JP2021146328A - Dye crushing apparatus - Google Patents

Abstract

To disclose a dye crushing apparatus.SOLUTION: A dye crushing apparatus described in the present application includes a body. A diversion space is installed in the body. An inlet that communicates with the outside is installed on an upper wall of the diversion space. Fixed blocks are fixed to front and rear walls of the diversion space. A third concave groove that opens upward is formed on an upper wall of the fixed block. A sub-transmission device is installed in the third concave groove. The present invention is simple in structure and operation. By rotating a dye cylinder by a main transmission shaft and at the same time rotating a blade, the efficiency of crushing the dye is guaranteed. A filter plate controls the degree of crushing of the dye. A push rod separates the diversion space and the stirring space, and at the same time controls the discharge of the stirred dye.SELECTED DRAWING: Figure 1

Description

The present invention takes up the field of dye technology, and specifically is a dye crushing device.

Due to its versatility, dyes are used in many production activities. For ease of handling and transportation, dye products are generally in powder form, and when purchasing large quantities of dyes, they are often stacked in one place, so over time some dyes will solidify for subsequent processing. May cause inconvenience. For solidified dyes, the conventional method is used after crushing the dye using a crusher, but the size of the dye differs depending on the crushing process, which is inconvenient for subsequent dissolution and use.

Chinese Patent Application Publication No. 106334607

The present application provides a dye crushing apparatus, and an object of the present application is to eliminate the above-mentioned drawbacks in the prior art.

The dye crushing apparatus described in the present application includes a main body, a diversion space is installed in the main body, an inlet for communicating with the outside is installed in the upper wall of the diversion space, and fixed to the front and rear walls of the diversion space. The block is fixed, a third concave groove that opens upward is formed on the upper wall of the fixed block, a secondary transmission device is installed in the third concave groove, and the fixing is performed on the lower side of the third concave groove. A motor transmission space is installed in the block, a first motor is fixed to the left wall of the motor transmission space, the first motor is movably connected to the first transmission shaft, and the first transmission shaft is connected to the first motor. The sixth helical gear is fixed, the sixth helical gear meshes with the first helical gear, the first helical gear is fixed to the main transmission shaft, and the main transmission shaft is the motor. It is rotatably connected to the upper and lower walls of the transmission space, and on the left and right sides of the third concave groove, rotary grooves are symmetrically formed on the upper wall of the fixed block, and the first position limiting groove is formed on the left and right walls of the rotary groove. Is formed, the first position limiting groove is connected to the second position limiting groove, a movable rod is slidably connected to the second position limiting groove, and the movable rod is slidably connected to the lower wall of the second position limiting groove. A second spring connected to the rod is fixed, a fifth rotating shaft is rotatably attached to the movable rod, a roller is fixed to the fifth rotating shaft, and a dye cylinder is installed on the roller. An annular groove is formed on the upper wall of the diversion space, the dye cylinder extends upward to the annular groove, the inner wall of the dye cylinder is penetrated by a filter plate, and a stirring space is provided at the lower end of the fixed block. Installed, the main transmission shaft extends downward to the stirring space and is rotatably connected to the lower wall of the stirring space, and the first impeller is fixedly connected to the main transmission shaft in the stirring space. A first concave groove is formed on the right wall of the stirring space, the first concave groove is connected to the discharge port to the right, and a first movable space is installed on the right wall of the stirring space. A main transmission device is installed in one movable space.

Advantageously, the sub-transmission device includes the main transmission shaft, the main transmission shaft extending upward into the third concave groove and rotatably connected to the bottom wall of the third concave groove. In the third concave groove, the first friction plate and the third gear are fixedly connected to the main transmission shaft, the third gear meshes with the second gear to the left and right, and the two second gears Arranged symmetrically, the second gear is fixed to the fourth rotating shaft, the fourth rotating shaft is rotatably attached to the movable plate, and the movable plate is slidably connected to the third concave groove. A communication hole is provided in the movable plate, the main transmission shaft passes through the communication hole, a second friction plate is fixed to the lower wall of the dye cylinder in the third concave groove, and the fourth rotation. A first spline sleeve is connected to the shaft by a spline, the first spline sleeve is rotatably attached to the lower wall of the dye cylinder, and the fourth rotation shaft extends upward to the dye cylinder and with a blade. It is fixed.

Advantageously, the main transmission device includes a second motor fixed to the upper wall of the first movable space, and the second motor is communicably connected to the second transmission shaft so that the second transmission shaft can be transmitted. The first pulley is fixed to the second pulley, the first pulley is connected to the second pulley by the first transport belt, the second pulley is fixed to the second spline sleeve, and the second pulley is fixed to the left side of the first movable space. Two movable spaces are installed, the second spline sleeve is rotatably attached between the first movable space and the second movable space, and a fourth transmission shaft is connected to the second spline sleeve by a spline. , The fourth transmission shaft is rotatably connected to the right with a push rod, the push rod is slidably connected to the right wall of the first movable space, and penetrates the main body, and the fourth transmission A circular table is fixed to the right side of the shaft, the circular table is slidably connected to the second helical gear, and a T-shaped annular groove is formed on the right wall of the second helical gear. A fixing rod is rotatably connected to the shaped annular groove, and the right end of the fixing rod is fixed to the right wall of the first movable space.

Advantageously, a water extraction space is installed below the first movable space, a water inlet is installed on the right side of the water extraction space, and is connected to the stirring space on the left side of the water extraction space. A drainage port is installed, a third transmission shaft is rotatably attached to the lower wall of the water extraction space, a second impeller is fixed to the third transmission shaft, and the third transmission shaft moves upward. It extends to the first movable space and is fixedly connected to the third helical gear, and the third helical gear is meshed upward with the second helical gear.

Advantageously, the fourth transmission shaft extends to the left in the second movable space and is fixedly connected to the first friction block, and the first rotation shaft is on the left wall of the second movable space. It is rotatably attached, and a fourth pulley and a fourth helical gear are fixed to the first rotating shaft, and a second friction block is fixed to the right surface of the fourth helical gear, and the second movable A worm is rotatably attached to the left wall of the space, a third pulley is fixed to the worm, the third pulley is connected to the fourth pulley by a second transport belt, and the worm meshes with a worm gear. The worm gear is fixed to the screw, a second slide groove is formed on the lower side of the second movable space, the screw extends downward to the second slide groove, and the second slide groove and the said. A first partition plate rotatably connected to the second movable space and slidably connected to the second slide groove is connected to the screw via a screw thread, and the second slide groove is connected to the screw. It penetrates the first concave groove.

Advantageously, a third slide groove is formed at the upper end of the second movable space, and a second concave groove that opens upward is formed on the lower wall of the third slide groove. A second rotating shaft is rotatably attached to the second movable space, and the second rotating shaft extends downward to the second movable space and is fixedly connected to the fifth helical gear. The fifth helical gear is meshed with the fourth helical gear, and the seventh helical gear is fixedly connected to the upper end of the second rotating shaft in the second concave groove. The seventh helical gear meshes with the eighth helical gear, the eighth helical gear is fixed to the third rotating shaft, and the third rotating shaft is attached to the front and rear walls of the second concave groove. It is rotatably connected, the first gear is fixed to the third rotating shaft, the upper end of the first gear meshes with the rack in the third slide groove, and the rack is slidable with the third slide groove. Is connected to.

Advantageously, a first slide groove is formed on the right wall of the fixed block, a hydraulic space is installed on the left wall of the first slide groove, and a first piston plate is installed on the right side of the hydraulic space. The first push rod is fixed to the first piston plate, and the first push rod extends to the left in the first slide groove and slides between the first slide groove and the hydraulic space. In the first slide groove, the first push rod is connected to the left wall of the first slide groove by a first spring, and a fourth slide groove that opens to the left is on the left side of the hydraulic space. A fourth piston plate is installed on the left side of the hydraulic space, the fourth piston plate is fixedly connected to the second push rod, and the second push rod extends into the fourth slide groove. Further, the fourth slide groove and the hydraulic space are slidably connected, and in the fourth slide groove, the second partition plate is fixedly connected to the second push rod, and the second partition plate is connected. It is slidably connected to the fourth slide groove.

Advantageously, a third position limiting groove is formed on the left wall of the diversion space, the third position limiting groove and the fourth slide groove are located on the same horizontal line, and the third position limiting groove is a movable block. The movable block is slidably connected to the third position limiting groove by a third spring.

The present invention has a simple structure and operation. The dye cylinder is rotated by the main transmission shaft, and at the same time, the blade is rotated to guarantee the efficiency of crushing the dye, and the filter plate controls the crushing condition of the dye. The push rod separates the diversion space and the stirring space, and at the same time controls the discharge of the stirred dye.

In order to explain the present invention in detail with reference to FIGS. 1 to 4 below and to explain the present invention in a convenient manner, the following directions are defined as follows: FIG. The left-right front-back direction and the up-down, left-right front-back direction of the self-projection relationship in FIG. 1 are the same.

FIG. 1 is a schematic diagram of the overall configuration of the present invention. FIG. 2 is an enlarged schematic diagram of part A in FIG. FIG. 3 is an enlarged schematic diagram of part B in FIG. FIG. 4 is an enlarged schematic diagram of part C in FIG.

The dye crushing apparatus described in the present application includes a main body 2, a diversion space 3 is installed in the main body 2, an inlet 1 communicating with the outside is installed on the upper wall of the diversion space 3, and the diversion space 3 is provided. A fixed block 17 is fixed to the front and rear walls of the fixed block 17, a third concave groove 65 that opens upward is formed on the upper wall of the fixed block 17, and a secondary transmission device is installed in the third concave groove 65. A motor transmission space 4 is installed in the fixed block 17 below the third concave groove 65, a first motor 18 is fixed to the left wall of the motor transmission space 4, and the first motor 18 is the first transmission. The sixth helical gear 9 is fixed to the first transmission shaft 19 so as to be transmitably connected to the shaft 19, and the sixth helical gear 9 meshes with the first helical gear 16. The first helical gear 16 is fixed to the main transmission shaft 22, the main transmission shaft 22 is rotatably connected to the upper and lower walls of the motor transmission space 4, and the fixing blocks are rotatably connected to the left and right sides of the third concave groove 65. Rotating grooves 69 are symmetrically formed on the upper wall of 17, and first position limiting grooves 68 are formed on the left and right walls of the rotating groove 69, and the first position limiting groove 68 is connected to the second position limiting groove 72. A movable rod 70 is slidably connected to the second position limiting groove 72, and a second spring 71 connected to the movable rod 70 is fixed to the lower wall of the second position limiting groove 72. A fifth rotating shaft 67 is rotatably attached to the movable rod 70, a roller 66 is fixed to the fifth rotating shaft 67, a dye cylinder 13 is installed on the roller 66, and an upper wall of the diversion space 3 is installed. An annular groove 12 is formed in the structure, the dye cylinder 13 extends upward in the annular groove 12, the inner wall of the dye cylinder 13 is penetrated by a filter plate 14, and a stirring space 20 is formed at the lower end of the fixed block 17. Is installed, and the main transmission shaft 22 extends downward to the stirring space 20 and is rotatably connected to the lower wall of the stirring space 20. In the stirring space 20, the main transmission shaft 22 has a first impeller. 21 is fixedly connected, a first concave groove 23 is formed on the right wall of the stirring space 20, the first concave groove 23 is connected to the discharge port 11 to the right, and the right wall of the stirring space 20 is connected. A first movable space 30 is installed in the first movable space 30, and a main transmission device is installed in the first movable space 30.

Advantageously, the sub-transmission device includes the main transmission shaft 22 so that the main transmission shaft 22 extends upward into the third recess 65 and is rotatable to the bottom wall of the third recess 65. The first friction plate 78 and the third gear 76 are fixedly connected to the main transmission shaft 22 in the third concave groove 65, and the third gear 76 meshes with the second gear 73 to the left and right. The two second gears 73 are arranged symmetrically, the second gear 73 is fixed to the fourth rotating shaft 63, and the fourth rotating shaft 63 is rotatably attached to the movable plate 74. The movable plate 74 is slidably connected to the third concave groove 65, the movable plate 74 is provided with a communication hole 75, the main transmission shaft 22 passes through the communication hole 75, and the third concave groove At 65, a second friction plate 79 is fixed to the lower wall of the dye cylinder 13, a first spline sleeve 80 is connected to the fourth rotating shaft 63 by a spline, and the first spline sleeve 80 is connected to the dye cylinder 13. It is rotatably attached to the lower wall, and the fourth rotating shaft 63 extends upward to the dye cylinder 13 and is fixed to the blade 15.

Advantageously, the main transmission device includes a second motor 29 fixed to the upper wall of the first movable space 30, and the second motor 29 is communicably connected to the second transmission shaft 28. The first pulley 27 is fixed to the second transmission shaft 28, the first pulley 27 is connected to the second pulley 31 by the first transport belt 26, and the second pulley 31 is fixed to the second spline sleeve 42. A second movable space 64 is installed on the left side of the first movable space 30, and the second spline sleeve 42 is rotatably attached between the first movable space 30 and the second movable space 64. A fourth transmission shaft 43 is connected to the second spline sleeve 42 by a spline, a push rod 34 is rotatably connected to the fourth transmission shaft 43 to the right, and the push rod 34 is connected to the first movable space 30. The circular base 33 is fixed to the right side of the fourth transmission shaft 43, and the circular base 33 slides with the second helical gear 32. A T-shaped annular groove 36 is formed on the right wall of the second helical gear 32, and a fixing rod 35 is rotatably connected to the T-shaped annular groove 36. The right end is fixed to the right wall of the first movable space 30.

Advantageously, a water extraction space 38 is installed below the first movable space 30, a water inlet is installed on the right side of the water extraction space 38, and the stirring is installed on the left side of the water extraction space 38. A drainage port 41 connected to the space 20 is installed, a third transmission shaft 40 is rotatably attached to the lower wall of the water extraction space 38, and a second impeller 39 is fixed to the third transmission shaft 40. The third transmission shaft 40 extends upward in the first movable space 30 and is fixedly connected to the third helical gear 37, and the third helical gear 37 moves upward. It meshes with the helical gear 32.

Advantageously, the fourth transmission shaft 43 extends to the left in the second movable space 64 and is fixedly connected to the first friction block 44, and is connected to the left wall of the second movable space 64. The one-rotating shaft 52 is rotatably attached, the fourth pulley 53 and the fourth helical gear 47 are fixed to the first rotating shaft 52, and the second friction is applied to the right surface of the fourth helical gear 47. The block 45 is fixed, the worm 50 is rotatably attached to the left wall of the second movable space 64, the third pulley 46 is fixed to the worm 50, and the third pulley 46 is attached to the second transport belt 51. The worm 50 is engaged with the worm gear 49, the worm gear 49 is fixed to the screw 48, and a second slide groove 24 is formed under the second movable space 64. The screw 48 extends downward into the second slide groove 24 and is rotatably connected between the second slide groove 24 and the second movable space 64, and the second slide is connected to the screw 48. The first partition plate 25 slidably connected to the groove 24 is connected via a screw thread, and the second slide groove 24 penetrates the first concave groove 23.

Advantageously, a third slide groove 62 is formed at the upper end of the second movable space 64, and a second concave groove 61 that opens upward is formed on the lower wall of the third slide groove 62. A second rotating shaft 55 is rotatably attached between the two concave grooves 61 and the second movable space 64, and the second rotating shaft 55 extends downward to the second movable space 64 to form a fifth. It is fixedly connected to the helical gear 54, and the fifth helical gear 54 meshes with the fourth helical gear 47, and in the second concave groove 61, at the upper end of the second rotating shaft 55. The seventh helical gear 56 is fixedly connected, the seventh helical gear 56 meshes with the eighth helical gear 58, and the eighth helical gear 58 is the third rotating shaft 57. The third rotating shaft 57 is rotatably connected to the front and rear walls of the second concave groove 61, and the first gear 59 is fixed to the third rotating shaft 57 in the third slide groove 62. The upper end of the first gear 59 meshes with the rack 60, and the rack 60 is slidably connected to the third slide groove 62.

Advantageously, a first slide groove 8 is formed on the right wall of the fixed block 17, a hydraulic space 10 is installed on the left wall of the first slide groove 8, and a first slide groove 8 is provided on the right side of the hydraulic space 10. A one-piston plate 5 is installed, a first push rod 6 is fixed to the first piston plate 5, the first push rod 6 extends to the left in the first slide groove 8, and the first slide. The groove 8 and the hydraulic space 10 are slidably connected, and in the first slide groove 8, the first push rod 6 is connected to the left wall of the first slide groove 8 by a first spring 7. A fourth slide groove 86 that opens to the left is formed on the left side of the hydraulic space 10, a fourth piston plate 87 is installed on the left side of the hydraulic space 10, and the fourth piston plate 87 is a second push rod 85. The second push rod 85 extends to the fourth slide groove 86 and is slidably connected between the fourth slide groove 86 and the hydraulic space 10 so as to be slidably connected to the fourth slide. In the groove 86, the second partition plate 84 is fixedly connected to the second push rod 85, and the second partition plate 84 is slidably connected to the fourth slide groove 86.

Advantageously, a third position limiting groove 81 is formed on the left wall of the diversion space 3, the third position limiting groove 81 and the fourth slide groove 86 are located on the same horizontal line, and the third position limiting groove 81 is formed. The groove 81 is slidably connected to the movable block 82, and the movable block 82 is connected to the third position limiting groove 81 by a third spring 83.

In the initial state, the first motor 18 and the second motor 29 are not operating.

At the time of operation, the dye is charged into the dye cylinder 13 from the charging port 1, the dye cylinder 13 is lowered, the first friction plate 78 and the second friction plate 79 are in contact with each other, the first motor 18 is rotated, and the first transmission is performed. The shaft 19 rotates the sixth helical gear 9 and the first helical gear 16, the first helical gear 16 rotates the main transmission shaft 22, and the main transmission shaft 22 rotates the first impeller 21. The first friction plate 78 and the third gear 76 are further rotated, the first friction plate 78 rotates the dye cylinder 13 by the second friction plate 79, and the third gear 76 rotates the fourth by the second gear 73. The shaft 63 is rotated, the fourth rotating shaft 63 rotates the blade 15, the blade 15 crushes the dye, the crushed dye enters the flow dividing space 3 via the filter plate 14, and the second motor 29 moves. Rotate, the second transmission shaft 28 rotates the first pulley 27, the first pulley 27 rotates the second pulley 31 by the first transport belt 26, and the second pulley 31 rotates the fourth transmission by the second spline sleeve 42. The shaft 43 is rotated, the fourth transmission shaft 43 rotates the third helical gear 37 by the second helical gear 32, and the third helical gear 37 uses the third transmission shaft 40 to rotate the second impeller 39. Rotate and the water extraction space 38 adds water to the stirring space 20.
When the dye concentration reaches a certain value, the push rod 34 is pushed, the push rod 34 moves the fourth transmission shaft 43, the second helical gear 32 stops rotating, and the water extraction space 38 stops operating. The first friction block 44 and the second friction block 45 are in contact with each other, the fourth helical gear 47 rotates the fourth pulley 53 and the fifth helical gear 54, and the fourth pulley 53 is the third pulley 46. The worm 50 and the worm gear 49 are rotated by the worm 50, the worm gear 49 moves the first partition plate 25 by the screw 48, the liquid in the stirring space 20 flows out from the discharge port 11, and the fifth helical gear 54 is the seventh. The helical gear 56 rotates the eighth helical gear 58, the eighth helical gear 58 moves the rack 60 by the first gear 59, and the rack 60 extends to the left in the first slide groove 8. The first push rod 6 is pushed and moved, the second push rod 85 moves the second partition plate 84, and the second partition plate 84 enters the third position limiting groove 81.
When the dye has been discharged, the second motor 29 is rotated in the reverse direction, the first partition plate 25 is closed, and the rack 60 and the second partition plate 84 return to the initial state.
When the work is completed, the first motor 18 and the second motor 29 are stopped.

According to the above method, the employee in the field can make various modifications according to the working situation within the scope of the present invention.

Claims (8)

A diversion space is installed in the main body including the main body, an inlet for communicating with the outside is installed on the upper wall of the diversion space, and fixed blocks are fixed on the front and rear walls of the diversion space. A third concave groove that opens upward is formed on the upper wall, a secondary transmission device is installed in the third concave groove, and a motor transmission space is installed in the fixed block below the third concave groove. The first motor is fixed to the left wall of the motor transmission space, the first motor is movably connected to the first transmission shaft, and the sixth helical gear is fixed to the first transmission shaft. The sixth helical gear meshes with the first helical gear, the first helical gear is fixed to the main transmission shaft, and the main transmission shaft can rotate with the upper and lower walls of the motor transmission space. Rotated grooves are symmetrically formed on the upper wall of the fixed block on the left and right sides of the third concave groove, and first position limiting grooves are formed on the left and right walls of the rotating groove, and the first position limiting groove is formed. The groove is connected to the second position limiting groove, the movable rod is slidably connected to the second position limiting groove, and the second spring connected to the movable rod is connected to the lower wall of the second position limiting groove. Fixed, a fifth rotating shaft is rotatably attached to the movable rod, a roller is fixed to the fifth rotating shaft, a dye cylinder is installed on the roller, and an annular shape is formed on the upper wall of the diversion space. A groove is formed, the dye cylinder extends upward to the annular groove, the inner wall of the dye cylinder is penetrated by a filter plate, a stirring space is provided at the lower end of the fixed block, and the main transmission shaft is downward. It extends to the stirring space and is rotatably connected to the lower wall of the stirring space. In the stirring space, the first impeller is fixedly connected to the main transmission shaft, and to the right wall of the stirring space. A first concave groove is formed, the first concave groove is connected to the discharge port to the right, a first movable space is installed on the right wall of the stirring space, and a main transmission device is installed in the first movable space. A dye crushing device characterized by being installed. The sub-transmission device includes the main transmission shaft, and the main transmission shaft extends upward to the third concave groove and is rotatably connected to the bottom wall of the third concave groove in the third concave groove. The first friction plate and the third gear are fixedly connected to the main transmission shaft, the third gear meshes with the second gear to the left and right, and the two second gears are arranged symmetrically. The second gear is fixed to the fourth rotating shaft, the fourth rotating shaft is rotatably attached to the movable plate, the movable plate is slidably connected to the third concave groove, and the movable plate is slidably connected to the movable plate. A communication hole is installed, the main transmission shaft passes through the communication hole, a second friction plate is fixed to the lower wall of the dye cylinder in the third concave groove, and a first friction plate is fixed to the fourth rotation shaft. The spline sleeve is connected by a spline, the first spline sleeve is rotatably attached to the lower wall of the dye cylinder, and the fourth rotation axis extends upward to the dye cylinder and is fixed to the blade. The dye crushing apparatus according to claim 1. The main transmission device includes a second motor fixed to the upper wall of the first movable space, the second motor is communicably connected to the second transmission shaft, and the first pulley is connected to the second transmission shaft. Is fixed, the first pulley is connected to the second pulley by the first transport belt, the second pulley is fixed to the second spline sleeve, and the second movable space is installed on the left side of the first movable space. The second spline sleeve is rotatably attached between the first movable space and the second movable space, and a fourth transmission shaft is connected to the second spline sleeve by a spline to form the fourth transmission. The shaft is rotatably connected to the push rod to the right, the push rod is slidably connected to the right wall of the first movable space and penetrates the main body, and on the right side of the fourth transmission shaft. The round table is fixed, the round table is slidably connected to the second helical gear, a T-shaped annular groove is formed on the right wall of the second helical gear, and the T-shaped annular groove is formed. The dye crushing apparatus according to claim 1, wherein the fixing rods are rotatably connected and the right end of the fixing rods is fixed to the right wall of the first movable space. A water extraction space is installed below the first movable space, a water inlet is installed on the right side of the water extraction space, and a drain port connected to the stirring space is installed on the left side of the water extraction space. A third transmission shaft is rotatably attached to the lower wall of the water extraction space, a second impeller is fixed to the third transmission shaft, and the third transmission shaft moves upward into the first movable space. The dye according to claim 3, wherein the third helical gear is extended and fixedly connected to the helical gear, and the third helical gear is meshed upward with the second helical gear. Crusher. The fourth transmission shaft extends to the left in the second movable space and is fixedly connected to the first friction block, and the first rotation shaft is rotatably attached to the left wall of the second movable space. A fourth pulley and a fourth helical gear are fixed to the first rotating shaft, a second friction block is fixed to the right surface of the fourth helical gear, and the left wall of the second movable space is fixed. The worm is rotatably attached, the third pulley is fixed to the worm, the third pulley is connected to the fourth pulley by the second transport belt, the worm is engaged with the worm gear, and the worm gear is engaged. It is fixed to the screw, a second slide groove is formed under the second movable space, the screw extends downward to the second slide groove, and the second slide groove and the second movable space A first partition plate slidably connected to the second slide groove is connected to the screw rotatably between the two, and the second slide groove connects the first concave groove to the screw. The dye crushing apparatus according to claim 3, further comprising penetrating. A third slide groove is formed at the upper end of the second movable space, a second concave groove that opens upward is formed on the lower wall of the third slide groove, and the second concave groove and the second movable space are formed. A second rotating shaft is rotatably attached between the two, and the second rotating shaft extends downward into the second movable space and is fixedly connected to the fifth helical gear. The helical gear meshes with the fourth helical gear, and the seventh helical gear is fixedly connected to the upper end of the second rotating shaft in the second concave groove, and the seventh helical gear is fixedly connected. The helical gear meshes with the eighth helical gear, the eighth helical gear is fixed to the third rotating shaft, and the third rotating shaft is rotatably connected to the front and rear walls of the second concave groove. , The first gear is fixed to the third rotating shaft, the upper end of the first gear meshes with the rack in the third slide groove, and the rack is slidably connected to the third slide groove. The dye crushing apparatus according to claim 5. A first slide groove is formed on the right wall of the fixed block, a hydraulic space is installed on the left wall of the first slide groove, and a first piston plate is installed on the right side of the hydraulic space. A first push rod is fixed to the piston plate, and the first push rod extends to the left in the first slide groove and is slidably connected between the first slide groove and the hydraulic space. In the first slide groove, the first push rod is connected to the left wall of the first slide groove by a first spring, and a fourth slide groove opening to the left is formed on the left side of the hydraulic space. A fourth piston plate is installed on the left side of the space, the fourth piston plate is fixedly connected to the second push rod, the second push rod extends into the fourth slide groove, and the fourth slide. A second partition plate is fixedly connected to the second push rod in the fourth slide groove, and the second partition plate is fixedly connected to the fourth slide groove. The dye crushing apparatus according to claim 6, wherein the dye crushing apparatus is slidably connected to the same. A third position limiting groove is formed on the left wall of the diversion space, the third position limiting groove and the fourth slide groove are located on the same horizontal line, and the third position limiting groove is slidably connected to the movable block. The dye crushing apparatus according to claim 7, wherein the movable block is connected to the third position limiting groove by a third spring.

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