CN115365483A - Light alloy motor casing casting equipment - Google Patents

Abstract

The invention relates to the technical field of casting of motor housings, in particular to light alloy motor housing casting equipment; the clamping device comprises an underframe, side frames, a cylinder A, a cylinder B, cylinders, a circular ring, sliding chutes A, sliding blocks A, clamping columns, clamping hands and a clamping frame, wherein the two side frames are fixedly connected to the underframe; a casting device for a light alloy motor shell.

Description

Light alloy motor casing casting equipment

Technical Field

The invention relates to the technical field of casting of motor housings, in particular to light alloy motor housing casting equipment.

Background

The motor casing is a casing for protecting electrical components inside the motor, and is usually made of aluminum alloy, and the casting is to melt metal and pour the metal into a casting mold to form a predetermined object, and when a light alloy motor casing model is cast, a light alloy motor casing casting device is used for casting the model.

Present light alloy motor casing casting equipment still needs personnel to use anchor clamps to come out with the motor casing centre gripping after the casting is accomplished, has both wasted a large amount of time, causes danger to personnel easily again, lacks a light alloy motor casing casting equipment that can come out with the motor casing centre gripping automatically.

Disclosure of Invention

In order to overcome the defects of the prior art, the invention provides light alloy motor shell casting equipment which can automatically clamp the cast light alloy motor shell.

The technical scheme adopted by the invention for solving the technical problems is as follows:

the cylinder type air compressor comprises an underframe, side frames, a cylinder A, a cylinder B and cylinders, wherein the two side frames are fixedly connected to the underframe, the cylinder A is fixedly connected between the two side frames, the cylinder B is slidably connected to the cylinder A, shells of the two cylinders are fixedly connected to the underframe, and cylinder rods of the two cylinders are fixedly connected to the cylinder B.

The clamping device comprises a clamping column, a clamping cup, a sliding block A, two sliding blocks A, two clamping handles and a clamping frame, the clamping column is fixedly connected between two side frames, the sliding blocks A are fixedly connected to the inner side of the circular ring, the two clamping columns are fixedly connected with the sliding blocks A respectively, the two sliding blocks A are slidably connected to the two sliding blocks A respectively, the two clamping columns are fixedly connected with the two clamping handles respectively, springs are fixedly connected between the two clamping columns and the two clamping handles respectively, the clamping frame is fixedly connected to a cylinder B, the clamping cup is fixedly connected to the lower portion of the clamping frame, and the clamping cup is rotatably connected with the clamping cup ring.

Still include the feed inlet, feed inlet fixed connection is in the top of holder.

Still include slider B and baffle A, all seted up the round hole in two spout A, two slider B difference sliding connection are in two round holes, equal fixedly connected with spring between two slider B and the ring, and baffle A fixed connection is in the top of holder.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

FIG. 1 is a schematic structural view of a light alloy motor housing casting apparatus according to the present invention;

FIG. 2 is a schematic view of the construction of the undercarriage and sideframe of the present invention;

FIG. 3 is a schematic view of the structure of a cylinder B according to the present invention;

FIG. 4 is a schematic view of the structure of cylinder A of the present invention;

FIG. 5 is a schematic view of the sideframe and the ring of the present invention;

FIG. 6 is a plan view of the ring of the present invention;

FIG. 7 is a schematic view of the structure of the gripper of the present invention;

FIG. 8 is a schematic view of the structure of the cylinder B and the clamping frame of the present invention;

FIG. 9 is a schematic view of the structure of the clamping frame of the present invention;

FIG. 10 is a schematic view of the structure of the equalizer bar and the strut of the present invention;

FIG. 11 is a schematic view of the structure of the blocking frame of the present invention;

fig. 12 is a schematic structural view of a carriage B in the present invention;

FIG. 13 is a schematic view of the structure of a slide B in the present invention;

fig. 14 is a schematic structural view of a tripod and a triangle in the present invention.

Detailed Description

Referring to fig. 1-5, an automatic demolding process for a light alloy motor housing is shown according to the following steps:

the invention comprises a chassis 1, side frames 2, a cylinder A3, a cylinder A4, a cylinder B5 and cylinders 31, wherein the two side frames 2 are fixedly connected to the chassis 1, the cylinder A3 is fixedly connected to the chassis 1, the cylinder A4 is fixedly connected between the two side frames 2, the cylinder B5 is slidably connected to the cylinder A3, housings of the two cylinders 31 are fixedly connected to the chassis 1, cylinder rods of the two cylinders 31 are fixedly connected to the cylinder B5, when the two cylinders 31 are not extended, the cylinder B5 is positioned at the lower part of the cylinder A4, melted light alloy materials are filled from the upper part of the cylinder A4, the filled light alloy materials flow into a die formed among the cylinder A3, the cylinder A4 and the cylinder B5, after the melted light alloy materials are cooled, the cooled light alloy materials are formed into a motor housing, the motor housing is located on the cylinder B5, and the two cylinders 31 are started simultaneously, the cylinder rods of the two cylinders 31 all extend upwards, the top ends of the cylinder rods of the two cylinders 31 are fixedly connected to the cylinder B5, the two cylinder rods can drive the cylinder B5 to move upwards together, the cylinder B5 can drive the light alloy motor shell located on the cylinder B5 to move upwards together, the cylinder rods of the two cylinders 31 extend upwards, the distance of the upward movement of the cylinder B5 is larger, the light alloy motor shell also follows the upward movement distance of the cylinder B5 to be larger, the light alloy motor shell slowly moves out of the cylinder A4 in the ascending process, when the light alloy motor shell completely moves out of the cylinder A4, the cylinder rods of the two cylinders 31 stop extending upwards, the whole light alloy motor shell completely moves out of the cylinder A4 and is located on the cylinder B5, and therefore the automatic demolding effect of the light alloy motor shell is obtained.

With reference to fig. 1 to 9, the process of moving the light alloy motor housing off the cylinder B5 can be obtained according to what is shown:

the invention also comprises a circular ring 6, a chute A7, a slide block A8, clamping columns 9, a clamping cup 10, a clamping cup ring 11, clamping hands 12 and a clamping frame 13, wherein the circular ring 6 is fixedly connected on the side frame 2, two chutes A7 are arranged in the circular ring 6, the slide blocks A8 are fixedly connected on the two clamping columns 9, the two slide blocks A8 are respectively and slidably connected in the two chutes A7, the two clamping columns 9 are respectively and fixedly connected with the two clamping hands 12, a spring is fixedly connected between the two clamping columns 9, the spring is fixedly connected between the two clamping hands 12, the clamping frame 13 is fixedly connected on the cylinder B5, the clamping cup 10 is fixedly connected below the clamping frame 13, the clamping cup ring 11 is movably connected in the clamping cup 10, the lengths of the two slide blocks A8 respectively and fixedly connected on the two clamping columns 9 are larger than the distance between the two clamping columns 9, the clamping frame 13 is fixedly connected on the cylinder B5, when the cylinder B5 rises, the clamping frame 13 is driven to move upwards, the clamping cup 10 moves upwards together with the clamping frame 13, the cup clamping ring 11 also moves upwards along with the cup clamping ring 10, the cup clamping ring 11 can slowly approach to the two clamping columns 9 in the process of moving upwards, when the cylinder B5 pushes the whole light alloy motor shell to slide out of the cylinder A4, the two clamping columns 9 slowly enter the cup clamping ring 11, the diameter of the cup clamping ring 11 becomes smaller towards the lower part, the two clamping columns 9 are drawn close towards the center when the cup clamping ring 11 moves upwards, the two clamping columns 12 drawn close towards the center can clamp the light alloy motor shell when the cylinder B5 pushes the light alloy motor shell to slide out of the cylinder A4, the cylinder rods of the two cylinders 31 continue to extend to drive the cylinder B5 to continue to move upwards, the cylinder B5 drives the clamping frame 13 to continue to move upwards, and the clamping frame 13 drives the cup clamping ring 11 to continue to move upwards, the cup clamping ring 11 can drive the two clamping columns 9 to move upwards, the two clamping columns 9 are fixedly connected with sliding blocks A8, two sliding grooves A7 are formed in the inner side of the circular ring 6, the two sliding blocks A8 are connected in the two sliding grooves A7 in a sliding mode respectively, the two sliding grooves A7 are oblique and upward notches, when the two sliding blocks A8 move upwards, the two sliding blocks A8 can rotate along with the two sliding grooves A7 when moving upwards, the two sliding blocks A8 rotate to drive the two clamping columns 9 to rotate, after clamping the light alloy motor shell, the two clamping hands 12 clamp the light alloy motor shell down from the circular cylinder B5, the light alloy motor shell rotates to the right side of the circular cylinder A4, after taking down the light alloy motor shell on the right side of the circular cylinder A4, the air cylinder rods of the two air cylinders 31 shrink, the two air cylinder rods shrink to drive the circular cylinder B5 to fall, the circular cylinder B5 drives the clamping frame 13 to fall, the cup frame 13 falls to drive the cup clamping ring 11 to fall, after the cup clamping ring 11, the two clamping columns 9 can follow the two sliding blocks A8 in the two sliding blocks A7, after completely moving downwards, the two clamping columns 9 move, the light alloy motor shell, the clamping columns 9 and the light alloy motor shell can return to the light alloy shell to melt, and the two clamping columns 9, and the light alloy shell after the light alloy shell moves to melt, and the light alloy motor shell, and the light alloy shell.

With reference to fig. 1 to 9, a process for reducing the use of light alloy materials can be obtained according to the figures:

the invention also comprises a feed inlet 14, the feed inlet 14 is fixedly connected above the clamping frame 13, the feed inlet 14 is positioned above the cylinder A4, when a light alloy motor shell is required to be cast, melted light alloy materials are filled into the feed inlet 14, the melted light alloy materials are in a liquid state and can enter the cylinder A4 along the feed inlet 14, the melted light alloy materials are stopped being filled after the cylinder A4 is full, then, after the light alloy materials are cooled into the light alloy motor shell in the cylinder A4, the cylinder rods of the two cylinders 31 are started to extend upwards, the clamping frame 13 moves upwards, the feed inlet 14 is driven by the clamping frame 13 to move upwards, after the light alloy is clamped out of the cylinder A4, the two cylinder rods retract to drive the clamping frame 13 to move downwards, the clamping frame 13 drives the feed inlet 14 to return to the initial stage, the feed inlet 14 is positioned above the cylinder A4 again, the feed inlet 14 is in a funnel shape, the light alloy materials after being melted can be prevented from being sputtered outside, the waste of the materials is reduced, and the effect of using the light alloy motor shell is achieved.

Referring to fig. 1-9, a process for automatically loosening a light alloy motor housing is obtained according to the illustration:

the invention also comprises a sliding block B15 and a baffle plate A16, wherein circular holes are respectively arranged in the two sliding chutes A7, the two sliding blocks B15 are respectively connected in the two circular holes in a sliding manner, springs are respectively fixedly connected between the two sliding blocks B15 and the circular ring 6, the baffle plate A16 is fixedly connected above the clamping frame 13, after the light alloy motor shell is clamped by the two clamping hands 12, the two air cylinders 31 continuously ascend to drive the two clamping hands 12 to clamp the light alloy motor shell to rotate to the right side of the cylinder A4, then the two sliding blocks A8 meet the two sliding blocks B15 which respectively slide in the circular holes of the two sliding chutes A7, the two air cylinders 31 continuously ascend to push the two clamping columns 9 to continuously move upwards through the clamping cup ring 11, the two clamping columns 9 drive the two sliding blocks A8 to continuously move upwards in the two sliding chutes A7, the two sliding blocks A8 press the two sliding blocks B15 into the circular holes arranged in the two sliding chutes A7, and then the two sliding blocks A8 reach the top ends of the two sliding chutes A7, the two sliding blocks B15 do not extrude the two sliding blocks A8 and then leak out of the circular holes through the action of the springs, then the air cylinder rods of the two air cylinders 31 start to retract into the cylinder B5 to move downwards, the clamping frame 13 moves downwards along with the cylinder B5, but because the two sliding blocks B15 are blocked, the two sliding blocks A8 cannot move downwards in the two sliding grooves A7, the clamping frame 13 drives the cup clamping ring 11 to move downwards, after the cup clamping ring 11 moves downwards, the two clamping columns 9 do not extrude the cup clamping ring 11 through the action of the springs and start to open towards two sides, the two clamping hands 12 fixedly connected to the two clamping columns 9 respectively start to open towards two sides, the clamped light alloy motor shell is loosened, then the clamping frame 13 continues to move downwards, the baffle A16 fixedly connected to the clamping frame 13 moves downwards along with the clamping frame 13, the right clamping hand 12 is met in the downward moving process of the baffle A16, and the bottom surface of the baffle A16 is an inclined surface, baffle A16 moves down the in-process and can extrude tong 12 on right side, and tong 12 on right side can extrude slider A8 and move down in spout A7, extrudes two sliders B15 back in the slide round hole when two sliders A8, and two sliders A8 slide to the bottom of two spouts A7, and two tong 12 are extruded initial position by baffle A16, repeats above step to this obtains the effect of automatic unclamping light alloy motor casing.

Referring to fig. 1 to 10, the process of dropping the light alloy motor case can be obtained according to the drawings:

the invention also comprises a balancing frame 17, a support column 18, a block 19, a containing cylinder 20 and a cylinder block 32, wherein the support column 18 is fixedly connected to the bottom frame 1, the two balancing frames 17 are connected to the support column 18 through a pin shaft, one end of each balancing frame 17 is connected to the block 19 through a pin shaft, the other end of each balancing frame 17 is connected to the containing cylinder 20 through a pin shaft, the light alloy motor shell is clamped by the two clamping hands 12 and rotates to the position above the containing cylinder 20, then the cylinder rods of the two cylinders 31 retract to drive the two clamping hands 12 to move outwards to release the clamped light alloy motor shell, the light alloy motor shell falls into the containing cylinder 20, the distance from the containing cylinder 20 to the support column 18 is the same as the distance from the block 19 to the support column 18, but the weight of the light alloy motor shell is larger than that of the block 19, when the light alloy motor shell is placed in the containing cylinder 20, the containing cylinder 20 contains the light alloy motor shell and falls together, one end of the block 19 connected to the light alloy motor shell through the pin shaft starts to rise, the light alloy motor shell falls down from a high position, and the light alloy motor shell can not be collided with the light alloy motor shell effectively.

Referring to fig. 1 to 11, a process of tilting the light alloy motor case can be obtained according to the drawings:

the invention also comprises a turning frame 22 and a barrel block 32, wherein the turning frame 22 is fixedly connected to the bottom frame 1, the barrel block 32 is fixedly connected to the lower part of the containing barrel 20, when the containing barrel 20 contains the light alloy motor shell and falls, the barrel block 32 fixedly connected to the lower part of the containing barrel 20 meets the turning frame 22 in the falling process, the turning frame 22 is a portal frame, when the falling barrel block 32 meets the turning frame 22, the barrel block 32 stops moving downwards, but the whole containing barrel 20 can move downwards under the action of gravity, the turning frame 22 causes the containing barrel 20 to incline towards the front end, when the containing barrel 20 inclines forwards, the gravity can increase the inclination angle of the containing barrel 20, when the barrel mouth of the containing barrel 20 inclines downwards, the light alloy motor shell slides out of the containing barrel 20 under the action of the gravity, and the light alloy motor shell slides out of the light alloy motor shell from the original vertical containing barrel 20 to be transversely placed on the bottom frame 1, so that the effect of the light alloy motor shell toppling over is obtained.

Referring to fig. 1 to 11, a process of smoothly dropping a light alloy motor case can be obtained according to the drawings:

the motor shell structure also comprises a blocking frame 21, wherein the blocking frame 21 is fixedly connected to the side frame 2, when the light alloy motor shell falls out of the containing barrel 20, the end of the containing barrel 20 can be lifted up by a heavy object 19 through the balancing frame 17 due to the fact that the weight is reduced, the containing barrel 20 can swing front and back in the rising process, the upper portion of the containing barrel 20 is rectangular, the containing barrel 20 which swings back currently rises to the top end and can touch the blocking frame 21, the blocking frame 21 is a rectangular frame, the containing barrel 20 is clamped at the lower end of the blocking frame 21 under the action of the heavy object 19 and the blocking frame 21, the containing barrel 20 can be stably located at the lower end of the blocking frame 21 through clamping, then the light alloy motor shell is placed into the containing barrel 20, the balancing frame 17 at the end of the containing barrel 20 inclines downwards next time after the light alloy motor shell is placed into the containing barrel 20, then the containing barrel 20 touches the overturning frame 22, the light alloy and the light alloy motor shell falls out of the containing barrel 20, and the steps are repeated, and the effect of enabling the light alloy motor shell to fall down stably is achieved.

Referring to fig. 1-13, a process for transporting a light alloy motor housing is shown according to the drawings:

the invention also comprises a sliding plate B25, sliding frames B26, sliding chutes C27, sliding blocks C28 and sliding columns C29, wherein two sliding frames B26 are fixedly connected to the underframe 1, four sliding blocks C28 are fixedly connected to the sliding plate B25, four sliding chutes C27 are respectively arranged in the two sliding frames B26, one sliding block C28 is slidably connected in each sliding chute C27, four sliding columns C29 are respectively fixedly connected to the four sliding blocks C28, springs are fixedly connected between the four sliding blocks C28 and the two sliding frames B26, the light alloy motor shell is toppled between the two sliding frames B26 from the containing cylinder 20, a worker can place a transfer forklift below the underframe 1, after the light alloy motor shell is toppled between the two sliding frames B26, the four sliding blocks C28 respectively slide rightwards in the four sliding chutes C27, and the four sliding blocks C28 can drive the fixedly connected sliding plate B25 to move rightwards, when the four sliding blocks C28 move rightwards, the four sliding columns C29 are pushed out from the two sliding frames B26, a light alloy motor shell can be met in the rightwards moving process of the sliding plate B25, the sliding plate B25 pushes the light alloy motor shell to move rightwards together, the sliding plate B25 continuously moves rightwards to push the light alloy motor shell down to the bottom frame 1, a transfer forklift used by a worker below the bottom frame 1 can just hold the light alloy motor shell, then the worker can use the transfer forklift to transfer the light alloy motor shell to a next working procedure, the four sliding columns C29 pushed out from the two sliding frames B26 can be blocked at the front end and the rear end of the light alloy motor shell, the light alloy motor shell deflects in the falling process, and the light alloy motor shell can better fall onto the transfer forklift, so that the effect of transferring the light alloy motor shell is obtained.

Referring to fig. 1, 10 and 11, the automatic transfer process of the light alloy motor shell can be obtained according to the process shown in the figures:

the invention also comprises a tripod 23 and a triangular plate 24, the tripod 23 is fixedly connected on the balancing stand 17, the triangular plate 24 is connected on the tripod 23 in a sliding manner, a rectangular through hole is formed in the underframe 1, the triangular plate 24 is connected in the rectangular through hole in a sliding manner, when a light alloy motor shell in the containing barrel 20 is inclined between two sliding frames B26, the weight of the end of the containing barrel 20 is reduced along with the pouring of the light alloy motor shell, the weight of the containing barrel 20 is smaller than that of the object 19, the object 19 lifts the end of the containing barrel 20 through the balancing stand 17, the object 19 moves downwards, the containing barrel 20 moves upwards, the balancing stand 17 at the end of the containing barrel 20 also inclines upwards, the tripod 23 fixedly connected on the balancing stand 17 also moves upwards, the triangular plate 23 moves upwards to drive the triangular plate 24 to move upwards, an inclined plane is arranged below the triangular plate 24, the inclined plane faces the sliding plate B25, the triangular plate 24 presses the sliding plate B25 rightwards in the process that the triangular plate 24 moves upwards, the light alloy sliding plate B25 moves rightwards to push the light alloy sliding plate out the light alloy motor shell 1 rightwards, when the motor shell 20 is connected in the motor shell, the motor shell 20, the light alloy motor shell slowly returns the inclined plane to the inclined plane 17 to press the inclined plane of the containing barrel, and the light alloy motor shell, the light alloy motor shell 17, and the light alloy motor shell 17, and the light alloy motor shell 23 is automatically.

With reference to fig. 1 to 7, a procedure for cleaning the casting mould can be obtained according to what is shown:

the invention also comprises an air outlet pipe 30, the air outlet pipe 30 is fixedly connected to the clamping columns 9, when the light alloy motor shell is clamped by the two clamping hands 12 and rotates to the right side of the cylinder A4, the air outlet pipe 30 just rotates above the cylinder B5 along with the clamping columns 9, the cylinder B5 can push out the light alloy materials left in the cylinder A4 in the process of rising, the light alloy materials are pushed to the top end of the cylinder A4, then the air outlet pipe 30 is opened, strong wind is blown out of the air pipe 30, the strong wind can blow the light alloy materials left on the cylinder B5 completely, then the two clamping hands 12 are rotated to the initial position, the clamping columns 9 drive the air outlet pipe 30 to rotate to the initial position, then the strong wind blown out of the air outlet pipe 30 is closed, the steps are repeated, and the casting die can be cleaned once after the light alloy motor shell is cast, so that the effect of cleaning the die is obtained.

Claims (10)

1. The utility model provides a light alloy motor casing casting equipment which characterized in that: the frame comprises an underframe (1), side frames (2), a cylinder A (3), a cylinder A (4), a cylinder B (5) and cylinders (31), wherein the two side frames (2) are fixedly connected to the underframe (1), the cylinder A (3) is fixedly connected to the underframe (1), the cylinder A (4) is fixedly connected between the two side frames (2), the cylinders B (5) are slidably connected to the cylinder A (3), shells of the two cylinders (31) are fixedly connected to the underframe (1), and cylinder rods of the two cylinders (31) are fixedly connected to the cylinders B (5).

2. The casting device of the light alloy motor casing according to claim 1, wherein: still include ring (6), spout A (7), slider A (8), press from both sides post (9), press from both sides cup (10), press from both sides cup ring (11), tong (12) and holder (13), ring (6) fixed connection is between two side bearer (2), two spout A (7) have been seted up to ring (6) inboard, equal fixedly connected with slider A (8) on two clamp posts (9), two slider A (8) sliding connection respectively are in two spout A (7), two tong (12) of fixedly connected with respectively on two clamp posts (9), equal fixedly connected with spring between two clamp posts (9) and two tong (12), holder (13) fixed connection is on drum B (5), press from both sides cup (10) fixed connection in the below of holder (13), it has clamp cup ring (11) to press from both sides in cup (10) the rotary connection.

3. The casting device of the light alloy motor casing according to claim 2, wherein: the feeding device also comprises a feeding hole (14), and the feeding hole (14) is fixedly connected above the clamping frame (13).

4. The casting device of the light alloy motor casing according to claim 3, wherein: still include slider B (15) and baffle A (16), all seted up the round hole in two spout A (7), two slider B (15) sliding connection respectively in two round holes, equal fixedly connected with spring between two slider B (15) and ring (6), baffle A (16) fixed connection is in the top of holder (13).

5. The casting device of the light alloy motor casing as claimed in claim 4, wherein: still include gimbal (17), pillar (18), thing piece (19) and connect a section of thick bamboo (20) greatly, pillar (18) fixed connection is on chassis (1), and two gimbals (17) are all through the round pin hub connection on pillar (18), and the one end of two gimbals (17) is all through the round pin hub connection on thing piece (19), and the other end of two gimbals (17) is all through the round pin hub connection on Cheng Jietong (20).

6. The casting device of the light alloy motor casing as claimed in claim 5, wherein: the device also comprises a roll-over stand (22) and a barrel block (32), wherein the roll-over stand (22) is fixedly connected on the underframe (1), and the barrel block (32) is fixedly connected below the Cheng Jietong (20).

7. The casting device of the light alloy motor casing as claimed in claim 6, wherein: the anti-collision device also comprises a blocking frame (21), wherein the blocking frame (21) is fixedly connected to the side frame (2).

8. The casting device of the light alloy motor casing according to claim 7, wherein: still include slide B (25), balladeur train B (26), spout C (27), slider C (28) and traveller C (29), two equal fixed connection of balladeur train B (26) are on chassis (1), slide B (25) are gone up four slider C (28) of fixedly connected with, four spout C (27) have been seted up respectively in two balladeur train B (26), sliding connection has a slider C (28) in every spout C (27), four traveller C (29) are on four slider C (28) of fixed connection respectively, equal fixedly connected with spring between four slider C (28) and two balladeur train B (26).

9. The casting device of the light alloy motor casing according to claim 8, wherein: still include tripod (23) and set-square (24), tripod (23) fixed connection is on balancing stand (17), and set-square (24) sliding connection has seted up the rectangle through-hole on tripod (23) chassis (1), and set-square (24) sliding connection is in the rectangle through-hole.

10. The casting device of the light alloy motor casing according to claim 9, wherein: the air outlet pipe (30) is fixedly connected to the clamping column (9).

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