CN212309850U - Ultrasonic wave pulsation magnetic separator - Google Patents

Abstract

The utility model discloses an ultrasonic wave pulsation magnet separator, include: the top of the grading cylinder is provided with a tailing outlet and a feeding port, the bottom of the grading cylinder is provided with a water inlet pipe and a concentrate outlet, the wall of the grading cylinder is uniformly and circumferentially inserted and fixed with a plurality of ultrasonic vibration rods, and the wall of the grading cylinder is wound with an electromagnetic coil; the vertical ore feeding pipe is arranged inside the grading cylinder, one end of the vertical ore feeding pipe is communicated with the ore feeding port, the other end of the vertical ore feeding pipe is a closed end and extends downwards, and a plurality of first rotational flow discharge ports are uniformly distributed on the outer wall, close to the closed end, of the vertical ore feeding pipe along the circumferential direction of the vertical ore feeding pipe; the vertical setting of material blocking column is in the inside bottom of a sorting section of thick bamboo, and its top is provided with the material chamber, and a plurality of second whirl discharge gates have been seted up along its circumference equipartition to material chamber outer wall, and the blind end of vertical feeding pipe passes and hinders the material capital end and extend to material intracavity portion. The equipment reduces water consumption, saves water resources and improves the magnetic separation effect.

Description

Ultrasonic wave pulsation magnetic separator

Technical Field

The utility model relates to a mineral sorting technical field, more specifically the ultrasonic wave pulsation magnet separator that says so relates to.

Background

Currently, the concentration of iron ore generally comprises the free flow of ore pulp in a grading cylinder and the separation of concentrate under the action of an electromagnetic coil. Because the ore pulp generally directly flows out of the ore feeding pipe and the outflow speed is high, in order to ensure the magnetic separation effect, water which is always introduced into the grading cylinder is also high-pressure water, so that the water consumption of the magnetic separation equipment is greatly increased, and the waste of water resources is caused; meanwhile, in the magnetic separation process, non-magnetic particles and magnetic particles are mixed and agglomerated, so that the magnetic separation effect is poor; in addition, the size of the coil magnetic field and the size of water quantity of the existing equipment need to be adjusted manually, and the automation degree is low.

Therefore, it is an urgent need to solve the problem of the art to provide an ultrasonic pulse magnetic separator with water saving, good magnetic separation effect and high automation degree.

SUMMERY OF THE UTILITY MODEL

In view of this, the utility model provides a can the water economy resource, the better just ultrasonic wave pulsation magnetic separator that degree of automation is higher of magnetic separation effect.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

an ultrasonic pulsed magnetic separator comprising:

the device comprises a grading cylinder, a water inlet pipe, a concentrate outlet, a tailing outlet, a plurality of ultrasonic vibration rods, a plurality of electromagnetic coils and a plurality of water outlet pipes, wherein the top of the grading cylinder is provided with the tailing outlet and the ore feeding port;

the vertical ore feeding pipe is arranged in the middle of the interior of the grading barrel, one end of the vertical ore feeding pipe is communicated with the ore feeding port, the other end of the vertical ore feeding pipe is a closed end and extends downwards, and a plurality of first rotational flow discharge ports are uniformly distributed on the outer wall, close to the closed end, of the vertical ore feeding pipe along the circumferential direction of the vertical ore feeding pipe;

the material blocking column is vertically arranged at the bottom inside the sorting cylinder and located under the other end of the vertical feeding pipe, a material cavity is formed in the top of the material blocking column, a plurality of second rotational flow discharge holes are uniformly distributed in the outer wall of the material cavity along the circumferential direction of the material cavity, and the closed end of the vertical feeding pipe penetrates through the top end of the material blocking column and extends to the inside of the material cavity.

According to the technical scheme, compared with the prior art, the utility model discloses an ultrasonic wave pulsation magnetic separator, the ore pulp enters into the ore feeding pipe through the ore feeding mouth through the high-pressure pump sending, and is certain whirl through first whirl discharge gate and flows out to the material intracavity, can make the ore pulp slow down, then flow out to the grading section of thick bamboo through second whirl discharge gate is certain whirl once more, the ore pulp slow down once more, the ore pulp speed that finally enters into the grading section of thick bamboo is lower, make the velocity of flow of water that lets in the grading section of thick bamboo also reduce thereupon, thereby reduced magnetic separation equipment's water consumption, the water resource has been practiced thrift; meanwhile, the arrangement of the first cyclone discharge port and the second cyclone discharge port enables ore pulp to flow out in a rotary direction, so that the ore pulp and water are mixed to form irregular turbulence, the ore pulp is separated, and the ore dressing effect is improved; and the ultrasonic wave generated by the ultrasonic vibration rod vibrates the ore pulp, so that the non-magnetic particles and the magnetic particles in the ore pulp can be kept in a loose state, the mechanical inclusion of the non-magnetic particles and the magnetic particles is effectively eliminated, and the magnetic separation effect is obviously improved.

Furthermore, a first inclined baffle is fixedly connected to the outer wall of the vertical ore feeding pipe at a position located at the first rotational flow discharge port, and an included angle a between the first inclined baffle and the vertical ore feeding pipe is 30-45 degrees.

The beneficial effect who adopts above-mentioned technical scheme to produce is, the setting of first slant baffle for give intraductal ore pulp of ore deposit when first whirl discharge gate flows, be the whirl form and flow, effectively reduced ore pulp outflow speed.

Furthermore, a second inclined baffle is fixedly connected to the outer wall of the material blocking column at the position of the second cyclone discharge port, and an included angle b between the second inclined baffle and the material blocking column is 30-45 degrees.

The beneficial effect who adopts above-mentioned technical scheme to produce is, the setting of second slant baffle for when the ore pulp of material intracavity flows through second whirl discharge gate, be the whirl form and flow out, can reduce ore pulp outflow speed once more.

Furthermore, the rotating directions of the first rotational flow discharge port and the second rotational flow discharge port are opposite.

The beneficial effect who adopts above-mentioned technical scheme to produce is that, when the ore pulp flows through second whirl discharge gate after first whirl discharge gate flows, because of the opposite of the rotation of the two for the speed greatly reduced after the ore pulp flows through second whirl discharge gate, thereby effectively reduced the outflow speed of ore pulp.

Furthermore, the first rotational flow discharge holes and the second rotational flow discharge holes are arranged in a staggered mode.

The beneficial effect that adopts above-mentioned technical scheme to produce is that, the ore pulp behind first whirl discharge gate runner material intracavity, the ore pulp at first strikes the chamber wall deceleration, then flows through second whirl discharge gate again, has improved the ore pulp deceleration effect.

Furthermore, a plurality of transverse supporting rods are uniformly and fixedly arranged on the material blocking column along the circumferential direction of the material blocking column, the transverse supporting rods are located below the second cyclone discharge port, and one end of each transverse supporting rod, which is far away from the material blocking column, is fixedly connected with the inner wall of the sorting cylinder.

Adopt above-mentioned technical scheme to produce the beneficial effect be for it is more firm to hinder the material post.

Furthermore, the bottom of the sorting cylinder is connected with a pulsating pipe, one end of the pulsating pipe is communicated with the inside of the sorting cylinder, and the other end of the pulsating pipe is provided with a tympanic membrane;

the pulsator is fixedly arranged on the outer cylinder wall of the sorting cylinder, and an output end of the pulsator is in reciprocating contact with the tympanic membrane.

The beneficial effect that adopts above-mentioned technical scheme to produce is that, when the pulsation machine promoted the tympanic membrane, the tympanic membrane promoted the ore pulp, made non-magnetic particle in the ore pulp and magnetic particle keep loose state to further effectual elimination non-magnetic particle and magnetic particle's mechanical inclusion has improved the magnetic separation effect greatly.

Further, the pulsator includes: support, motor, stroke case, the support fixed mounting be in select and do not expect on the section of thick bamboo outer wall, the motor with the stroke case all sets up on the support, and the two passes through drive mechanism transmission and connects, the output fixedly connected with push pedal of stroke case, the push pedal with eardrum reciprocating contact.

The beneficial effects that adopt above-mentioned technical scheme to produce are that, the motor provides power, through the reciprocating linear motion of stroke case with circular motion conversion to push pedal, the push pedal makes tympanic membrane reciprocating motion, and the tympanic membrane makes the interior ore pulp of pulsation pipe do left and right reciprocating motion, and then the interior ore pulp of pulsation pipe promotes the ore pulp in the grading section of thick bamboo and do up and down reciprocating motion to make nonmagnetic particle and magnetic particle in the ore pulp keep loose state, the effectual machinery that has eliminated nonmagnetic particle and magnetic particle is mingled, has improved the magnetic separation effect.

Further, the transmission mechanism is one or more of belt transmission, chain transmission and gear transmission.

Further, the ultrasonic vibrator is electrically connected with an ultrasonic controller arranged outside, the electromagnetic coil is electrically connected with a coil controller arranged outside, an outer shell is sleeved on the sorting cylinder, an overflow groove is formed between the outer shell and the sorting cylinder, the tailing outlet is communicated with the overflow groove, and the water inlet pipe is connected with a water pump arranged outside, and the ultrasonic vibrator further comprises:

the first concentration sensor is inserted into the shell, and the detection end of the first concentration sensor is arranged in the overflow groove;

the second concentration sensor is inserted at the bottom of the grading cylinder, and the detection end of the second concentration sensor is arranged in the grading cylinder and close to the concentrate outlet; and

and the controller is electrically connected with the ultrasonic controller, the coil controller, the water pump, the first concentration sensor, the second concentration sensor and the motor.

The beneficial effects that adopt above-mentioned technical scheme to produce are that, detect the content of iron powder in the tailing and the content of iron powder in the concentrate through first concentration sensor, and the two sends the testing result to the controller, the controller carries out the comparison with the setting value of inside setting according to the measuring value, thereby control ultrasonic controller, coil controller, water pump and motor, come the size of ultrasonic wave in the regulation equipment, the size of coil magnetic field, the water yield and the stroke size of stroke case, automatic adjustment has been realized, the degree of automation of equipment has been improved.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings required to be used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the provided drawings without creative efforts.

FIG. 1 is a schematic structural diagram of an ultrasonic pulsating magnetic separator according to the present invention.

Fig. 2 is an enlarged schematic view of a part a in fig. 1.

Fig. 3 is an exploded structure diagram of the ore feeding pipe and the blocking column.

FIG. 4 is a schematic top view of the first cyclone discharge port on the feeding pipe.

FIG. 5 is a schematic top view of the second cyclone discharge port on the baffle column.

Fig. 6 is an enlarged schematic view of a part B in fig. 1.

FIG. 7 is a control schematic block diagram of an ultrasonic pulsating magnetic separator.

Wherein: 1-a grading cylinder, 11-a tailing outlet, 12-an ore feeding port, 13-a water inlet pipe, 14-a concentrate outlet, 15-a pulsating pipe, 2-an ultrasonic vibrating rod, 3-an electromagnetic coil, 4-a vertical ore feeding pipe, 41-a first cyclone discharge port, 5-a material blocking column, 51-a material cavity, 52-a second cyclone discharge port, 6-a first inclined baffle, 7-a second inclined baffle, 8-a transverse support rod, 9-a tympanic membrane, 10-a pulsating machine, 101-a bracket, 102-a motor, 103-a stroke box, 104-a transmission mechanism, 105-a push plate, 16-an ultrasonic controller, 17-a coil controller, 18-a shell, 19-an overflow groove, 20-a water pump and 21-a first concentration sensor, 22-second concentration sensor, 23-controller.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

The embodiment of the utility model discloses ultrasonic wave pulsation magnet separator, include:

the ore dressing device comprises a sorting cylinder 1, wherein a tailing outlet 11 and an ore feeding port 12 are arranged at the top of the sorting cylinder 1, a water inlet pipe 13 and a concentrate outlet 14 are arranged at the bottom of the sorting cylinder 1, a plurality of ultrasonic vibration rods 2 are uniformly and fixedly inserted on the cylinder wall of the sorting cylinder 1 along the circumferential direction of the cylinder wall, a plurality of electromagnetic coils 3 are wound on the cylinder wall of the sorting cylinder 1, the ultrasonic vibration rods 2 are positioned between every two adjacent electromagnetic coils 3, the ultrasonic vibration rods 2 and the electromagnetic coils 3 are uniformly arranged above and below the cylinder wall of the sorting cylinder, and the size of ultrasonic waves and the size of a magnetic field are sequentially increased from top to bottom so as to improve the ore dressing effect, wherein an interlayer (not marked) can be arranged on the cylinder wall of the sorting cylinder, and the electromagnetic coils are arranged in the interlayer so;

the vertical ore feeding pipe 4 is arranged in the middle of the interior of the grading barrel 1, one end of the vertical ore feeding pipe 4 is communicated with the ore feeding port 12, the other end of the vertical ore feeding pipe is a closed end and extends downwards, and a plurality of first rotational flow discharge ports 41 are uniformly distributed on the outer wall, close to the closed end, of the vertical ore feeding pipe 4 along the circumferential direction of the vertical ore feeding pipe;

the material blocking column 5 is vertically arranged at the bottom inside the grading barrel 1 and is positioned right below the other end of the vertical ore feeding pipe 4, a material cavity 51 is arranged at the top of the material blocking column 5, a plurality of second rotational flow discharge holes 52 are uniformly distributed on the outer wall of the material cavity 51 along the circumferential direction of the material cavity, and the closed end of the vertical ore feeding pipe 4 penetrates through the top end of the material blocking column 5 and extends into the material cavity 51;

the pulsator 6 is fixedly arranged on the outer cylinder wall of the sorting cylinder 1, and the output end of the pulsator 6 is in reciprocating contact with the tympanic membrane 2.

The position of the outer wall of the vertical ore feeding pipe 4, which is positioned at the first rotational flow discharge port 41, is fixedly connected with a first inclined baffle 7, and an included angle a between the first inclined baffle 7 and the vertical ore feeding pipe 4 is 30-45 degrees.

The position of the outer wall of the material blocking column 5, which is positioned at the second cyclone discharge port 52, is fixedly connected with a second inclined baffle 8, and the included angle b between the second inclined baffle 8 and the material blocking column 5 is 30-45 degrees.

The first cyclone discharge port 41 and the second cyclone discharge port 52 are arranged in opposite rotating directions.

The first swirl discharge openings 41 and the second swirl discharge openings 52 are arranged in a staggered manner.

A plurality of transverse supporting rods 9 are uniformly and fixedly arranged on the material blocking column 5 along the circumferential direction of the material blocking column, the transverse supporting rods 9 are positioned below the second cyclone discharge port 52, and one end of each transverse supporting rod, which is far away from the material blocking column 5, is fixedly connected with the inner wall of the grading cylinder 1.

The bottom of the grading cylinder 1 is connected with a pulse pipe 15, one end of the pulse pipe 15 is communicated with the interior of the grading cylinder 1, the other end of the pulse pipe is connected with a tympanic membrane 9 through a flange structure, and the tympanic membrane 9 is made of rubber;

the pulsator 10 is fixedly arranged on the outer cylinder wall of the sorting cylinder 1, and the output end of the pulsator 10 is in reciprocating contact with the tympanic membrane 9.

The pulsator 6 includes: support 61, motor 62, stroke case 63, support 61 fixed mounting are on selecting and do not a set 1 outer wall, and motor 62 and stroke case 63 all set up on support 61, and the two passes through drive mechanism 64 transmission and connects, and the output fixedly connected with push pedal 65 of stroke case 63, push pedal 65 and eardrum 2 reciprocating contact.

The transmission mechanism 64 is one or more of a belt drive, a chain drive, and a gear drive.

Ultrasonic wave vibrting spear 2 is connected with the ultrasonic controller 16 electricity that the outside set up, and solenoid 3 is connected with the coil controller 17 electricity that the outside set up, selects to distinguish 1 upper end cover and is equipped with shell 18, and shell 18 and select to distinguish and be formed with overflow launder 19 between the section of thick bamboo 1, tailings export 11 and overflow launder 19 intercommunication, inlet tube 13 are connected with the water pump 20 of outside setting, still include:

the first concentration sensor 21 is inserted on the shell 18, and the detection end of the first concentration sensor 21 is arranged in the overflow groove 19;

the second concentration sensor 22 is inserted at the bottom of the grading cylinder 1, and the detection end of the second concentration sensor 22 is arranged in the grading cylinder 1 and close to the concentrate outlet 14; and

and the controller 23 is electrically connected with the ultrasonic controller 16, the coil controller 17, the water pump 20, the first concentration sensor 21, the second concentration sensor 22 and the motor 102.

The working principle of the ultrasonic pulse magnetic separator is as follows:

an external high-pressure ore pulp pump injects ore pulp into an ore feeding pipe through an ore feeding port, the ore pulp flows out of a first rotational flow discharge port into a material cavity in a certain rotational direction to realize speed reduction of the ore pulp, then the ore pulp in the material cavity flows out of a sorting cylinder in a certain rotational direction again through a second rotational flow discharge port to realize speed reduction of the ore pulp again, and finally the ore pulp entering the sorting cylinder is low in speed, so that the flow rate of water introduced into the sorting cylinder is reduced, the water consumption of the magnetic separation equipment is reduced, and water resources are saved; meanwhile, the arrangement of the first cyclone discharge port and the second cyclone discharge port enables ore pulp to flow out in a rotary direction, so that the ore pulp and water are mixed to form irregular turbulence, the ore pulp is separated, and the ore dressing effect is improved; the ultrasonic vibration rods are uniformly arranged in the grading cylinder up and down, so that ore pulp in the grading cylinder vibrates under the action of the ultrasonic vibration rods, meanwhile, when the pulsator pushes the tympanic membrane, the tympanic membrane pushes the ore pulp to make the ore pulp reciprocate up and down, and the non-magnetic particles and the magnetic particles in the ore pulp keep a loose state under the combined action of vibration and pulsation, so that mechanical inclusion of the non-magnetic particles and the magnetic particles is effectively eliminated, the magnetic separation effect is improved, and when the tympanic membrane pushes the ore pulp to move, the materials at a concentrate outlet and a tailing outlet are favorably discharged, and blockage is avoided; meanwhile, the content of the iron powder in the tailings can be detected through the first concentration sensor, the content of the iron powder in the concentrate can be detected through the second concentration sensor, the detection results are sent to the controller through the first concentration sensor and the second concentration sensor, the controller compares the detection values with set values set inside the controller, and therefore the ultrasonic controller, the coil controller, the water pump and the motor are controlled, the size of ultrasonic waves in the equipment, the size of a coil magnetic field, the water quantity and the stroke size of a stroke box are adjusted, automatic adjustment is achieved, and the automation degree of the equipment is improved.

The embodiments in the present description are described in a progressive manner, each embodiment focuses on differences from other embodiments, and the same and similar parts among the embodiments are referred to each other. The device disclosed by the embodiment corresponds to the method disclosed by the embodiment, so that the description is simple, and the relevant points can be referred to the method part for description.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (10)

1. An ultrasonic pulsating magnetic separator, comprising:

the ore dressing device comprises a grading cylinder (1), wherein a tailing outlet (11) and an ore feeding port (12) are formed in the top of the grading cylinder (1), a water inlet pipe (13) and a concentrate outlet (14) are formed in the bottom of the grading cylinder (1), a plurality of ultrasonic vibration rods (2) are uniformly inserted and fixed in the cylinder wall of the grading cylinder (1) along the circumferential direction of the cylinder wall, a plurality of electromagnetic coils (3) are wound on the cylinder wall of the grading cylinder (1), and the ultrasonic vibration rods (2) are located between every two adjacent electromagnetic coils (3);

the vertical ore feeding pipe (4) is arranged in the middle of the interior of the grading barrel (1), one end of the vertical ore feeding pipe is communicated with the ore feeding port (12), the other end of the vertical ore feeding pipe is a closed end and extends downwards, and a plurality of first rotational flow discharge ports (41) are uniformly distributed on the outer wall, close to the closed end, of the vertical ore feeding pipe (4) along the circumferential direction of the vertical ore feeding pipe;

the vertical setting of material blocking column (5) is in the inside bottom of sorting section of thick bamboo (1), and is located under vertical feeding pipe (4) other end, material blocking column (5) top is provided with material chamber (51), a plurality of second whirl discharge gates (52) have been seted up along its circumference equipartition to material chamber (51) outer wall, vertical feeding pipe (4) the blind end passes material blocking column (5) top extends to inside material chamber (51).

2. An ultrasonic pulse magnetic separator as claimed in claim 1, characterized in that the position of the outer wall of the vertical feeding pipe (4) at the first cyclone discharge port (41) is fixedly connected with a first inclined baffle (6), and the included angle a between the first inclined baffle (6) and the vertical feeding pipe (4) is 30-45 °.

3. An ultrasonic pulse magnetic separator as claimed in claim 2, characterized in that a second oblique baffle (7) is fixedly connected to the outer wall of the baffle column (5) at the position of the second cyclone discharge port (52), and the included angle b between the second oblique baffle (7) and the baffle column (5) is 30-45 °.

4. An ultrasonic pulse magnetic separator as claimed in claim 3, wherein the direction of rotation of said first cyclone discharge port (41) and said second cyclone discharge port (52) are opposite.

5. An ultrasonic pulsed magnetic separator as claimed in claim 1 wherein said first cyclone discharge openings (41) and said second cyclone discharge openings (52) are staggered.

6. An ultrasonic pulse magnetic separator as claimed in claim 1, wherein a plurality of transverse support rods (8) are uniformly and fixedly mounted on the baffle column (5) along the circumferential direction thereof, the transverse support rods (8) are located below the second cyclone discharge port (52), and one end of the transverse support rods, which is far away from the baffle column (5), is fixedly connected with the inner wall of the sorting cylinder (1).

7. An ultrasonic pulse magnetic separator as claimed in any one of claims 1 to 6, characterized in that a pulse tube (15) is connected to the bottom of the sorting cylinder (1), one end of the pulse tube (15) is communicated with the interior of the sorting cylinder (1), and the other end is provided with a tympanic membrane (9);

the pulsator (10) is fixedly installed on the outer cylinder wall of the sorting cylinder (1), and the output end of the pulsator (10) is in reciprocating contact with the tympanic membrane (9).

8. An ultrasonic pulsating magnetic separator as claimed in claim 7 wherein the pulsating machine (10) comprises: support (101), motor (102), stroke case (103), support (101) fixed mounting be in select and do not expect a section of thick bamboo (1) outer wall on, motor (102) with stroke case (103) all set up on support (101), and the two passes through drive mechanism (104) transmission and connects, the output fixedly connected with push pedal (105) of stroke case (103), push pedal (105) with eardrum (9) reciprocating contact.

9. An ultrasonic pulsating magnetic separator as claimed in claim 8 wherein said drive mechanism (104) is one or more of a belt drive, chain drive, gear drive.

10. An ultrasonic pulse magnetic separator as claimed in claim 8, wherein the ultrasonic vibrator rod (2) is electrically connected with an externally arranged ultrasonic controller (16), the electromagnetic coil (3) is electrically connected with an externally arranged coil controller (17), the upper end of the grading cylinder (1) is sleeved with a housing (18), an overflow trough (19) is formed between the housing (18) and the grading cylinder (1), the tailings outlet (11) is communicated with the overflow trough (19), the water inlet pipe (13) is connected with an externally arranged water pump (20), and the ultrasonic pulse magnetic separator further comprises:

the first concentration sensor (21), the first concentration sensor (21) is inserted on the housing (18), and the detection end of the first concentration sensor (21) is arranged in the overflow trough (19);

the second concentration sensor (22) is inserted at the bottom of the grading cylinder (1), and the detection end of the second concentration sensor (22) is arranged in the grading cylinder (1) and close to the concentrate outlet (14); and

a controller (23), the controller (23) being electrically connected to the ultrasonic controller (16), the coil controller (17), the water pump (20), the first concentration sensor (21), the second concentration sensor (22), and the motor (102).

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