KR20150131774A - Apparatus for optial solid-liquid spatation in use of high stregth organic wastewater disposal - Google Patents

Abstract

Disclosed is a solid-liquid separation device used in high density pre-treatment waste organic equipment such as livestock wastewater or the like by using a mesh type solid-liquid separation film and a vacuum pump. Slurry is positioned on the upper surface of the solid-liquid separation film. An inhalation plate is arranged on the lower surface of the solid-liquid separation film. An inhalation chamber and a diffusion chamber are positioned in the inhalation plate. The inhalation chamber and the diffusion chamber are connected by using a throat having a narrow cross section of a pipe line. The diffusion chamber is connected to an inhalation line, a vacuum tank, and the vacuum pump. When the vacuum tank is operated, vacuum pressure is formed in the vacuum tank, and a solid body is separated from the solid-liquid separation film by using the vacuum pressure. The solid-liquid separation device is provided to downwardly drop the solid-liquid separation film under the inhalation chamber when the slurry is positioned on the upper surface of the inhalation chamber, and rapidly escape filtrate with air from the throat, thereby easily separating the solid body from the solid-liquid separation film.

Description

TECHNICAL FIELD [0001] The present invention relates to a solid-liquid separation apparatus for a high concentration organic wastewater treatment plant,

More particularly, the present invention relates to a vacuum suction type solid-liquid separator using a solid-liquid separation membrane and a vacuum pump.

Recently, as the level of living has improved due to economic growth and the westernization of eating habits has led to an increase in the consumption of meat and livestock products, the increase in livestock manure increases the volume of livestock manure.

Currently, livestock wastewater is known to be less than 1.0% of total wastewater generated from the amount of generated wastewater. However, when the wastewater is discharged in an untreated state due to high pollutant load due to high concentration of organic matter, it causes environmental problems such as water pollution in the rivers. Therefore, the discharge allowance of livestock wastewater treatment is 30 mg / L for BOD (Biochemical oxygen demand), SS (Suspended solid), 50 mg / L for COD (chemical oxygen demand), 60 mg / nitogen) 8 mg / L or less. Therefore, it is difficult to manage livestock wastewater. In order to meet the standards, effective measures such as process selection and technology development are urgently needed.

In order to reduce the burden on the subsequent process and to stabilize the characteristics of the wastewater, the liquor wastewater is primarily purified by a solid-liquid separation (screen, centrifugation, centrifugation, etc.), which removes suspended substances, After the pretreatment process, it is subjected to advanced biological treatment such as biological primary treatment, biological secondary treatment such as activated sludge, and removal of nutrients such as nitrogen and phosphorus. Particularly, in the case of food or livestock wastewater, since it is a high concentration organic matter, if the solid-liquid separation can not be effectively performed in the pretreatment process, additional chemical treatment such as coagulant is required to meet the design concentration required in the post- The cost of the preprocessing equipment is increased because additional processes or devices are required, such as paralleling the apparatus. Therefore, it is preferable that the solid-liquid separation process, which is a pretreatment process of wastewater, is performed more effectively, thereby simplifying the subsequent process or equipment and minimizing the operation cost thereof.

Various methods such as gravitational force, centrifugal force or vibration, or a pressing method are known in connection with such a pretreatment process. However, when gravity is used, the treatment efficiency is lowered. When the centrifugal force is used, the mechanical device becomes large and complicated. In addition, the number of revolutions of the drum screen, , There is a problem in that the mechanical device becomes too large when the liquid is separated by solid-liquid separation by using a plurality of perforated plates or screens or when the liquid is separated by increasing the vibration.

Accordingly, a vacuum suction type solid-liquid separating apparatus, which can relatively simplify the mechanical apparatus and improve the processing capacity of the wastewater without requiring any additional apparatus such as a pressing roller or a drum screen, is disclosed in Korean Patent Application No. 10-1998-0014257 Lt; / RTI > Korean Patent Application No. 10-1998-0014257 discloses a solid-liquid separation method of livestock wastewater using a PVA (polyvinyl alcohol) sponge and a vacuum inhaler, and a method of controlling moisture content of livestock manure. However, since the solid-liquid separation membrane has a structure in which the sponge membrane is simply placed and vacuum suction is performed, the continuous process is difficult, the process time is long, and the processing capacity is low and inefficient. As a solution to this problem, Korean Patent Application No. 10-2001-0009922 discloses a continuous inhalation type dewatering system for industrial sludge in which solid-liquid separation from a wastewater is carried out by vacuum suction while continuously conveying a mesh-like solid-liquid separation membrane have.

However, in the case of a solid-liquid separator as disclosed in Korean Patent Application No. 10-2001-0009922, there is an advantage that a continuous suction type pre-treatment process in which a solid-liquid separation membrane is continuously transferred while using an infinite orbital can be performed, It has a structure in which wastewater is placed on the upper surface and is simply sucked into the vacuum line from the bottom of the solid-liquid separation membrane, so that the suction power is weak and the effectiveness is inferior. In order to solve this problem, it is necessary to use a vacuum pump having a large capacity but it is not preferable because it is limited in installation, operation and maintenance. If the mesh spacing of the solid-liquid separation membrane is increased, the effect of pretreatment for purification of wastewater can be reduced since a small-sized solid matter is not separated. Furthermore, when the mesh spacing of the solid-liquid separation membrane is made small, moisture is contained in the solid particles larger than the mesh spacing, making solid-liquid separation difficult. Therefore, for example, it is possible to separate a solid material by sequentially stacking a plurality of solid-liquid separation membranes such that a gap between meshes is 500 mu m in size with a first solid-liquid separation membrane and a gap between meshes is 250 mu m in size with a second solid- Or a plurality of conveyor systems and a solid-liquid separation membrane are continuously disposed to transfer the wastewater to separate the solid matter, which is inefficient because the facility becomes large or complicated. Furthermore, when the mesh pore size of the solid-liquid separation membrane is set to a value of less than 100 m, for example, the solids are included in the viscosity, so that it is difficult to separate the solids from the solid-liquid separation membrane.

DISCLOSURE Technical Problem The present invention has been devised to solve such problems, and it is an object of the present invention to provide a solid-liquid separator for a solid-liquid separation membrane, which can be easily made from wastewater by a vacuum suction method without any additional equipment such as a compression roller or a drum screen Liquid separating apparatus of a high concentration organic wastewater pretreatment facility for applying a small-sized solid-liquid separating membrane.

In order to solve the above problems, a solid-liquid separator according to the present invention comprises: a net-like solid-liquid separation membrane in which a slurry is positioned and a plurality of voids are formed; a suction chamber formed in an upper portion in contact with the solid-liquid separation membrane, A diffusion plate, and a throat which interconnects the suction chamber and the diffusion chamber and has a narrowed section of the channel, the suction plate being disposed on the bottom surface of the solid-liquid separation membrane; A suction line connected to the diffusion chamber of the suction plate; And a pump connected to the suction line to allow the slurry filtrate and air to be sucked into the suction line. The vacuum pump may include a vacuum tank connected to the suction line for separating and storing the filtrate and air, and a vacuum line for discharging air of the vacuum tank. The vacuum pump may include a vacuum pump connected to the vacuum line. have.

In the solid-liquid separator according to the present invention, when the vacuum tank is operated, vacuum pressure is formed in the vacuum tank. The solid-liquid separation membrane together with the slurry is squeezed under the suction chamber, and the filtrate is discharged at a high flow rate together with air at the throat Solids can be easily separated from the solid-liquid separation membrane.

1 is a configuration diagram of a solid-liquid separator as a preferred embodiment according to the present invention,
2 is a plan view of a suction plate as a preferred embodiment according to the present invention,
3 is a sectional view of a suction plate as a preferred embodiment according to the present invention,
4 is a configuration diagram of a solid-liquid separator as another embodiment according to the present invention.

Generally, a mixture of a solid and a liquid or a suspension in which fine solid particles are suspended in a liquid is collectively referred to as slurry. Industrial wastewater, animal manure, and the like fall under this category. Therefore, the term "slurry" The solid is separated from the slurry by the solid-liquid separator according to the present invention, and the liquid is referred to as "filtrate ".

Hereinafter, the solid-liquid separator according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a diagram showing the structure of a solid-liquid separator according to an embodiment of the present invention.

1, a solid-liquid separator according to an embodiment of the present invention includes a slurry receiving part 100 for receiving and storing a slurry from the outside, a slurry receiving part 100 for receiving slurry, A solid-liquid separator 120 separating the solids from the solid-liquid separator 120, a slurry injecting unit 110 for injecting the slurry into the slurry injecting unit 110, A suction plate 130 disposed at the bottom surface of the solid-liquid separation membrane 120 for sucking the liquid, a suction line 140 140 'connected to the suction plate 130, and a suction And a pump 150, 150 'connected to the suction line 140, 140' to draw fluid.

As a preferred embodiment of the present invention, it is preferable that the solid-liquid separator 1 is capable of sucking air and solids from the slurry of the solid-liquid separation membrane 120 with vacuum pressure. To this end, the pumps 150 and 150 'are configured as vacuum pumps, and the suction lines 140 and 140' are connected to the vacuum tanks 160 and 180, respectively. The filtrate and air are transferred to the vacuum tanks 160 and 180 through the suction lines 140 and 140 ', and the filtrate and air are temporarily stored in the vacuum tank 160 and 180, respectively. In addition, a vacuum line 170 is connected to the upper side of the vacuum tanks 160 and 180, and the vacuum line 170 is connected to the suction side of the vacuum pumps 150 and 150 '. Accordingly, when the vacuum pumps 150 and 150 'are operated, air is discharged from the vacuum tanks 160 and 180 so that vacuum pressure is formed inside the vacuum tanks 160 and 180. As a result, the vacuum liquid is discharged through the suction lines 140 and 140' The air and the filtrate can be sucked from the filter 120. In this case, the filtrate is collected in the vacuum tanks 160 and 180. When a large vacuum pressure is applied by the vacuum pumps 150 and 150 ', dissociation or relaxation of the volatile contaminants in the filtrate is accelerated to remove the volatile contaminants in the filtrate Can be achieved. Then, the filtrate is transferred to a post-treatment process such as a biological treatment through a discharge pipe 220 by a transfer pump 210.

In the solid-liquid separator according to an embodiment of the present invention, the solid-liquid separator may be installed outside the slurry injecting unit 110 to cover the upper and both ends of the solid-liquid separating membrane 120 to guide the sludge cake to the discharge position A cake guider 180, a plate-shaped scraper 182 for separating the cake adhering to the solid-liquid separation membrane 120 in the solid-liquid separation membrane 120, and a cleaning means. The cleaning means includes an air compressor 310 and a second injection nozzle 313 disposed adjacent to the solid-liquid separation membrane 120, a water tank 315, and a first injection nozzle 313 located in front of the second injection nozzle 313, And a nozzle 319.

1, the first injection nozzle 319 and the water tank 315 are connected to each other through a second water supply line 317b branched from the first water supply line 317a, And the air compressor 310 and the second injection nozzle 313 are connected to each other via an exhaust line 190. A first water supply line 317a is connected to the exhaust line 190. [ For example, water is sprayed into the solid-liquid separation membrane 120 through the first injection nozzle 319 to wet the solids remaining in the solid-liquid separation membrane 120, and the second injection nozzle 313 Water and air are discharged together and injected into the solid-liquid separation membrane 120 to remove the remaining solid matter.

The solid-liquid separation membrane 120 passes through the first injection nozzle 319 and the second injection nozzle 313 in a stepwise manner. First, the solid-liquid separation membrane 120 separates the first injection nozzle 319 The water sprayed through the first injection nozzle 319 is injected into the solid-liquid separation membrane 120, so that the solidified solid remaining in the solid-liquid separation membrane 120 is moistened with water and becomes like mud, In this state, when the solid-liquid separation membrane 120 passes through the second injection nozzle 313, water and air are simultaneously discharged from the second injection nozzle 313, so that the solid matter remaining in the solid-liquid separation membrane 120 is separated. Accordingly, even if solids remain in the solid-liquid separation membrane 120, it is possible to easily remove the solids. Particularly, when the solids are removed, the solids can not be scattered and the working environment can be greatly improved. So it is very useful.

In another embodiment, as shown in Fig. 4, the cleaning means of the foregoing embodiment can be modified so that the first injection nozzle 319 and the second water supply line 317b are removed. According to this, since it is not necessary to wet the solid matter remaining in the solid-liquid separation membrane 120 through the first injection nozzle 319 in advance, the use of water can be saved so much, and the structure can be simplified compared with the previous embodiment.

Here, the cleaning means is exemplarily shown and described as an example, but various means known in the belt cleaning field, for example, wash water may be used, and air and wash water may be used together as a cleaning means.

The solid-liquid separator according to the present invention is configured to be capable of continuous treatment of sludge. To this end, the solid-liquid separation membrane 120 has a belt-like shape as a whole, and constitutes an endless conveyor belt and is continuously conveyed in an endless track Drive. A slurry thickness regulating plate 113 is installed in the slurry injecting unit 110 in order to uniformly apply the slurry to the solid-liquid separating membrane 120. The lower portion of the slurry injecting portion 110 is opened to allow the solid-liquid separating membrane 120 and the suction plate 130 to be disposed therein. In the slurry injecting portion 110, A slurry guide plate 115 for guiding the slurry to be positioned above the separation membrane 120 is provided.

The roller conveying device includes a plurality of rollers for moving the solid-liquid separating film 120 to a predetermined conveying path. For example, the roller conveying device may include a driving roller 123 driven by a motor (not shown), a driven roller 125 rotated by receiving the power of the driving roller, a load cell (not shown) And a tension roller 129 for imparting a tension by being rotatably mounted by a tension roller 129A connected to a guide roller 127 and an encoder (not shown) having an encoder.

The solid-liquid separation membrane 120 may be made of various materials and shapes known in the art, such as a mesh having voids using a material such as iron, non-ferrous metal, plastic or fiber, (See FIG. 3) and a reinforcing strip 122 (see FIG. 3) attached to both sides of the metal net 121 between the metal net 121 and the metal net 121 so as to be able to act as a conveyor belt .

The metal mesh 121 is made up to 30 mu m or less in the current line (the distance between the line and the line closest to the line). Such a known metal mesh 121 may be used. The metal mesh 121 is exposed to the worn or highly corrosive wastewater in contact with the suction plate 130, so that it is preferable that the metal mesh 121 is a stainless steel metal having excellent corrosion resistance as well as abrasion resistance. The reinforcing strip 122 is integrally attached to both sides of the metal net 121 by reinforcing the strength of the metal net 121 and smoothly performing continuous conveyance by roller driving. Here, when the solid-liquid separating membrane 120 is made of a metal, particularly a stainless steel metal, the scraper 182 and other cleaning means are also advantageous in corrosion resistance and abrasion resistance.

2 is a cross-sectional view of the suction plate 130 as a preferred embodiment according to the present invention.

Referring to FIG. 2, the suction plate 130 is fixed to the fixed frame 5 adjacent to the bottom surface of the solid-liquid separation membrane 120. The suction plate 130 may be made of a variety of materials, but it is preferable that the suction plate 130 is made of a plastic material having a reduced contact resistance and less abrasion of the metal mesh 121. The suction plate 130 includes a suction chamber 133 provided at an upper portion thereof, a diffusion chamber 135 provided at a lower portion of the suction chamber 133, and a suction chamber 133 connected to the diffusion chamber 135 And a throat (137) to be used. Here, the suction plate 130 may be formed in various ways. For example, a groove may be formed on a plastic plate, a throat may be formed on the bottom of the plastic plate, a separate plastic hollow tube may be divided into two, And then adhered to the plastic plate on which the throat is formed or mutually fixed with a separate fixture.

The suction plate 130 is preferably in close contact with the solid-liquid separation membrane 120 and sucks the filtrate through the vacuum pumps 150 and 150 '. To this end, the upper surface of the suction plate 130 is convexly curved in the conveyance direction of the solid-liquid separation membrane 120.

The suction chamber 133 is formed in a groove shape on an upper portion of the suction plate 130 contacting with the solid-liquid separation membrane 120. Since the suction chamber 133 is formed in the shape of a groove, the metal mesh 121 of the solid-liquid separation membrane 120 is spread over the groove-shaped space. At this time, the metal mesh 121 together with the slurry is moved downward I'm stuck. At this time, in order to increase the adhesion of the metal mesh 121 at the upper end of the suction chamber 133, the upper end edge portion of the suction chamber 133 is appropriately selected according to the input amount of the slurry and the weight of the metal mesh used, It is preferable that it is formed of one curved surface.

3 is a plan view of the suction plate 130 as a preferred embodiment according to the present invention.

3, the suction chamber 133 may be formed to extend in the direction crossing the transport direction of the solid-liquid separation membrane 120, that is, toward the both side ends of the solid-liquid separation membrane 120, rather than being discontinuously formed over the entire surface And it is preferably formed in a long groove shape. Accordingly, the vacuum pressure by the vacuum pumps 150 and 150 'is not dispersed but concentrated in one suction chamber 133, thereby effectively separating the solids from the slurry. Furthermore, the solid-liquid separation of the slurry can be continuously performed by sequentially passing through the suction chamber 133 successively in accordance with the conveyance of the metal mesh 121.

In addition, it is preferable that a plurality of, preferably three, suction chambers 133 are arranged in parallel in the transport direction of the solid-liquid separation membrane 120. Accordingly, the slurry is intensively sucked in the first first suction chamber 133A, and additionally sucked in the second and third second suction chambers 133B and 133C to perform solid-liquid separation Can be performed more effectively. The suction lines 140 and 140 'and the vacuum tanks 160 and 180 connected to the first and second and third suction chambers 133A and 133B and the vacuum tanks 160 and 180 may be used in common. However, in the first suction chamber 133A, The first suction chamber 133A is constituted by a separate suction line 140 and a vacuum tank 160 separately from the second suction chamber 133B and the third suction chamber 133C so as to perform solid- .

3, the diffusion chamber 135 is located at a lower portion of the suction chamber 133 and includes a suction chamber 133 for diffusing the filtrate and air sucked from the suction chamber 133, A space portion having a semicircular cross-sectional shape with a larger volume is provided.

The throat 137 connects the suction chamber 133 and the diffusion chamber 135 so as to communicate with each other and has a structure in which the cross section of the channel is narrowed. Accordingly, when the vacuum pumps 150 and 150 'are operated, the air flow speed is increased in the throat 137 having the narrowed section of the channel between the suction chamber 133 and the diffusion chamber 135, The liquid can be quickly discharged to the diffusion chamber 135.

Hereinafter, the operation of the solid-liquid separator 1 will be described in detail as an embodiment of the present invention.

1 to 3, the roller conveying device is driven to drive the solid-liquid separator 120, and the vacuum pumps 150 and 150 'are driven to form vacuum pressure in the vacuum tanks 160 and 180, To the slurry injecting unit 110 from the slurry receiving unit 100. [ The slurry supplied from the slurry receiving portion 100 is regulated by a flow control valve V1 and flows into the slurry injecting portion 110 along the slurry guide plate 115. [ The sludge introduced along the slurry guide plate 115 is disposed on the solid-liquid separation membrane 120. When the slurry of thick slurry is thickly accumulated on the slurry guide plate 115, the slurry is thinly coated on the solid-liquid separation membrane 120 by the slurry thickness control plate 113, 130) is subjected to solid-liquid separation.

Since the suction plate 130 is curved (see FIG. 3) when the solid-liquid separator 120 runs and passes through the suction plate 130, the solid-liquid separator 120 and the suction plate 130 are in close contact with each other State is maintained. When the slurry is positioned above the suction chamber 133, the metal mesh 121 of the solid-liquid separation membrane 120 is formed as a thin mesh And is brought into a state of being close to the throat 137 due to the weight of the slurry, the weight of the slurry, and the vacuum pressure. Since the throat 137 has a reduced channel cross section, the flow velocity in the channel 137 is increased, so that the solids are separated from the slurry of the metal mesh 121 and the filtrate is rapidly transported. In addition, the solid-liquid separation membrane 120 continues to run. The same process as above is performed after passing through the first suction chamber 133A and the upper portion of the second suction chamber 133B and the third suction chamber 133C. The filtrate is transferred to the vacuum tanks 160 and 180 through the suction lines 140 and 140 'and the filtrate and the introduced air are separated from the vacuum tanks 160 and 180 and the air is continuously discharged by the vacuum pumps 150 and 150' And the filtrate is sent to the post-treatment process for the biological treatment or the like by the transfer pump 210. [

On the other hand, as the solid-liquid separating membrane 120 continues to travel after passing through the suction plate 130, the solids remaining on the solid-liquid separating membrane 120 form a sludge cake, which is guided by the cake guider 180 The solids are separated from the solid-liquid separation membrane 120 by the scraper 182 and are discharged to the outside through the discharge port 185.

That is, the slurry containing section 100 is moved to the slurry inlet 110 by passing through the cleaning means, that is, the second injection nozzle 313 as the solid-liquid separator 120 continues to travel. Liquid separation of the slurry flowing into the slurry injecting unit 110 is performed.

4 is a system configuration diagram showing a solid-liquid separator as another embodiment according to the present invention.

4, the solid-liquid separator 1 according to another embodiment of the present invention is the same as the solid-liquid separator 1 shown and described with reference to FIG. 1, but the air compressor 310 shown in FIG. Is connected to the air injection nozzle 313 through the exhaust line 190 of the vacuum pump 150 'so as to be sprayed. According to this configuration, since the conventional air compressor 310 is not required, the facility is simplified and advantageous from the viewpoint of energy efficiency.

Particularly, in the solid-liquid separation device 1 according to the present invention, as shown in Fig. 3, when a plurality of suction chambers 133 are arranged in parallel, solid-liquid separation is performed in the first suction chamber 133A The second suction chamber 133B and the third suction chamber 133C are connected to the second suction chamber 133B and the third suction chamber 133C because the solid-liquid separation is assisted by the second suction chamber 133B and the third suction chamber 133C, It is preferable that the exhaust line 190 of the vacuum pump 150 'and the air injection nozzle 313 are interconnected to perform a cleaning action by air pressure. As a result, the main function of the slurry solid-liquid separation can be exhibited in the first suction chamber 133A, the second suction chamber 133B and the third suction chamber 133C exert an auxiliary function of slurry solid-liquid separation At the same time, the exhausted air can be recycled as cleaning means, which contributes to simplification of the facility and energy efficiency, which is desirable.

Although the solid-liquid separator according to the present invention has been shown and described in detail in the foregoing, it will be apparent to those skilled in the art that various modifications and variations may be made without departing from the spirit and scope of the invention. The technical scope should not be construed as being limited to the illustrated and described embodiments and should be defined by the appended claims.

1: solid-liquid separator 5: fixed frame 100: slurry receiving part
110 Slurry injecting section 113 Slurry thickness regulating plate 115 Slurry guide plate
120: solid-liquid separation membrane 121: metal mesh 122: reinforcing strip
123: drive roller 125: driven roller 127: guide roller
129: tension roller 129A: tension arm 130: suction plate
133: suction chamber 135: diffusion chamber 137: throat
140.140 ': Suction line 150.150': Vacuum pump 160: Vacuum tank
170: Vacuum line 180: Vacuum tank 190: Exhaust line
210: transfer pump 220: discharge pipe 310: air compressor
313: second injection nozzle 315: water tank 317a: first water supply line
317b: second water supply line 319: second injection nozzle

Claims (6)

A mesh-type solid-liquid separation membrane having a plurality of pores formed at the upper part of the slurry:
A suction chamber in which a space is formed in a groove shape on an upper side in contact with the solid-liquid separation membrane, a diffusion chamber provided in a lower portion of the suction chamber, and a throttle which interconnects the suction chamber and the diffusion chamber and has a narrowed cross section, A suction plate disposed on a bottom surface of the casing;
A suction line connected to the diffusion chamber of the suction plate; And
And a pump connected to the suction line to allow the slurry filtrate and air to be sucked into the suction line.
The method according to claim 1,
A vacuum tank connected to the suction line for separating and storing the filtrate and air, and a vacuum line for discharging air from the vacuum tank;
Wherein the pump is a vacuum pump connected to the vacuum line.
3. The method according to claim 1 or 2,
The upper surface of the suction plate, which is in contact with the solid-liquid separation membrane,
Wherein the solid-liquid separator has a convexly curved surface as a whole in the conveyance direction of the solid-liquid separation membrane.
The method of claim 3,
The upper end of the suction chamber of the suction plate, which is in contact with the solid-liquid separation membrane,
Liquid separation device according to claim 1, wherein the solid-liquid separator has a smooth curved shape. The method of claim 3,
The suction chamber
Liquid separator is formed in a shape of an elongated shape extending in a direction intersecting the conveyance direction of the solid-liquid separation membrane.
6. The method of claim 5,
Wherein the suction chamber is arranged in a plurality of directions in the conveyance direction of the solid-liquid separation membrane.

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