sludge discharged from the water treatment apparatus 200 as described above is supplied to the sludge drying apparatus 100 according to the present embodiment. The sludge drying apparatus 100 includes a buffer pump (110), a vacuum chamber (120), a cold trap (cold trap, 130), a condensate tank (condensate water tank, 140), a water pump (water) pump, 150), a vacuum pump (vacuum pump, 160) and a blower (blower, 170).

The buffer tank 110 is a tank for temporarily receiving sludge discharged from the water treatment system 230 of the ship and temporarily receiving it. The buffer tank 110 may temporarily receive and store sludge when the sludge is not received in the vacuum chamber 120 (eg, when the capacity of the vacuum chamber 120 is exceeded). In this case, the buffer tank 110 may temporarily store and store sludge when the first control valve CV1 is blocked to maintain the degree of vacuum during vacuum drying in the vacuum chamber 120. At this time, the first control valve (CV1) may be blocked to maintain the vacuum degree of the vacuum chamber 120, as described above, and also, about 80% or more sludge inside compared to the capacity of the vacuum chamber 120 When it is filled in the vacuum chamber 120 may be blocked.

In this embodiment, an on-off valve OV may be disposed between the buffer tank 110 and the water treatment system 230. The on-off valve OV can block the sludge discharged from the water treatment system 230 from being supplied to the buffer tank 110. The opening / closing valve OV can prevent the sludge temporarily stored in the buffer tank 110 from being filled more than a predetermined amount. In addition, when an abnormality occurs in the water treatment device 200 and the sludge is not normally operated in the water treatment system 230, the on-off valve OV may be blocked.

In addition, if necessary, when the sludge containing sulfur oxides is discharged between the opening / closing valve OV and the water treatment system 230, a neutralization device for neutralizing by adding sodium hydroxide may be additionally included. Here, the acidity sensor, such as a pH meter for measuring the acidity of the sludge discharged from the water treatment system 230 may be further included. Accordingly, the neutralization apparatus can control the amount of sodium hydroxide added according to the acidity measured by the acidity sensor.

The vacuum chamber 120 is provided to vacuum dry the sludge discharged through the water treatment system 230 to reduce the volume of the sludge. The vacuum chamber 120 may be controlled such that the internal vacuum degree is 3 torr or more. Thus, when the vacuum is made until the internal vacuum degree of the vacuum chamber 120 is 3 torr or more, drying of the sludge may be completed. As the degree of vacuum of the vacuum chamber 120 rises, the boiling point of water decreases, and accordingly, moisture is vaporized in the vacuum chamber 120 to dry the sludge.

The sludge dried in the vacuum chamber 120 may be discharged to the outside through a separate outlet. At this time, the dried sludge to be discharged may contain sulfur oxides, and moisture may be removed to minimize weight. In this embodiment, the dried sludge discharged from the vacuum chamber 120 may have a weight of about 10% compared to the sludge containing moisture. And the dried sludge to be discharged can be treated externally by pressing.

Here, in some cases, it is necessary to apply heat directly to the vacuum chamber 120 in order to increase the drying speed of the sludge in the vacuum chamber 120 and prevent the sludge from freezing. To this end, the vacuum chamber 120 may include a heater 126.

In addition, the vacuum gauge 122 may be connected to check the vacuum degree of the vacuum chamber 120. At this time, in this embodiment, the vacuum gauge 122 may be a pyrani gauge. In addition, a temperature sensor 124 for measuring the internal temperature of the vacuum chamber 120 may be installed.

As described above, the front end of the vacuum chamber 120 is to prevent the sludge in the vacuum chamber 120 from being over a certain level (for example, the amount of sludge compared to the receiving space of the vacuum chamber 120 is about 80% or more). The first control valve CV1 may be installed.

In addition, when the internal vacuum degree of the vacuum chamber 120 is 3 torr or more, a second control valve CV2 may be installed at a rear end of the vacuum chamber 120 so that the vacuum degree does not increase. That is, when the internal vacuum state of the vacuum chamber 120 is stabilized, the second control valve CV2 may be blocked for a period of time to stabilize the internal vacuum state of the vacuum chamber 120. In addition, the second control valve CV2 may control the vacuum speed of the vacuum chamber 120, and opening and closing may be controlled such that the vacuum degree of the vacuum chamber 120 is increased for each step. In this way, the degree of vacuum of the second control valve CV2 is increased step by step to prevent the inside of the vacuum chamber 120 from freezing.

At this time, as the vacuum pump 160 is operated to vacuum the vacuum chamber 120, the gas discharged from the vacuum chamber 120 through the second control valve CV2 may include moisture vaporized while the sludge is dried. have. Here, the vaporized moisture may not contain sulfur oxides as the sludge is vaporized in a vacuum.

The cold trap 130 is provided to separate the gas discharged from the vacuum chamber 120 from moisture and dried gas in a low temperature environment (eg, -20 ° C to ?? 40 ° C). The cold trap 130 may include a refrigerant to separate the gas discharged from the vacuum chamber 120 from moisture and dried gas in a low temperature environment. As the refrigerant, HCFC (hydro chloro fluro carbon) can be used.

After being separated from the cold trap 130 into moisture and dried gas, the filtered moisture may be condensed and stored in the condensate tank 140. The condensate tank 140 stores condensate separated from the cold trap 130, and condensate stored in the condensate tank 140 may be supplied to the water treatment system 230 by the water pump 150.

Here, a third control valve CV3 may be provided between the cold trap 130 and the condensate tank 140, and the third control valve CV3 is discharged from the cold trap 130 to the condensate tank 140. The flow rate of condensate can be controlled, and condensate is discharged to the condensate tank 140. That is, while the sludge drying apparatus 100 according to the present embodiment is operating, the third control valve CV3 is opened when the moisture is discharged from the cold trap 130, and the third control valve when the moisture is not discharged (CV3) can be closed.

In addition, a fourth control valve CV4 may be installed between the condensate tank 140 and the water pump 150. The fourth control valve CV4 may control the flow rate of the condensate discharged to the water treatment system 230 through the water pump 150, and may block the discharge of condensate discharged to the water treatment system 230.

In addition, a first check valve CHV1 may be disposed at a rear end of the water pump 150 to prevent the condensate from flowing back to the water pump 150. At this time, the condensate discharged through the water pump 150 may be supplied to a path discharged from the scrubber 220 to the water treatment system 230.

The dried gas discharged from the cold trap 130 is separated from moisture as described above, and the dried gas may be discharged through the vacuum pump 160. That is, the vacuum pump 160 may operate to suck the gas in the vacuum chamber 120 through the cold trap 130 so that the inside of the vacuum chamber 120 becomes vacuum. In addition, the vacuum pump 160 may not operate while the inside of the vacuum chamber 120 reaches a preset vacuum state or the inside vacuum state of the vacuum chamber 120 is stabilized.

At this time, when water is introduced into the vacuum pump 160, a problem may occur in the vacuum chamber 120, so that only the dried gas is introduced through the cold trap 130.

The inverter 162 is connected to the vacuum pump 160, and controls the vacuum pump 160. The inverter 162 may control the rotational speed of the motor included in the vacuum pump 160.

The blower 170 is disposed at the rear end of the vacuum pump 160 and may transfer the dried gas discharged from the vacuum pump 160 to the scrubber 220 side. At this time, the blower 170 may forcibly transfer the dried gas from the vacuum pump 160 to the scrubber 220 side. In addition, a second check valve CHV2 may be installed between the blower 170 and the scrubber 220 to prevent gas from flowing backward. At this time, the dried gas transferred from the blower 170 to the scrubber 220 may be transferred with a clean gas containing no sulfur oxides.

As described above, in the vacuum chamber 120, the moisture contained in the sludge is vaporized by vacuum, and at this time, as the vaporized gas is vaporized, sulfur oxide or fine particles may not be included. Then, the moisture contained in the gas is condensed and supplied to the water treatment system 230 through the cold trap 130, and the dried gas is supplied to the scrubber 220, so that unpolluted moisture and dried gas are treated by the water treatment device 200. ). Therefore, it is possible to prevent circulating contaminated water or contaminated gas from the water treatment device 200, thereby preventing secondary environmental pollution.

In addition, in the vacuum chamber 120, the sludge containing sulfur oxides or fine particles is discharged separately, and the weight of the sludge can be significantly reduced compared to the conventional method as moisture is removed from the discharged sludge. Accordingly, the process for the disposal of sludge can be reduced afterwards, and it can be more conveniently transported during transport for the disposal of sludge.

2 is an exemplary view showing a sludge drying apparatus for a scrubber for exhaust gas treatment of a ship according to an embodiment of the present invention.

The sludge drying apparatus 100 according to this embodiment may be installed as illustrated in FIG. 2.

Referring to FIG. 2, a buffer tank 110 may be installed on an upper portion of the vacuum chamber 120. In addition, a vacuum pump 160 and a condensate tank 140 may be disposed on one side of the vacuum chamber 120. A cold trap 130 may be installed on the top of the condensate tank 140. In addition, the vacuum chamber 120 and the cold trap 130 may be connected to the first pipe P1, and the cold trap 130 and the vacuum pump 160 may be connected to the second pipe P2.

At this time, the gas containing moisture may be transferred from the vacuum chamber 120 to the cold trap 130 through the first pipe P1. In addition, the gas dried through the second pipe P2 may be transferred from the cold trap 130 to the vacuum pump 160.

The moisture separated from the gas dried in the cold trap 130 may be stored in the condensate tank 140 disposed at the bottom.

In addition, as shown, the sludge drying apparatus 100 may further include a control panel 180 on one side. The control panel 180 may display information on the internal vacuum degree and the internal temperature of the vacuum chamber 120 through the vacuum gauge 122 and the temperature sensor 124 described above, and based on this, the sludge drying device 100 ). Therefore, the control panel 180 can control the operation of the first and second check valves CHV1 and CHV2, the first to fourth control valves CV1 to CV4, and the on-off valve OV, and also, the water pump. The operation of the 150 and the vacuum pump 160 can be controlled.

And if necessary, a pressure gauge may be installed in the sludge drying apparatus 100. The pressure gauge can be used to confirm the airtightness between the bulbs, with the sludge drying device 100 installed. The information on the airtightness measured by the pressure gauge may be displayed on the control panel 180.

As described above, the detailed description of the present invention has been made by the embodiments with reference to the accompanying drawings, but the above-described embodiments are merely described as preferred examples of the present invention, and the present invention is limited to the above-described embodiments only. It should not be understood, and the scope of the present invention should be understood as the claims and the equivalent concept described below.

100: sludge drying device
110: buffer tank 120: vacuum chamber
122: vacuum gauge 124: temperature sensor
126: heater
130: cold trap 140: condensate tank
150: water pump
160: vacuum pump 162: inverter
170: blower 180: control panel
CHV1 to CHV2: first and second check valves
CV1 to CV4: first to fourth control valves
OV: open / close valve
200: water treatment unit 210: engine
220: scrubber 230: water treatment system
240: water management system

Claims (1)

Sludge containing sulfur oxides discharged from a water treatment system is introduced to treat sludge contained in contaminated water discharged from a scrubber for treating exhaust gas of a ship. A vacuum chamber for vacuuming sludge;
A vacuum pump that discharges gas from inside the vacuum chamber;
It is disposed between the vacuum chamber and the vacuum pump, and includes a cold trim for separating moisture and dried gas from the gas discharged from the vacuum chamber,
The vacuum chamber is a sludge drying apparatus for a scrubber for exhaust gas treatment of a ship that vacuum-treats the sludge introduced therein to separate gas and sludge containing moisture, and discharge the dried sludge separated from moisture to the outside.

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