KR101489273B1 - Reduction System for Odor Caused by Deposit in Sewer Pipe - Google Patents

Abstract

Disclosed is an odor reduction system capable of controlling a sewage flow. The odor reduction system comprises: a chamber structure having a flow path connected to a culvert buried underground such that a sewage flowing into the path can flow, an inlet into which the sewage flows and an outlet of which the sewage flows out, and a manhole allowing a manhole cover to be connected to the top of the chamber structure; a pair of floodgates disposed to face each other so as to pivot on first and second sluice pivot axes installed in a vertical direction spaced apart from each other in the chamber structure; a sluice driving unit which drives the first sluice pivot axis to pivot; and a sluice motor driving unit having a gear train which transmits a pivoting force of the first sluice pivot axis to the second sluice pivot axis. The gear train comprises first and second pinions which are connected to the first and second sluice pivot axes respectively and a plurality of gear wheels which are connected to each other between the first and second pinions. According to the present invention, the odor reduction system for controlling the sewage flow prevents a deposition from being piled in sewer pipe by selectively charging and discharging water, thereby fundamentally controlling odor substances generated from the deposition.

Description

TECHNICAL FIELD [0001] The present invention relates to a reduction system for odor reduction by sewage flow control,

More particularly, the present invention relates to a system for temporarily collecting wastewater flowing into a sewer line and washing sediments accumulated on the bottom of a sewer line by an unsteady flow generated when the collected wastewater is rapidly discharged The present invention relates to a malodor reduction system by sewage flow control for reducing the odor generated by sediment.

The use of the disposer increases the amount of food waste directly fed into the sewer line and the amount of sediment in the sewer line is increasing due to the leakage of manure such as manure due to improper function of the septic tank. Increased sediments in the sewer line not only impede the smooth flow of sewage but also generate various kinds of odor causing substances in the anaerobic state, which is recognized as a main cause of complaints.

In order to remove sediments in the sewer line, which is one of the causes of such a bad odor, conventionally, a pigging technique in which pigs are driven by air pressure in a pipeline, a jetting technique in which sediments are washed away using piping using high pressure water, A scraping power bucket technique was used. However, these techniques are one of the methods to treat the sediments once after the sediment has been formed in the sewer line. In addition to not being able to remove sediment early or in real time, there is a limitation in controlling the odor generated within a few hours after accumulation of sediments .

In order to effectively clean the sewer line before the sediment accumulates, there is a method of installing the gate (water gate) in the sewer line to confine the sewage in the sewer line to secure the water quantity and then opening the gate (gate) at once to float and move the sediment. This method of gate opening and closing treatment of sediments is generally accompanied by the weight secured by the gate and the weight is added to the buoyant body so that the gate can be opened and closed by itself.

However, proper operation of the gate is not guaranteed when the element supporting the operation of the gate, the buoyant body, the weight or the like is contaminated or adhered or adhered, and it is desired to secure the quantity for effective cleaning depending on the situation in the sewer pipe There is a problem that the function can not be maintained properly.

Accordingly, it is an object of the present invention to provide a malodor reduction system by sewage flow control that is capable of originally controlling odor-causing substances generated by sediments by preventing accumulation of sediments in a sewer line by selective collecting and discharging.

An object of the present invention is to provide a malodor reduction system by sewage flow control, wherein a flow path is formed so that sewage flowing in the water channel can flow by being connected to a water channel buried underground, A chamber structure in which a manhole is formed so that a manhole cover is coupled to an upper portion of the chamber structure, and a first and a second hydrologic pivot shafts provided in a vertical direction spaced apart from each other in the chamber structure, A pair of openable and closable hydrants for interrupting and allowing the flow of the sewage, a hydraulically operated portion for rotationally driving the first hydratea pivoting shaft and a gear for transmitting rotation force of the first hydratea pivot shaft to the second hydratea pivot shaft Wherein the gear train comprises first and second pinions respectively coupled to the first and second hydrodynamic rotary shafts, Odor reduction is achieved by the system according to the sewage flow control, it characterized in that having a second plurality of cross-coupled between the pinion gear wheel.

Wherein the pair of gates are in contact with the rear surface of the free end region where the pair of gates are in contact with each other while blocking the flow of the sewage to resist the opening force of the gates due to water pressure, The apparatus further comprises a hydrographic support member pivotally supporting the support member between the contact support position and the release position and a hydrographic support member driving unit for rotating the hydrographic support member pivot shaft.

The hydrator driving unit may include a hydraulically driving motor having a driving shaft, a driving bevel gear provided at the free end of the driving shaft to transmit power between the driving shaft and the first hydromorning unit, And a driven bevel gear engaged with the driven bevel gear.

The hydrator driving unit may include a drive bevel gear installed at a free end of the drive shaft and a pair of bevel gears coupled to ends of the hydrologic pivot shaft to engage with the driven bevel gear.

And the hydraulically-operated member driving unit has a first electric clutch that is provided in the drive shaft and selectively restricts transmission of power, and the hydraulically -supporting member driving unit is capable of transmitting power between the drive shaft of the hydraulically- And a second electric clutch interposed between the chain transmission portion and the pivotal support member pivot for selectively interrupting transmission of power, wherein the chain transmission portion is connected to the drive shaft of the hydraulically- A driven sprocket connected to the driven sprocket and rotated, and a chain connecting the driven sprocket and the driven sprocket.

A water level sensor for sensing the level of the sewage contained in the chamber structure by interception of the water gates; and a water level sensor for detecting the water level of the water contained in the chamber structure, It is further preferable to further include a control unit for controlling the electric clutch.

It is preferable that the hydrologic drive motor is located in at least one of the inside and the outside of the chamber structure.

According to the present invention, there is provided a malodor reduction system by sewage flow control capable of originally controlling odor-causing substances generated by sediments by preventing accumulation of sediments in a sewer line by selective collecting and discharging.

1 is a sectional view of a malodor reduction system by sewage flow control according to the present invention,
Fig. 2 is a partial cross-sectional view showing the operating structure of the water can,
3 is a cross-sectional view showing another position of the hydrometric drive motor,
Figs. 4 (a) and 4 (b) are perspective views each showing a closed and open state of the watercourse,
FIG. 5 is a partial cross-sectional view showing a hydrologic operation structure of another embodiment according to the present invention,
6 (a) and 6 (b) are side cross-sectional views respectively showing the hydrant closing and opening states of another embodiment.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of a malodor reduction system by sewage flow control according to the present invention will be described with reference to the drawings.

1 is a cross-sectional view of a malodor reduction system by sewage flow control according to the present invention. 1, a malodor reduction system by sewage flow control includes a chamber structure 110 and first and second sluices 113 and 115 selectively interrupting the flow of sewage in the chamber structure 110. [ And a water gate drive motor 117 which rotates the first and second water gates 113 and 115 to open and close.

The chamber structure 110 is a generally rectangular parallelepiped concrete structure having an inlet 119 formed to be connected to an inflow channel 10 in which sewage is introduced by being buried in the basement and the inflow sewage is passed through the chamber structure 110 And an outlet 121 is formed so as to be connected to the effluent flow path 20 that flows out. The inlet 119 is located above the outlet 121 for smooth flow of sewage. A flow path 123 is formed at the bottom of the chamber structure 110 so that the sewage flowing into the inlet 119 flows to the outlet 121. The chamber structure 110 may be made of steel, plastic, stainless steel, or the like in addition to concrete. A manhole 125 is formed at an upper portion of the chamber structure 110 so that a worker can enter and exit the manhole 125. The manhole 125 is covered with a manhole cover 127 to prevent contaminants on the road from entering the chamber structure 110 prevent.

Fig. 2 is a sectional view showing the operation structure of the watercraft. Fig. 2, first and second water gates 113 and 115 are installed in the flow path 123 at the bottom of the chamber structure 110 in the vertical direction, and the upper and lower portions of the water gates 113 and 115 And a water gate drive motor 117 for opening and closing the water gate doors 113 and 115 is provided.

The first and second water gates 113 and 115 are disposed to face each other in a shape corresponding to the inner wall surface of the chamber structure 110 having a rectangular cross section. The first and second water gates 113 and 115 may be formed in various shapes such as a circle, a semicircle, and a polygon according to the inner cross-sectional shape of the chamber structure 110. The first and second hydrants 113 and 115 are provided with first and second hydrologic pivot shafts 129 and 131 at positions adjacent to the inner wall surface of the chamber structure 110.

The first and second hydrologic pivoting shafts 129 and 131 protrude upward from the first and second hydrants 113 and 115 and are disposed between the first and second hydrants 113 and 115 and the hydrants driving motor 117 And is received and supported in the pivot support portion 133 interposed therebetween. The first and second pivot shafts 135 and 137 are formed in the lower portion of the pivot support 133 to receive the first and second pivot shafts 129 and 131. A third rotation shaft opening 139 is formed in an upper portion of the first coaxial opening 135 in the vertical direction so that the first water gate rotary shaft 129 passes through the first water gate rotary shaft 129. The first and second water gate rotary shafts 129, Is supported by the radial bearing in the pivot support portion 133. [

The pivot support 133 is provided to prevent the sewage in the chamber structure 110 from flowing backward when the first and second sluices 113 and 115 are fixedly closed due to the non-operation of the first and second sluices 113 and 113 , 115). The sewage in the chamber structure 110 can flow into the space between the rotation shaft support 133 and the first and second water gates 113 and 115 even if the first and second water gates 113 and 115 are closed and closed, The sewage in the structure 110 is prevented from flowing backward.

The upper end of the rotating shaft support portion 133 is provided with a plate-shaped hydrological lid 141 covering the upper space between the first and second hydrants 113 and 115 and the outlet 121, Is installed. 2, the hydrologic drive motor 117 may be installed in the chamber structure 110 and may be installed outside the chamber structure 110, not inside the chamber structure 110, A separate chamber structure may be provided.

The water gate drive motor 117 has a drive shaft 143. A drive bevel gear 145 that rotates in accordance with the rotation of the drive shaft 143 is mounted on the free end of the hydrologic drive motor 117. A driven bevel gear 145 is mounted on the first hydrological drive shaft 129, And a bevel gear 147 is mounted. In the illustrated embodiment, the connection between the hydrographic driving motor 117 and the first hydrograph pivot 129 is shown as a connection using a bevel gear, but it may be connected by various means such as a chain, a belt or the like.

The first hydrometric rotary shaft 129 accommodated in the rotary shaft support portion 133 rotates in accordance with the rotation of the driven bevel gear 147. At this time, the first and second hydrologic pivoting shafts 129 and 131 are connected to each other by a pair of spur gears so that the first hydrological pivoting shaft 129 and the second hydrologic pivoting shaft 131 are opposed and rotated at the same time. As shown in FIGS. 3 and 4, the first and second hydrodynamic rotary shafts 129 and 131 are coupled with first and second pinions 149 and 151, respectively, and pinions 149 and 151, The first and second gear wheels 153 and 155 that are in contact with the rotation shaft support portion 133 are mounted on the rotation shaft support portion 133. More than two first and second gear wheels 153 and 155 may be added to the first and second gear wheels 153 and 155 according to the sizes of the first and second water gates 113 and 115, respectively. When the first hydrant rotation shaft 129 connected to the hydrological drive motor 117 is rotated, the first hydraulically operated rotary shaft 129 rotates and the first hydraulically operated rotary shaft 129 rotates, 1 gear wheel 153 rotates in a direction opposite to the rotating direction of the first pinion 149. [ The first gear wheel 153 is connected to the second gear wheel 155 so as to rotate the second gear wheel 155 in the direction opposite to the direction of the first gear wheel 153. The second gear wheel 155 is engaged with the second pinion 151 coupled to the second hydrodynamic rotary shaft 131 and the second pinion 151 is rotated in the direction opposite to the second gear wheel 155 As a result, the first and second hydrologic pivoting shafts 129 and 131 are rotated to face each other.

Fig. 4 is a perspective view briefly showing an operating state of the watercraft. Fig. 3 and 4, there is shown a schematic view of the structure of the sewage treatment system in which sediment is piled up in the effluent channel 20 and is disposed in the inflow channel 10 located upstream of the first and second sluices 113 and 115 in the chamber structure 110, The first and second water gates 113 and 115 are closed as shown in Fig. 4 (a). At this time, due to the closed first and second gates 113 and 115, the amount of sewage in the inflow passage 10 located upstream of the first and second gates 113 and 115 increases. The water level sensor 157 is provided in the chamber structure 110 and the signal of the water level sensor 157 is transmitted to the control unit 159 in the water level driving motor 117 when the water level in the chamber structure 110 reaches a certain water level do. The control unit 159 receiving the signal of the water level sensor 157 determines that the operation of the water level driving motor 117 is necessary and operates the water level driving motor 117. The operation of the hydrologic drive motor 117 rotates the first hydrologic pivot shaft 129 connected to the hydrologic drive motor 117. The spiral gears rotate by the rotation of the first hydrological pivot shaft 129 and are connected to the first and second hydrologic pivot shafts 129 and 131 by the rotation of the second hydrological pivot shaft 131, The water gates 113 and 115 are mutually opposed and simultaneously rotated.

The inner wall surface of the chamber structure 110 and the first and second water gates 113 and 115 reduce damage due to friction between the first and second water gates 113 and 115 while the first and second water gates 113 and 115 are rotated, In order to prevent leakage of sewage from the two gates 113 and 115 and to prevent foreign matter contained in sewage from adhering to the inner wall surface of the chamber structure 110 and the first and second gates 113 and 115, And the elastic members are joined to the edge regions of the first and second water gates (113, 115). The elastic members may be coupled to the edge regions of the first and second water gates 113 and 115 on the bottom surface of the first and second water gates 113 and 115 and the chamber structure 110, The elastic members convex as much as the widths of the first and second sluices 113 and 115 are fixed to the bottom surface of the chamber structure 110 in the direction opposite to the direction in which the first and second sluices 113 and 115 are opened, 115 of the first and second water gates 113, 115 are in close contact with the elastic members in the transverse direction of the first and second water gates 113, 115 to prevent leakage of sewage stored upstream of the first and second water gates 113, You may. The elastic member may be made of silicone, sponge, latex or various other elastic materials. The inner wall surface of the chamber structure 110 may be provided with a metal or plastic lining to reduce friction with the elastic member.

By opening the first and second water gates 113 and 115, the sewage temporarily stored in the chamber structure 110 is simultaneously discharged, and the sediment in the effluent passage 20 is washed out due to the increased flow rate. In this way, the first and second water gates 113 and 115 can be opened or closed continuously or periodically to float and move sediments to fundamentally control the odor generated by the sediments. The water level of the water gates 113 and 115 is lowered and the water level sensor in the chamber structure 110 reaches a predetermined water level when the water gates 113 and 115 are closed, The control unit 159 reversely rotates the water gate drive motor 117 to close the first and second water gates 113 and 115 that have been opened. The present invention can effectively remove the sediments in the effluent channel 20 by opening and closing the first and second water gates 113 and 115 when the river is in a clear stream or during rainfall. The control unit 159 connected to the water level sensor 157 at the time of rainfall may be separately or centrally controlled so as to minimize flooding and submersion in the downstream area of the effluent channel 20, , 115) can be controlled so that the sewage can be stored in the upstream sewer line of the first and second sluices 113, 115 or the sewage draining time (the time the sewage flows through the chamber structure) can be delayed Do.

5 is a view showing the hydrologic operation structure of another embodiment according to the present invention. 5, the structure adopting the chamber structure 210 and the first and second sidewalls 213 and 215 is the same as that of the embodiment of FIG. 1, but the supporting structure of the first and second sidewalls 213 and 215 There is a difference in the rotation method. First and second pivot openings 235 and 237 are formed in the lower end of the pivot support 233 to receive the first and second pivot joints 229 and 231. The first and second hydrologic pivoting shafts 229 and 231 penetrate the pivot shaft support portion 233 in the vertical direction above the first and second pivot shafts 235 and 237, 239, and 240 are formed, and a radial bearing is interposed therebetween. A drive sprocket 249 rotatable together with the rotation of the drive shaft 243 is provided between the drive bevel gear 245 and the water gate drive motor 217 and is connected to a driven sprocket 251 to be described later. A first electric clutch 253 is provided between the drive sprocket 249 and the drive bevel gear 245 for controlling the transmission of the rotational force of the drive shaft 243 to the drive bevel gear 245 and is connected to the control unit 259 have. The first electric clutch 253 is installed on the pair of drive shafts 243 and is rotated by the rotational force of the water gate drive motor 217 so that the first and second water gate pivot shafts 229 and 231 are simultaneously rotated in mutually opposing directions . One of the hydrological drive motors 217 may be connected to one of the first and second hydrologic pivot shafts 229 and 231 and may be connected to the first and second hydrologic pivot shafts 229 and 231 respectively . When one hydromotor drive motor 217 is connected to one hydromotor pivot, the pair of hydrologic pivot axes are connected to one another and the chain is twisted to intersect. Therefore, even if one hydromotor rotation shaft is connected to the hydrometric drive motor 217, the first and second hydrometric joints 213 and 215 combined with a pair of hydrologic operation shafts can be simultaneously rotated and opened and closed.

In order to prevent the first and second water gates 213 and 215 from being opened by the water pressure in a state where the first and second water gates 213 and 215 block the flow of the sewage, The hydrologic support portion 260 is provided. The hydro-support member 260 has a hydro-support member pivot shaft 263 coupled to the pivot shaft support 233 and a hydro-support member 261 coupled to the hydro-support member pivot shaft 263. The hydrographic support member 261 has a support bar 267 connected transversely to the longitudinal direction of the rotary car 265 and the rotary car 265 so that the first and second hydrogels 213, Thereby preventing it from being opened.

Both ends of the hydrogel supporting member rotating shaft 263 are rotatably coupled to the rotating shaft supporting portion 233. The hydrographic support member pivot shaft 263 is provided with a hydrographic support member drive unit for rotating and driving the hydrographic support member pivot shaft 263. The hydrographic support member drive unit has a chain drive unit and a second electric clutch 271 interposed between the chain drive unit and the hydrographic support member pivot shaft 263 to selectively block power transmission. The chain transmission section has a driven sprocket 251 connected to and rotated by a drive sprocket 249 mounted on the drive shaft 243 and a chain 269 connecting the drive sprocket 249 and the driven sprocket 251 to each other. The drive sprocket 249 and the driven sprocket 251 are connected to a chain 269 so that when the drive sprocket 249 rotates, the driven sprocket 251 rotates together, which leads to rotation of the hydrodynamic bearing member pivot shaft 263. In the illustrated embodiment, one drive sprocket 249 and the driven sprocket 251 are mounted on the drive shaft 243 and the hydrographic support member pivot shaft 263 connected to the second hydraulic pivot 231, The drive sprocket 249 and the driven sprocket 251 are additionally or alternatively mounted on the drive shaft 243 and the hydrodynamic bearing member pivot shaft 263 connected to the first hydrodynamic pivot shaft 229 in accordance with the rotation of the hydrodynamic bearing member pivot shaft 263 can be smoothly rotated. A second electric clutch 271 is provided between the driven sprocket 251 and the rotary rocking arm 265 for controlling the rotational force of the driven sprocket 251 to be transmitted by the rotational force of the hydrogel supporting member rotary shaft 263, .

A swivel arm 265 is coupled to the swivel support member pivot shaft 263 to rotate in accordance with the rotation of the swivel support member pivot shaft 263. The rotary rocking arm 265 extends laterally in the axial direction of the hydrogel supporting member pivot shaft 263. The position of the swivel arm 265 can be anywhere on the swivel support member pivot shaft 263 but preferably at a point where the first and second swim wards 213 and 215 contact when the swivel arm 265 is turned downward . Shaped support bar 267 formed at the end of the rotary rocking arm 265 in the longitudinal direction of the rotary rocking arm 265. The support bar 267 simultaneously supports the first and second water gates 213 and 215 to prevent the first and second water gates 213 and 215 from being opened by water pressure.

6 is a side cross-sectional view showing an operating state of the watercraft in another embodiment. 5 and 6, in order to prevent the first and second water gates 213 and 215 from being opened due to water pressure due to an increase in the number of sewage, the water gate support portion 260 is rotated downward, And supports the water gates 213 and 215.

First, the control unit 259 determines that the operation of the water gate drive motor 217 is necessary, and operates the water gate drive motor 217. The operation of the hydrologic drive motor 217 causes the drive sprocket 249 connected to the hydrologic drive motor 217 to rotate. The driven sprocket 251 is rotated by the rotation of the drive sprocket 249 to rotate the swing arm 265 connected to the swing support member pivot shaft 263 by the rotation of the swing support shaft 263. At this time, the control unit 259 controls the first electric clutch 253 so that the connection between the hydrologic drive motor 217 and the first and second hydrologic operation shafts 229 is cut off. The control unit 259 judges the operation time of the hydrologic drive motor 217 and judges that the swasharm 265 has been rotated upward enough to open the hydrological gate so that the second hydraulically operated clutch 271 of the hydrometric support unit 260 is driven The connection between the sprocket 251 and the hydrogel supporting member pivot shaft 263 is disconnected so that the pivot arm 265 is no longer rotated upward. The control unit 259 controls the first electric clutch 253 to connect the first and second hydrologic drive motors 217 and 229 and 231 to each other . The first and second hydrologic pivot shafts 229 and 231 connected to the hydrometric drive motor 217 are rotated in opposition to each other with respect to the vertical axis and opened as shown in Fig. 6 (b).

10: Inflow water 20: Effluent water
110, 210: chamber structure 113, 213: first gate
115, 215: second water gate 117, 217: water gate drive motor
119: inlet 121: outlet
123: Flow path 125: Manhole
127: Manhole cover 129, 229: First water gate rotary shaft
131, 231: second water gate pivot 133, 233: pivot shaft support
135, 235: first coaxial opening 137, 237: second coaxial opening
139, 239: Third coaxial opening 141: Hydr.
143, 243: drive shaft 145, 245: drive bevel gear
147, 247: driven bevel gear 148:
149: first pinion 151: second pinion 153: first gear wheel 155: second gear wheel 157: water level sensor 159, 259: control unit 249: drive sprocket 251:
253: first electric clutch 260: hydrological support part 261: hydrologic support member 263: hydrologic support member rotating shaft
265: Cone rock 267: Support bar
269: chain 271: second electric clutch

Claims (6)

In a malodor reduction system by sewage flow control,
A flow path is formed so that sewage flowing in the water channel can be connected to a water channel buried in the basement, an inlet through which the sewage flows and an outlet through which the sewage flows out are formed, and a manhole cover And a chamber structure
A pair of openable and closable hydrological gates that are disposed opposite to each other so as to be pivotable by first and second hydrologic pivot shafts provided in a vertical direction spaced apart from each other in the chamber structure,
A hydrator driving unit for rotationally driving the first hydrological pivot;
And a hydro-electric transducer having a gear train for transmitting the rotational force of the first hydro-pivot shaft to the second hydro-pivot shaft,
Wherein the gear train has first and second pinions respectively coupled to the first and second hydrologic pivot shafts and a plurality of gear wheels interconnected with each other between the first and second pinions. Odor reduction system. The method according to claim 1,
A hydrological support member which is in contact with the rear surface of the free end region where the pair of hydrants are in contact with the pair of hydrants in a state in which the flow of the sewer water is blocked and resists the opening force of the hydrants by water pressure; Further comprising a hydrographic support member having a hydrographic support member pivoting shaft for pivotally supporting the member between the contact support position and the release position and a hydrographic support member driver for rotationally driving the hydrographic support member pivotal shaft, Odor reduction system. 3. The method of claim 2,
The hydro-
A hydrologic drive motor having a drive shaft,
And a driven bevel gear which is connected to the drive shaft and the first hydrologic pivot shaft so as to transmit power and which is coupled to an end of the hydrologic pivot shaft and engaged with the driven bevel gear, Odor Reduction System by Sewage Flow Control Including Pairs. The method of claim 3,
The hydraulically-operated portion has a first electric clutch provided in the drive shaft to selectively restrict power transmission,
The hydrogel supporting member driving unit includes a chain driving unit for connecting the drive shaft of the hydromeathrow driving unit and the hydrogel supporting member rotating shaft to each other for power transmission and a power transmission unit interposed between the chain driving unit and the hydrogel supporting member pivot, And a second electric clutch selectively blocking transmission,
Wherein the chain transmission section includes a driven sprocket connected to the drive sprocket mounted on the driving shaft of the hydraulic motor and rotatable thereon and a chain connecting the drive sprocket and the driven sprocket. . 5. The method of claim 4,
A water level sensor for sensing a water level of sewage contained in the chamber structure by interception of the water gate,
Further comprising a control unit for controlling the hydraulically operated unit and the first and second electric clutches based on a water level detection signal from the water level sensor and a preset control value. The method according to claim 1,
Wherein the water gate drive motor is located at least one of the inside and the outside of the chamber structure.

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