CN112194070A - A canning closing device for feed additive production - Google Patents

Abstract

The invention discloses a canning sealing device for feed additive production, which comprises a conveying device for tank body movement, wherein a rotating device for rotating a tank body is arranged in the middle of the conveying device, an extruding device for extruding a tank cover seal is arranged on the rotating device, a grabbing device for grabbing a filling cover is arranged on one side of the rotating device, and a transferring device for driving the tank cover to move is arranged on one side of the grabbing device. According to the invention, through the arrangement of the extrusion sealing in the moving process of the tank body, the independent arrangement of a canning sealing device is avoided, and the production speed is accelerated; through the arrangement of the extrusion sealing in the moving process of the tank body, the existing filling conveying equipment is convenient to transform, and the cost is reduced; through the setting that multirow sealed simultaneously for production speed has improved production efficiency.

Description

A canning closing device for feed additive production

Technical Field

The invention relates to the technical field of feed additive production, in particular to a canning and sealing device for feed additive production.

Background

The feed additive is a small amount or trace substance added in the production, processing and using processes of feed, and the feed additive is small in dosage but remarkable in effect. The feed additive is a raw material inevitably used in modern feed industry, and has obvious effects on strengthening the nutritive value of basic feed, improving the production performance of animals, ensuring the health of the animals, saving the feed cost, improving the quality of animal products and the like. Generally, the product is sold and used by filling.

However, in the prior art, the canning and sealing devices for producing the feed additive are separately arranged, so that the following problems are caused: 1. the sealing can not be extruded in the moving process of the tank body, so that the production speed is reduced; 2. the existing filling and conveying equipment is not convenient to transform, and the cost is increased; 3. can only seal by a tank body, slows down the production speed and reduces the production efficiency.

Disclosure of Invention

The present invention is directed to solving the above problems and providing a can closure apparatus for use in feed additive production.

The invention realizes the purpose through the following technical scheme:

a canning sealing device for feed additive production comprises a conveying device for moving a tank body, wherein a rotating device for rotating the tank body is arranged in the middle of the conveying device, an extruding device for extruding a tank cover for sealing is arranged on the rotating device, a grabbing device for grabbing a canned cover is arranged on one side of the rotating device, and a transferring device for driving the tank cover to move is arranged on one side of the grabbing device; the conveying device comprises two symmetrically arranged transmission shafts, a first motor is arranged in front of each transmission shaft, two conveying wheels are symmetrically arranged at two ends of each transmission shaft, a conveying belt is arranged between the conveying wheels, a plurality of limiting plates are uniformly distributed between the conveying belts, a plurality of limiting grooves are uniformly distributed in the middles of the limiting plates, and a plurality of through holes are uniformly distributed at the bottoms of the limiting plates; the rotating device comprises a first support, two first support plates are symmetrically arranged in the first support from top to bottom, four first cylinders are uniformly distributed at four corners of each first support plate, a second motor is mounted on each first support plate, a large gear is mounted on each second motor, a plurality of small gears are uniformly distributed on one side of each large gear, and clamping rods are arranged on the small gears; the extrusion device comprises a second support, a plurality of second cylinders are symmetrically distributed at two ends of the second support, a second support plate is arranged in each second cylinder, and a forming wheel is arranged below each second support plate; the gripping device comprises a third support plate, two third cylinders are symmetrically mounted on the third support plate, a plurality of suckers are uniformly distributed below the third support plate, and pipe joints are mounted on the suckers.

Preferably: the transfer device comprises a third support, a lead screw and a sliding rod are mounted between the third supports, a third motor is mounted in front of the lead screw, and a fourth support plate is mounted below the lead screw.

According to the arrangement, the third support supports the third motor to drive the screw rod to rotate so as to push the fourth support plate to move along the sliding rod.

Preferably: the transfer device comprises a third support, a guide rail is installed between the third supports, a linear motor is arranged below the guide rail, and a fourth support plate is installed below the linear motor.

According to the arrangement, the third support supports the guide rail, and the linear motor drives the fourth support plate to move along the guide rail.

Preferably: the transmission shaft is respectively connected with the first motor and the conveying wheel through flat keys, and the limiting plate is riveted with the conveying belt.

So set up, the smooth transmission of power has been guaranteed in the parallel key connection, and the riveting has guaranteed the limiting plate is firm reliable.

Preferably: the first cylinder is respectively connected with the first bracket and the first supporting plate through bolts, and the second motor is connected with the first supporting plate through bolts.

So set up, bolted connection is convenient for dismouting maintenance first cylinder with the second motor.

Preferably: the second motor with the gear wheel parallel key is connected, the supporting rod with pinion bolted connection, the pinion with first backup pad bearing connects, the gear wheel with pinion meshing transmission.

So set up, guaranteed the second motor drive the gear wheel is rotatory to be engaged with the pinion drives the supporting rod is rotatory.

Preferably: the second support is respectively in bolted connection with the first support and the second cylinder, the second support plate is in bolted connection with the second cylinder, and the forming wheel is in bearing connection with the second support plate.

So set up, bolted connection is convenient for the dismouting the second extension board with the second cylinder is maintained, and bearing connection has guaranteed the shaping wheel is nimble rotatory.

Preferably: the third cylinder is respectively in bolted connection with the third support plate and the transfer device, the sucker is in bolted connection with the third support plate, and the pipe joint is in sealed threaded connection with the sucker.

So set up, bolted connection is convenient for the dismouting the third cylinder with the sucking disc is maintained, and sealed threaded connection has guaranteed the sealing of coupling.

Preferably: the screw rod is in threaded connection with the fourth support plate, the sliding rod is in sliding connection with the fourth support plate, and the third motor is in bolted connection with the third support.

According to the arrangement, the threaded connection is convenient for power transmission, the sliding connection ensures that the fourth support plate can move flexibly, and the bolt connection is convenient for disassembly, assembly and maintenance of the third motor.

Preferably: the guide rail is connected with the third support through a bolt, and the linear motor is connected with the third support plate through a bolt.

So set up, bolted connection is convenient for dismouting maintenance the guide rail with linear electric motor.

Compared with the prior art, the invention has the following beneficial effects:

1. by arranging the extrusion sealing in the moving process of the tank body, the independent arrangement of a canning sealing device is avoided, and the production speed is accelerated;

2. through the arrangement of the extrusion sealing in the moving process of the tank body, the existing filling conveying equipment is convenient to transform, and the cost is reduced;

3. through the setting that multirow sealed simultaneously for production speed has improved production efficiency.

Drawings

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

FIG. 1 is a schematic view of a can closure apparatus for feed additive production according to the present invention;

FIG. 2 is a front cross-sectional view of a can closure for feed additive production according to the present invention;

FIG. 3 is a schematic view of a conveyor for a can sealer for feed additive production according to the present invention;

FIG. 4 is a schematic view of a rotary apparatus of a can sealer for feed additive production according to the present invention;

FIG. 5 is a schematic view of an extrusion apparatus of a can sealer for feed additive production according to the present invention;

FIG. 6 is a schematic view of a gripping device of the can closure apparatus for feed additive production according to the present invention;

FIG. 7 is a schematic view of an embodiment 1 of a transfer device of a can closure for feed additive production according to the present invention;

fig. 8 is a schematic view of a transfer device of an embodiment 2 of the canning closure device for feed additive production according to the present invention.

The reference numerals are explained below:

1. a conveying device; 101. a drive shaft; 102. a delivery wheel; 103. a first motor; 104. a conveyor belt; 105. a limiting plate; 106. a limiting groove; 107. a through hole; 2. a rotating device; 201. a first bracket; 202. a first support plate; 203. a first cylinder; 204. a second motor; 205. a bull gear; 206. a pinion gear; 207. a clamping rod; 3. an extrusion device; 301. a second bracket; 302. a second cylinder; 303. a second support plate; 304. a forming wheel; 4. a gripping device; 401. a third support plate; 402. a suction cup; 403. a pipe joint; 404. a third cylinder; 5. a transfer device; 501. a third support; 502. a fourth support plate; 503. a lead screw; 504. a slide bar; 505. a third motor; 506. a linear motor; 507. a guide rail.

Detailed Description

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "up", "down", "front", "back", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on those shown in the drawings, and are used only for convenience in describing the present invention and for simplicity in description, and do not indicate or imply that the referenced devices or elements must have a particular orientation, be constructed and operated in a particular orientation, and thus, are not to be construed as limiting the present invention. Furthermore, the terms "first", "second", etc. are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first," "second," etc. may explicitly or implicitly include one or more of that feature. In the description of the present invention, "a plurality" means two or more unless otherwise specified.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood by those of ordinary skill in the art through specific situations.

The invention will be further described with reference to the accompanying drawings in which:

example 1

As shown in fig. 1-7, a can sealing device for feed additive production comprises a conveying device 1 for moving a can body, a rotating device 2 for rotating the can body is arranged in the middle of the conveying device 1, an extruding device 3 for extruding a can cover seal is arranged on the rotating device 2, a gripping device 4 for gripping a filled cover is arranged on one side of the rotating device 2, and a transferring device 5 for driving the can cover to move is arranged on one side of the gripping device 4; the conveying device 1 comprises two symmetrically arranged transmission shafts 101, a first motor 103 is installed in front of the transmission shafts 101, two conveying wheels 102 are symmetrically arranged at two ends of the transmission shafts 101, conveying belts 104 are installed between the conveying wheels 102, a plurality of limiting plates 105 are uniformly distributed between the conveying belts 104, a plurality of limiting grooves 106 are uniformly distributed in the middle of the limiting plates 105, and a plurality of through holes 107 are uniformly distributed at the bottoms of the limiting plates 105; the rotating device 2 comprises a first support 201, two first support plates 202 are symmetrically arranged in the first support 201 from top to bottom, four first cylinders 203 are uniformly distributed at four corners of each first support plate 202, a second motor 204 is mounted on each first support plate 202, a large gear 205 is mounted on each second motor 204, a plurality of small gears 206 are uniformly distributed on one side of each large gear 205, and clamping rods 207 are arranged on the small gears 206; the extrusion device 3 comprises a second bracket 301, a plurality of second cylinders 302 are symmetrically distributed at two ends of the second bracket 301, a second support plate 303 is installed in the second cylinders 302, and a forming wheel 304 is installed below the second support plate 303; the gripping device 4 comprises a third support plate 401, two third cylinders 404 are symmetrically mounted on the third support plate 401, a plurality of suckers 402 are uniformly distributed below the third support plate 401, and pipe joints 403 are mounted on the suckers 402.

Preferably: the transfer device 5 comprises a third bracket 501, a lead screw 503 and a slide bar 504 are arranged between the third bracket 501, a third motor 505 is arranged in front of the lead screw 503, a fourth support plate 502 is arranged below the lead screw 503, and the third bracket 501 supports the third motor 505 to drive the lead screw 503 to rotate and push the fourth support plate 502 to move along the slide bar 504; the transmission shaft 101 is respectively in flat key connection with the first motor 103 and the conveying wheel 102, the limiting plate 105 is riveted with the conveying belt 104, the flat key connection ensures stable transmission of power, and riveting ensures that the limiting plate 105 is stable and reliable; the first cylinder 203 is respectively in bolted connection with the first bracket 201 and the first supporting plate 202, and the second motor 204 is in bolted connection with the first supporting plate 202, so that the first cylinder 203 and the second motor 204 can be conveniently dismounted, mounted and maintained through the bolted connection; the second motor 204 is in flat key connection with the large gear 205, the clamping rod 207 is in bolt connection with the small gear 206, the small gear 206 is in bearing connection with the first supporting plate 202, and the large gear 205 and the small gear 206 are in meshing transmission, so that the second motor 204 is ensured to drive the large gear 205 to rotate and mesh the small gear 206 to drive the clamping rod 207 to rotate; the second bracket 301 is respectively in bolted connection with the first bracket 201 and the second cylinder 302, the second support plate 303 is in bolted connection with the second cylinder 302, and the forming wheel 304 is in bearing connection with the second support plate 303, so that the second support plate 303 and the second cylinder 302 can be conveniently dismounted and mounted for maintenance through the bolted connection, and the bearing connection ensures that the forming wheel 304 can flexibly rotate; the third cylinder 404 is respectively in bolted connection with the third support plate 401 and the transfer device 5, the sucker 402 is in bolted connection with the third support plate 401, the pipe joint 403 is in sealed threaded connection with the sucker 402, the third cylinder 404 and the sucker 402 can be conveniently dismounted and mounted for maintenance through the bolted connection, and the sealed threaded connection ensures the sealing of the pipe joint 403; the screw 503 is in threaded connection with the fourth support plate 502, the slide rod 504 is in sliding connection with the fourth support plate 502, and the third motor 505 is in bolted connection with the third support 501, the threaded connection facilitates power transmission, the sliding connection ensures that the fourth support plate 502 can move flexibly, and the bolted connection facilitates disassembly, assembly and maintenance of the third motor 505.

Example 2

As shown in fig. 8, embodiment 2 differs from embodiment 1 in that: the transfer device 5 comprises a third bracket 501, a guide rail 507 is arranged between the third brackets 501, a linear motor 506 is arranged below the guide rail 507, a fourth support plate 502 is arranged below the linear motor 506, the third bracket 501 supports the guide rail 507, and the linear motor 506 drives the fourth support plate 502 to move along the guide rail 507; the guide rail 507 is connected with the third support 501 through bolts, and the linear motor 506 is connected with the third support plate 401 through bolts, so that the guide rail 507 and the linear motor 506 can be conveniently dismounted, repaired and connected through the bolts.

The working principle is as follows: inserting the can body into the limiting groove 106 of the limiting plate 105, the first motor 103 drives the transmission shaft 101 to drive the transmission wheel 102 to rotate, the transmission wheel 102 drives the limiting plate 105 and the can body to move through the transmission belt 104, the third cylinder 404 first presses down the third support plate 401 to enable the suction cup 402 to grasp the can cover through vacuum suction, then the third support 501 supports the third motor 505 to drive the lead screw 503 to rotate and push the fourth support plate 502 to move along the slide bar 504, or the third support 501 supports the guide rail 507, the linear motor 506 drives the fourth support plate 502 to move along the guide rail 507 to enable the fourth support plate 502 to move the can cover to the upper part of the can body, the third cylinder 404 presses down the third support plate 401 again to enable the suction cup 402 to place the can cover on the can body, the first support 201 supports the first cylinder 203 to extend to push the first support plate 202 to support the clamping rod 207 to clamp the can cover and the can body from top to bottom, the second motor 204 drives the pinion 205, the second cylinder 302 pushes the forming wheel 304 to press the can lid to close the can body through the second support plate 303.

The foregoing illustrates and describes the principles, general features, and advantages of the present invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are described in the specification and illustrated only to illustrate the principle of the present invention, but that various changes and modifications may be made therein without departing from the spirit and scope of the present invention, which fall within the scope of the invention as claimed.

Claims (10)

1. A canning closing device for feed additive production which characterized in that: the tank cover sealing device comprises a conveying device (1) used for moving a tank body, wherein a rotating device (2) used for rotating the tank body is arranged in the middle of the conveying device (1), an extruding device (3) used for extruding a tank cover seal is arranged on the rotating device (2), a grabbing device (4) used for grabbing a filled cover is arranged on one side of the rotating device (2), and a transferring device (5) used for driving the tank cover to move is arranged on one side of the grabbing device (4);

the conveying device (1) comprises two symmetrically arranged transmission shafts (101), a first motor (103) is installed in front of the transmission shafts (101), two conveying wheels (102) are symmetrically arranged at two ends of each transmission shaft (101), a conveying belt (104) is installed between the conveying wheels (102), a plurality of limiting plates (105) are uniformly distributed among the conveying belts (104), a plurality of limiting grooves (106) are uniformly distributed in the middles of the limiting plates (105), and a plurality of through holes (107) are uniformly distributed at the bottoms of the limiting plates (105);

the rotating device (2) comprises a first support (201), two first support plates (202) are symmetrically arranged in the first support (201) from top to bottom, four first cylinders (203) are uniformly distributed at four corners of each first support plate (202), a second motor (204) is mounted on each first support plate (202), a large gear (205) is mounted on each second motor (204), a plurality of small gears (206) are uniformly distributed on one side of each large gear (205), and clamping rods (207) are arranged on the small gears (206);

the extrusion device (3) comprises a second support (301), a plurality of second cylinders (302) are symmetrically distributed at two ends of the second support (301), a second support plate (303) is installed in each second cylinder (302), and a forming wheel (304) is installed below each second support plate (303);

the gripping device (4) comprises a third support plate (401), two third air cylinders (404) are symmetrically mounted on the third support plate (401), a plurality of suckers (402) are uniformly distributed below the third support plate (401), and pipe joints (403) are mounted on the suckers (402).

2. The can closure apparatus for feed additive production of claim 1, wherein: the transfer device (5) comprises third supports (501), a lead screw (503) and a sliding rod (504) are mounted between the third supports (501), a third motor (505) is mounted in front of the lead screw (503), and a fourth support plate (502) is mounted below the lead screw (503).

3. The can closure apparatus for feed additive production of claim 1, wherein: the transfer device (5) comprises third supports (501), guide rails (507) are installed between the third supports (501), linear motors (506) are arranged below the guide rails (507), and fourth support plates (502) are installed below the linear motors (506).

4. The can closure apparatus for feed additive production of claim 1, wherein: the transmission shaft (101) is respectively in flat key connection with the first motor (103) and the conveying wheel (102), and the limiting plate (105) is riveted with the conveying belt (104).

5. The can closure apparatus for feed additive production of claim 1, wherein: the first cylinder (203) is respectively in bolted connection with the first bracket (201) and the first support plate (202), and the second motor (204) is in bolted connection with the first support plate (202).

6. The can closure apparatus for feed additive production of claim 1, wherein: the second motor (204) is in flat key connection with the large gear (205), the clamping rod (207) is in bolt connection with the small gear (206), the small gear (206) is in bearing connection with the first support plate (202), and the large gear (205) and the small gear (206) are in meshing transmission.

7. The can closure apparatus for feed additive production of claim 1, wherein: the second bracket (301) is respectively in bolted connection with the first bracket (201) and the second cylinder (302), the second support plate (303) is in bolted connection with the second cylinder (302), and the forming wheel (304) is in bearing connection with the second support plate (303).

8. The can closure apparatus for feed additive production of claim 1, wherein: the third air cylinder (404) is respectively connected with the third support plate (401) and the transfer device (5) through bolts, the suction cup (402) is connected with the third support plate (401) through bolts, and the pipe joint (403) is connected with the suction cup (402) through sealing threads.

9. The can closure apparatus for feed additive production of claim 2, wherein: the lead screw (503) is in threaded connection with the fourth support plate (502), the sliding rod (504) is in sliding connection with the fourth support plate (502), and the third motor (505) is in bolted connection with the third support (501).

10. The can closure for feed additive production of claim 3, wherein: the guide rail (507) is connected with the third bracket (501) through bolts, and the linear motor (506) is connected with the third support plate (401) through bolts.

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