CN219003260U - Gear rotary mechanism of steel slag ball mill - Google Patents

Abstract

The utility model discloses a gear rotating mechanism of a steel slag ball mill, which comprises a supporting plate, a first connecting plate, a servo motor and a first transmission gear, wherein two groups of mutually symmetrical buffer mechanisms are arranged above the supporting plate, a movable positioning mechanism is arranged above the first connecting plate, and a lifting positioning mechanism is arranged above the movable positioning mechanism. According to the utility model, the rotating speed of the reversing gear can be adjusted by replacing the first transmission gear and the second transmission gear through the cooperation of the movable positioning mechanism, the lifting positioning mechanism, the servo motor, the rotating rod, the first transmission gear, the first through hole, the second transmission gear and the reversing gear.

Description

Gear rotary mechanism of steel slag ball mill

Technical Field

The utility model relates to the technical field of mineral processing equipment, in particular to a gear of a gear rotary mechanism of a steel slag ball mill.

Background

The steel slag ball mill is widely applied to the production industries of novel building materials, refractory materials, chemical fertilizers, black and nonferrous metal mineral processing, glass ceramics and the like of mud and silicate products, and carries out dry or wet grinding on various ores and other grindability materials.

At present, the rotating gear of a general steel slag ball mill can not be changed to adjust the rotating speed, and the rotating speed can only be adjusted by adjusting the power of a servo motor, so that a large amount of energy is wasted.

Disclosure of Invention

The utility model aims to make up the defects of the prior art and provides a gear rotating mechanism of a steel slag ball mill.

In order to achieve the above purpose, the present utility model provides the following technical solutions:

the utility model provides a slag ball mill gear rotation mechanism, includes backup pad, first connecting plate, servo motor, first drive gear, the top of backup pad is provided with two sets of buffer gear of mutual symmetry, the top of first connecting plate is provided with the removal positioning mechanism, the top of removal positioning mechanism is provided with lift positioning mechanism, servo motor's output fixedly connected with dwang, first through-hole has been seted up to first drive gear's right flank, the surface and the inside wall fixedly connected with of first through-hole of dwang, the left end fixedly connected with second drive gear of dwang, the last fixedly connected with of first connecting plate two sets of supporting legs of mutual symmetry, two sets of equal fixedly connected with support layer board in top of supporting leg, the last cambered surface fixedly connected with ball mill cylinder of support layer board, ball mill cylinder's internally mounted has reversing gear, reversing gear's surface and second drive gear's surface meshing are connected.

Further, the buffer mechanism comprises a buffer frame, the top end of the buffer frame is fixedly connected with the lower surface of the first connecting plate, a buffer cavity is formed in the bottom end of the buffer frame, an elastic piece is fixedly connected to the inner top wall of the buffer cavity, and a first sliding plate is fixedly connected to the bottom end of the elastic piece.

Further, the surface of first sliding plate and the inside wall sliding connection of buffering chamber, the bottom fixedly connected with support column of first sliding plate, the bottom fixedly connected with supporting disk of support column, the lower surface of supporting disk and the last fixed surface of backup pad are connected.

Further, remove positioning mechanism includes slip frame, second sliding plate, the upper surface fixed connection of lower surface and first connecting plate of slip frame, first draw-in groove has been seted up to the right-hand member of slip frame, a set of concentric second through-hole of equidistance has been seted up to the right-hand member of slip frame, the sliding chamber has been seted up to the upper surface of slip frame, the inside wall sliding connection in sliding chamber has the slider, the upper surface fixed connection of slider has the second connecting plate, the screw hole has been seted up to the right-hand member of slider, the inside wall threaded connection of screw hole has the threaded rod.

Further, the left end of threaded rod is connected with the inside wall rotation of sliding chamber, the right-hand member of threaded rod runs through first draw-in groove, and fixedly connected with head rod, the right-hand member fixedly connected with first rolling disc of head rod, the right flank fixedly connected with crank of first rolling disc, first spout has been seted up to the right flank of second sliding plate, the inside wall and the surface sliding connection of head rod of first spout, the left surface fixedly connected with of second sliding plate is a set of first joint post of equidistance concentricity.

Further, lifting positioning mechanism includes spliced pole, third sliding plate, the top and the servo motor fixed connection of spliced pole, the screw thread chamber has been seted up to the bottom of spliced pole, the inside wall threaded connection in screw thread chamber has the screw thread post, the bottom fixedly connected with baffle of screw thread post, the lower surface fixedly connected with second connecting rod of baffle, the bottom fixedly connected with second rolling disc of second connecting rod, the lower surface rotation of second rolling disc is connected with the fixed plate.

Further, a group of equidistant concentric second clamping grooves are formed in the upper surface of the fixing plate, the lower surface of the fixing plate is fixedly connected with the upper surface of the second connecting plate, a second sliding groove is formed in the upper surface of the third sliding plate, the inner side wall of the second sliding groove is slidably connected with the outer surface of the second connecting rod, and a group of equidistant concentric second clamping columns are fixedly connected with the lower surface of the third sliding plate.

Compared with the prior art, the gear rotary mechanism of the steel slag ball mill has the following beneficial effects:

1. according to the utility model, through the cooperation of the movable positioning mechanism, the lifting positioning mechanism, the servo motor, the rotating rod, the first transmission gear, the first through hole, the second transmission gear and the reversing gear, the rotating speed of the reversing gear can be adjusted by replacing the first transmission gear and the second transmission gear, the problems that the rotating speed of a common steel slag ball mill cannot be adjusted by replacing the gears, and a large amount of energy sources are wasted due to the fact that the rotating speed can be adjusted only by adjusting the power of the servo motor are solved, and the high efficiency of the device is realized.

2. According to the utility model, the buffer mechanism is arranged, and the first sliding plate is driven to slide up and down in the buffer cavity under the elastic action of the elastic piece, so that the device is driven to swing up and down, and the purpose of efficiently counteracting impact force of the device is realized.

Drawings

FIG. 1 is a schematic perspective elevation view of the present utility model;

FIG. 2 is a perspective elevation view of a split view of the structure of the present utility model;

FIG. 3 is a perspective view showing the elevation positioning mechanism of the present utility model;

FIG. 4 is a perspective exploded view of the mobile positioning mechanism of the present utility model;

fig. 5 is a perspective exploded view of the buffer mechanism of the present utility model.

In the figure: the ball mill comprises a 1 supporting plate, a 2 buffering mechanism, a 201 buffering frame, a 202 buffering cavity, a 203 elastic piece, a 204 first sliding plate, a 205 supporting column, a 206 supporting disk, a 3 first connecting plate, a 4 moving positioning mechanism, a 401 sliding frame, a 402 sliding cavity, a 403 sliding block, a 404 threaded hole, a 405 second connecting plate, a 406 first clamping groove, a 407 second through hole, a 408 threaded rod, a 409 first connecting rod, a 410 second sliding plate, a 411 first sliding groove, a 412 first clamping column, a 413 first rotating disk, a 414 crank, a 5 lifting positioning mechanism, a 501 connecting column, a 502 threaded cavity, a 503 threaded column, a 504 baffle plate, a 505 second connecting rod, a 506 third sliding plate, a 507 second sliding groove, a 508 second clamping column, a 509 second rotating disk, a 510 fixed plate, a 511 second clamping groove, a 6 servo motor, a 7 rotating rod, a 8 first transmission gear, a 9 first through hole, a 10 second transmission gear, a 11 supporting leg, a 12 supporting support plate, a 13 roller and a 14 reversing gear.

Detailed Description

The principles and features of the present utility model are described below with reference to the drawings, the examples are illustrated for the purpose of illustrating the utility model and are not to be construed as limiting the scope of the utility model.

Referring to fig. 1 to 5, the gear rotary mechanism of the steel slag ball mill comprises a supporting plate 1, a first connecting plate 3, a servo motor 6 and a first transmission gear 8, wherein two groups of buffer mechanisms 2 which are symmetrical with each other are arranged above the supporting plate 1.

The buffer mechanism 2 comprises a buffer frame 201, the top end of the buffer frame 201 is fixedly connected with the lower surface of the first connecting plate 3, a buffer cavity 202 is formed in the bottom end of the buffer frame 201, an elastic piece 203 is fixedly connected to the inner top wall of the buffer cavity 202, and a first sliding plate 204 is fixedly connected to the bottom end of the elastic piece 203.

The elastic member 203 is preferably a spring, and the diameter of the supporting plate 206 is larger than the aperture of the buffer cavity 202.

The surface of first sliding plate 204 and the inside wall sliding connection of cushion chamber 202, the bottom fixedly connected with support column 205 of first sliding plate 204, the bottom fixedly connected with supporting disk 206 of support column 205, the lower surface of supporting disk 206 and the upper surface fixed connection of backup pad 1.

The elastic part 203 drives the first sliding plate 204 to slide up and down in the buffer cavity 202, so as to drive the device to swing up and down, thereby realizing the purpose of efficiently counteracting the impact force during the operation of the device.

A moving and positioning mechanism 4 is arranged above the first connecting plate 3.

The movable positioning mechanism 4 comprises a sliding frame 401 and a second sliding plate 410, wherein the lower surface of the sliding frame 401 is fixedly connected with the upper surface of the first connecting plate 3, a first clamping groove 406 is formed in the right end of the sliding frame 401, a group of second through holes 407 which are equidistant and concentric are formed in the right end of the sliding frame 401, a sliding cavity 402 is formed in the upper surface of the sliding frame 401, a sliding block 403 is slidably connected to the inner side wall of the sliding cavity 402, a second connecting plate 405 is fixedly connected to the upper surface of the sliding block 403, a threaded hole 404 is formed in the right end of the sliding block 403, and a threaded rod 408 is connected to the inner side wall of the threaded hole 404 in a threaded manner.

Where the bore diameter of the threaded bore 404 corresponds to the diameter of the threaded rod 408.

The left end of threaded rod 408 rotates with the inside wall of sliding chamber 402 to be connected, and the right-hand member of threaded rod 408 runs through first draw-in groove 406, and fixedly connected with head rod 409, and the right-hand member fixedly connected with first rolling disc 413 of head rod 409, the right flank fixedly connected with crank 414 of head rod 413, first spout 411 has been seted up to the right flank of second sliding plate 410, the inside wall of first spout 411 and the surface sliding connection of head rod 409, the left flank fixedly connected with of second sliding plate 410 a set of concentric first joint post 412 of equidistance.

The second through hole 407 is clamped with the first clamping post 412, where the first connecting rod 409 may be a triangular prism, a quadrangular prism, a pentagonal prism, or an eight-square prism, where a quadrangular prism is preferred, and the first sliding slot 411 may be a triangular hole, a tetragonal hole, a pentagonal hole, or an octagonal hole, where a tetragonal hole is preferred, and the crank 414 is fixedly connected to an edge of the right side surface of the first rotating disc 413.

Through rocking crank 414, and then drive first rotating disk 413 and rotate, drive threaded rod 408 simultaneously and rotate, thereby drive slider 403 and move about, drive second connecting plate 405 and move about simultaneously, drive servo motor 6 and move about simultaneously, drive first drive gear 8 and move about simultaneously, stop rocking crank 414 when first drive gear 8 moves to reversing gear 14 under, then control second sliding plate 410 slides left, and then drive first joint post 412 and move left, and make the inside of first joint post 412 insert second through hole 407, thereby realized the purpose of this device rapid movement and location.

A lifting positioning mechanism 5 is arranged above the moving positioning mechanism 4.

The lifting positioning mechanism 5 comprises a connecting column 501 and a third sliding plate 506, wherein the top end of the connecting column 501 is fixedly connected with the servo motor 6, a threaded cavity 502 is formed in the bottom end of the connecting column 501, a threaded column 503 is connected to the inner side wall of the threaded cavity 502 in a threaded mode, a baffle 504 is fixedly connected to the bottom end of the threaded column 503, a second connecting rod 505 is fixedly connected to the lower surface of the baffle 504, a second rotating disc 509 is fixedly connected to the bottom end of the second connecting rod 505, and a fixing plate 510 is rotatably connected to the lower surface of the second rotating disc 509.

Here, the diameter of the threaded cavity 502 is identical to the diameter of the threaded post 503, and here, the second connecting rod 505 may be a triangular prism, a quadrangular prism, a pentagonal prism, or an octagonal prism, and here, a quadrangular prism is preferable.

The upper surface of fixed plate 510 has seted up a set of concentric second draw-in groove 511 of equidistance, and the lower surface of fixed plate 510 is fixedly connected with the upper surface of second connecting plate 405, and the second spout 507 has been seted up to the upper surface of third sliding plate 506, and the inside wall and the surface sliding connection of second connecting rod 505 of second spout 507, the lower surface fixedly connected with of third sliding plate 506 a set of concentric second joint post 508 of equidistance.

The second clamping groove 511 and the second clamping post 508 are clamped with each other, and the second sliding groove 507 may be a triangular hole, a square hole, a pentagonal hole, or an octagonal hole, and is preferably a square hole.

Through rotating baffle 504, and then drive spliced pole 501 upward movement, drive servo motor 6 upward movement simultaneously, drive first drive gear 8 upward movement simultaneously, and make first drive gear 8 and reversing gear 14 meshing be connected, then control third sliding plate 506 and slide down, and then drive second joint post 508 downward movement, and make second joint post 508 insert the inside of second draw-in groove 511, realized the purpose of this device quick lift and location.

The output fixedly connected with dwang 7 of servo motor 6, first through-hole 9 has been seted up to the right flank of first drive gear 8, the surface of dwang 7 and the inside wall fixed connection of first through-hole 9, the left end fixedly connected with second drive gear 10 of dwang 7, the last fixedly connected with of first connecting plate 3 two sets of mutual symmetrical supporting legs 11, the equal fixedly connected with supporting plate 12 in top of two sets of supporting legs 11, the last cambered surface fixedly connected with ball mill cylinder 13 of supporting plate 12, the internally mounted of ball mill cylinder 13 has reversing gear 14, reversing gear 14's surface and the surface meshing of second drive gear 10 are connected.

The inner side wall of the counter gear 14 is fixedly connected with a rotating drum inside the ball mill drum 13.

Through starting servo motor 6, and then drive dwang 7 rotation, drive first drive gear 8 and second drive gear 10 rotation simultaneously to drive reversing gear 14 rotation, realized this device quick driven purpose.

When the device is used, the crank 414 is rocked firstly to drive the first rotating disc 413 to rotate, and the threaded rod 408 is driven to rotate, so that the sliding block 403 is driven to move left and right, the second connecting plate 405 is driven to move left and right, the servo motor 6 is driven to move left and right, the first transmission gear 8 is driven to move left and right, the crank 414 is stopped to be rocked when the first transmission gear 8 moves to the position right below the reversing gear 14, the second sliding plate 410 is controlled to slide left, the first clamping column 412 is driven to move left, and the first clamping column 412 is inserted into the second through hole 407, so that the device can move and fix rapidly;

then, the baffle 504 is rotated to drive the connecting column 501 to move upwards, and simultaneously drive the servo motor 6 to move upwards, and simultaneously drive the first transmission gear 8 to move upwards, and make the first transmission gear 8 and the reversing gear 14 mesh be connected, then control the third sliding plate 506 to slide downwards, and then drive the second joint post 508 to move downwards, and make the second joint post 508 insert the inside of the second draw-in groove 511, the purpose of quick lifting and positioning of this device is realized, the purpose of quick replacement of this device big or small gear is realized through the cooperation of the mobile positioning mechanism 4 and the lifting positioning mechanism 5, when this device operates, the elastic action through the elastic component 203 drives the first sliding plate 204 to slide up and down in the inside of the buffer chamber 202, and then drive this device to swing up and down, thereby the purpose of impact force when having realized high-efficient offset this device operation.

The foregoing description of the preferred embodiments of the utility model is not intended to limit the utility model to the precise form disclosed, and any such modifications, equivalents, and alternatives falling within the spirit and scope of the utility model are intended to be included within the scope of the utility model.

Claims (7)

1. The utility model provides a slag ball mill gear rotation mechanism, includes backup pad (1), first connecting plate (3), servo motor (6), first drive gear (8), its characterized in that: two groups of buffer mechanisms (2) which are symmetrical with each other are arranged above the supporting plate (1), a movable positioning mechanism (4) is arranged above the first connecting plate (3), a lifting positioning mechanism (5) is arranged above the movable positioning mechanism (4), the output end of the servo motor (6) is fixedly connected with a rotating rod (7), a first through hole (9) is formed in the right side face of the first transmission gear (8), the outer surface of the rotating rod (7) is fixedly connected with the inner side wall of the first through hole (9), the ball mill is characterized in that the left end of the rotating rod (7) is fixedly connected with a second transmission gear (10), the upper surface of the first connecting plate (3) is fixedly connected with two groups of mutually symmetrical supporting legs (11), the top ends of the supporting legs (11) are fixedly connected with supporting plates (12), the upper cambered surface of the supporting plates (12) is fixedly connected with a ball mill roller (13), the inner part of the ball mill roller (13) is provided with a reversing gear (14), and the outer surface of the reversing gear (14) is connected with the outer surface of the second transmission gear (10) in a meshed mode.

2. The gear wheel turning mechanism of a steel slag ball mill according to claim 1, wherein: the buffer mechanism (2) comprises a buffer frame (201), the top end of the buffer frame (201) is fixedly connected with the lower surface of the first connecting plate (3), a buffer cavity (202) is formed in the bottom end of the buffer frame (201), an elastic piece (203) is fixedly connected to the inner top wall of the buffer cavity (202), and a first sliding plate (204) is fixedly connected to the bottom end of the elastic piece (203).

3. The gear wheel turning mechanism of the steel slag ball mill according to claim 2, wherein: the outer surface of first sliding plate (204) and the inside wall sliding connection of cushion chamber (202), the bottom fixedly connected with support column (205) of first sliding plate (204), the bottom fixedly connected with supporting disk (206) of support column (205), the upper surface fixed connection of lower surface and backup pad (1) of supporting disk (206).

4. The gear wheel turning mechanism of a steel slag ball mill according to claim 1, wherein: the mobile positioning mechanism (4) comprises a sliding frame (401) and a second sliding plate (410), wherein the lower surface of the sliding frame (401) is fixedly connected with the upper surface of a first connecting plate (3), a first clamping groove (406) is formed in the right end of the sliding frame (401), a group of second through holes (407) which are equidistant and concentric are formed in the right end of the sliding frame (401), a sliding cavity (402) is formed in the upper surface of the sliding frame (401), a sliding block (403) is slidably connected to the inner side wall of the sliding cavity (402), a second connecting plate (405) is fixedly connected to the upper surface of the sliding block (403), a threaded hole (404) is formed in the right end of the sliding block (403), and a threaded rod (408) is connected to the inner side wall of the threaded hole (404).

5. The gear wheel turning mechanism of the steel slag ball mill according to claim 4, wherein: the left end of threaded rod (408) is rotated with the inside wall of sliding chamber (402) and is connected, the right-hand member of threaded rod (408) runs through first draw-in groove (406), and fixedly connected with head rod (409), the right-hand member fixedly connected with first rolling disc (413) of head rod (409), first spout (411) have been seted up to the right flank of first rolling disc (413), the inside wall of first spout (411) and the surface sliding connection of head rod (409), the first joint post (412) of a set of equidistance concentric of left surface fixedly connected with of second sliding plate (410).

6. The gear wheel turning mechanism of a steel slag ball mill according to claim 1, wherein: lifting positioning mechanism (5) are including spliced pole (501), third sliding plate (506), the top and the servo motor (6) fixed connection of spliced pole (501), screw thread chamber (502) have been seted up to the bottom of spliced pole (501), inside wall threaded connection in screw thread chamber (502) has screw thread post (503), the bottom fixedly connected with baffle (504) of screw thread post (503), the lower fixed surface of baffle (504) is connected with second connecting rod (505), the bottom fixedly connected with second rolling disc (509) of second connecting rod (505), the lower surface rotation of second rolling disc (509) is connected with fixed plate (510).

7. The gear wheel turning mechanism of the steel slag ball mill according to claim 6, wherein: a group of equidistant concentric second clamping grooves (511) are formed in the upper surface of the fixing plate (510), the lower surface of the fixing plate (510) is fixedly connected with the upper surface of the second connecting plate (405), a second sliding groove (507) is formed in the upper surface of the third sliding plate (506), the inner side wall of the second sliding groove (507) is in sliding connection with the outer surface of the second connecting rod (505), and a group of equidistant concentric second clamping columns (508) are fixedly connected with the lower surface of the third sliding plate (506).

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