阅读说明：本技术 一种自动罐装的饲料机 (Automatic canned feed machine ) 是由 李�杰 于 2020-06-15 设计创作，主要内容包括：本发明公开了一种自动罐装的饲料机,包括机壳,所述机壳内设有机腔,所述机腔左内壁固定设有碎料块,所述碎料块内设有将其上下贯穿且连通外部及所述机腔的碎料腔,所述碎料腔内设有碎料机构,所述机腔下侧设有输送机构,所述机腔右侧设有封盖机构,所述输送机构上侧设有推出机构,所述推出机构包括位于所述机腔后内壁固定连接的推出块,所述推出块内设有开口向前且连通所述机腔的推出腔,该发明结构简单,操作便捷,在需要自动罐装时,只需要事先将饲料的原材料放入碎料腔内,便可通过机械传动完成自动罐装,当需要对饲料罐封盖时,通过机械传动可以实现自动封盖,通过机械传动还可以实现对加工好的饲料罐头自动取出,从而减轻工人的工作量。(The invention discloses an automatic canned feed machine, which comprises a machine shell, wherein a machine cavity is arranged in the machine shell, a crushed material block is fixedly arranged on the left inner wall of the machine cavity, a crushed material cavity which penetrates through the crushed material block from top to bottom and is communicated with the outside and the machine cavity is arranged in the crushed material cavity, a crushed material mechanism is arranged in the crushed material cavity, a conveying mechanism is arranged on the lower side of the machine cavity, a sealing cover mechanism is arranged on the right side of the machine cavity, a push-out mechanism is arranged on the upper side of the conveying mechanism, the push-out mechanism comprises a push-out block fixedly connected with the rear inner wall of the machine cavity, and a push-out cavity with a forward opening and communicated with the machine cavity is arranged in the push-out block. The processed canned feed can be automatically taken out through mechanical transmission, so that the workload of workers is reduced.)

1. The utility model provides an automatic canned feed machine, includes the casing, its characterized in that: a machine cavity is arranged in the machine shell, a crushed material block is fixedly arranged on the left inner wall of the machine cavity, a crushed material cavity which penetrates through the crushed material block from top to bottom and is communicated with the outside and the machine cavity is arranged in the crushed material block, a crushed material mechanism is arranged in the crushed material cavity, a conveying mechanism is arranged on the lower side of the machine cavity, a sealing cover mechanism is arranged on the right side of the machine cavity, a pushing mechanism is arranged on the upper side of the conveying mechanism and comprises a pushing block fixedly connected with the rear inner wall of the machine cavity, a pushing cavity with a forward opening and communicated with the machine cavity is arranged in the pushing block, a driving block and a driven block which are distributed front and back are connected in a sliding manner in the pushing cavity, a driving spring fixedly connected with the rear end of the driving block is fixedly connected with the rear inner wall of the pushing cavity, a power rope is fixedly connected with the front end of the driving, the left and right inner walls of the push-out cavity are provided with a driving cavity with bilaterally symmetrical openings towards the center of the push-out cavity and a driven cavity with bilaterally symmetrical openings at the front side of the driving cavity towards the center of the push-out cavity, a driving clamping block with one end positioned in the push-out cavity is connected in a sliding manner in the driving cavity, a clamping spring fixedly connected with the driving clamping block at the end far away from the center of the push-out cavity is fixedly connected on the inner wall of the driving cavity at the center far away from the center of the push-out cavity, a clamping rope is fixedly connected with the driving clamping block at the end far away from the center of the push-out cavity, a driven clamping block with one end positioned in the push-out cavity is connected in a sliding manner in the driven cavity, a clamping spring fixedly connected with the driven clamping block at the end far, the inner wall is equipped with to run through before the machine chamber the casing just communicates outside taking out the chamber.

2. An automatic canned feed machine as claimed in claim 1, characterised in that: the sealing mechanism comprises a sealing block fixedly arranged on the upper side of the right inner wall of the machine cavity, a sealing cavity with an upward opening and communicated with the outside is arranged in the sealing block, a bottle cap is arranged in the sealing cavity in a sliding manner, an ejection cavity with an opening towards the crushing mechanism and communicated with the machine cavity is arranged on the right inner wall of the sealing cavity, an ejection block is connected in the ejection cavity in a sliding manner, the right inner wall of the ejection cavity is fixedly connected with an ejection spring fixedly connected with the right end of the ejection block, the right end of the ejection block is fixedly connected with an ejection rope, a lower pressing block is fixedly arranged on the upper inner wall of the machine cavity, a lower pressing cavity with a downward opening and communicated with the machine cavity is arranged in the lower pressing block, a lower pressing slide block with the lower end positioned in the machine cavity is connected in a sliding manner in the lower pressing cavity, and a lower pressing spring fixedly connected with the upper end of the lower pressing slide, push down slider upper end fixedly connected with push down the rope the other end of power rope, the fixed piece that moves to the right that is equipped with of machine intracavity right side inner wall, be equipped with the opening left and communicate in the right side moves the chamber to the right side in the machine intracavity, move intracavity sliding connection on the right side and be located the slider is moved to the right side in the machine intracavity, move intracavity right side inner wall fixedly connected with move slider right-hand member fixed connection's the right side on the right side and move the spring, move slider right-hand member fixedly connected with brake rope, two press from both sides tight rope the other end of ejecting rope to the right side.

3. An automatic canned feed machine as claimed in claim 2, characterised in that: the conveying mechanism comprises a rotating cavity, wherein the left inner wall of the machine cavity is provided with a right opening and is communicated with the machine cavity, a rotating block is connected in the rotating cavity in a sliding manner, the right end of the rotating block is fixedly provided with a rotating shaft, the right end of the rotating shaft is positioned in the machine cavity, a rotating gear and a rotating bevel gear are fixedly arranged in the rotating shaft, the front inner wall and the rear inner wall of the machine cavity are rotatably provided with a rotating shaft, a linkage shaft and a driving shaft which are distributed on the left and right in the same horizontal plane, the rotating shaft is fixedly provided with a power gear, a rotating gear and a rotating bevel gear, the rotating bevel gear is meshed with the rotating bevel gear, the driving shaft is fixedly connected with a driving gear, the rotating gear and the driving gear are in power fit connection through a conveying belt, the rear inner wall of the machine cavity is fixedly provided with a linkage block, the linkage cavity is provided with a forward opening, linkage chamber rear wall fixedly connected with linkage slider rear end fixed connection's linkage spring, linkage slider rear end fixedly connected with the other end of braking rope, be equipped with the opening and communicate left in the linkage slider the gear chamber in machine chamber, be equipped with the torsional spring chamber that the opening is backward in the universal driving shaft, the fixed rear end that is equipped with of inner wall before the torsional spring chamber with the braking torsional spring of machine chamber rear wall fixed connection, splined connection has the linkage gear on the universal driving shaft, the linkage gear right-hand member is located gear intracavity and sliding connection with it.

4. An automatic canned feed machine as claimed in claim 3, characterised in that: the crushing mechanism comprises a motor block fixedly arranged on the left inner wall of the crushing cavity, a motor cavity is arranged in the motor block, two synchronous motors which are distributed front and back and rotate in opposite directions are fixedly arranged on the left inner wall of the motor cavity, the right ends of the two synchronous motors are both in power connection with driving shafts, driving gears and crushing gears which are positioned in the motor cavity and are meshed with each other are fixedly arranged on the two driving shafts, two driven shafts which penetrate through the motor cavity and the crushing cavity are rotatably connected on the left inner wall of the motor cavity and the right inner wall of the crushing cavity, driven gears and shaping gears which are positioned in the motor cavity and are meshed with the driving gears are fixedly arranged on the two driven shafts, a braking gear which is positioned in the motor cavity is fixedly arranged on the driven shaft on the front side, an upper inner wall which is arranged on the lower inner wall of the motor cavity is communicated with a belt cavity of which the, the brake gear with the running gear is connected by driving belt power fit, the piece is deposited to fixed being equipped with on the inner wall behind the machine chamber, it upwards just communicates to be equipped with the opening in the piece to deposit the chamber of machine chamber, it has a jar body and slurcam to deposit intracavity sliding connection, deposit chamber back inner wall fixedly connected with slurcam rear end fixed connection's the spring of depositing, deposit under the chamber inner wall be equipped with run through from top to bottom deposit the piece and with deposit the rotatory chamber of chamber, machine chamber intercommunication, the inner wall all rotates around the rotatory chamber and is connected with the clamping shaft, the clamping shaft about both ends with the end wall is by clamping torsional spring fixed connection about the rotatory chamber, fixedly connected with clamping plate in the clamping shaft, clamping plate lower extreme fixedly connected with the other end of clamping rope.

5. An automatic canned feed machine as claimed in claim 4, characterised in that: the elasticity of the spring that moves to the right side is greater than ejecting spring's elasticity linkage spring's elasticity and two clamping spring's elasticity with, clamping spring's elasticity is greater than the torsion of card dynamic torsion spring, the gravity behind the feed is filled to the jar body is greater than two clamping spring's elasticity and two the torsion of card dynamic torsion spring with, the torsion of braking torsion spring is greater than push down spring's elasticity, push down the slider can with the bottle lid is inhaled mutually, jar body upside outer wall be equipped with the arcwall face can with the bottle lid blocks mutually.

Technical Field

The invention relates to the field of biological feed, in particular to an automatic canned feed machine.

Background

The feed machine can be used in the process of taking care of processing the feed, the feed machine can well process the feed, when the feed is processed, workers are required to manually pot the feed, and after the pot filling is completed, the workers are required to manually seal the feed pot.

At the present stage, canning and capping are both manually operated by workers, so that the phenomenon of tedious canning and capping processes is avoided, a large amount of physical strength of the workers is consumed, and the workload of the workers is increased.

Disclosure of Invention

The invention aims to solve the technical problem of providing a feed machine capable of automatically canning and sealing, solving the problems that the automatic canning and the automatic sealing of the feed tank cannot be realized, and the like, and increasing the functions of automatic canning and the automatic sealing of the feed tank.

The invention is realized by the following technical scheme.

The invention relates to an automatic canned feed machine, which comprises a machine shell, wherein a machine cavity is arranged in the machine shell, a crushed material block is fixedly arranged on the left inner wall of the machine cavity, a crushed material cavity which penetrates through the crushed material block from top to bottom and is communicated with the outside and the machine cavity is arranged in the crushed material cavity, a crushing mechanism is arranged in the crushed material cavity, a conveying mechanism is arranged on the lower side of the machine cavity, a sealing cover mechanism is arranged on the right side of the machine cavity, a push-out mechanism is arranged on the upper side of the conveying mechanism, the push-out mechanism comprises a push-out block fixedly connected with the rear inner wall of the machine cavity, a push-out cavity with a forward opening and communicated with the machine cavity is arranged in the push-out cavity, a driving block and a driven block which are distributed front and back are connected in a sliding manner in the push-out cavity, a driving spring fixedly connected with the rear end of the driving block is fixedly connected with the rear inner wall of the, the left and right inner walls of the push-out cavity are provided with a driving cavity with bilaterally symmetrical openings towards the center of the push-out cavity and a driven cavity with bilaterally symmetrical openings at the front side of the driving cavity towards the center of the push-out cavity, a driving clamping block with one end positioned in the push-out cavity is connected in a sliding manner in the driving cavity, a clamping spring fixedly connected with the driving clamping block at the end far away from the center of the push-out cavity is fixedly connected on the inner wall of the driving cavity at the center far away from the center of the push-out cavity, a clamping rope is fixedly connected with the driving clamping block at the end far away from the center of the push-out cavity, a driven clamping block with one end positioned in the push-out cavity is connected in a sliding manner in the driven cavity, a clamping spring fixedly connected with the driven clamping block at the end far, the inner wall is equipped with to run through before the machine chamber the casing just communicates outside taking out the chamber.

Further, the sealing mechanism comprises a sealing block fixedly arranged on the upper side of the right inner wall of the machine cavity, a sealing cavity with an upward opening and communicated with the outside is arranged in the sealing block, a bottle cap is arranged in the sealing cavity in a sliding manner, an ejection cavity with an opening towards the crushing mechanism and communicated with the machine cavity is arranged on the right inner wall of the sealing cavity, an ejection block is connected in the ejection cavity in a sliding manner, an ejection spring fixedly connected with the right end of the ejection block is fixedly connected to the right inner wall of the ejection cavity, an ejection rope is fixedly connected to the right end of the ejection block, a lower pressing block is fixedly arranged on the upper inner wall of the machine cavity, a lower pressing cavity with a downward opening and communicated with the machine cavity is arranged in the lower pressing block, a lower pressing slide block with the lower end positioned in the machine cavity is connected in the lower pressing cavity in a sliding manner, and a lower pressing spring fixedly connected with the upper end of the lower pressing slide block is, push down slider upper end fixedly connected with push down the rope the other end of power rope, the fixed piece that moves to the right that is equipped with of machine intracavity right side inner wall, be equipped with the opening left and communicate in the right side moves the chamber to the right side in the machine intracavity, move intracavity sliding connection on the right side and be located the slider is moved to the right side in the machine intracavity, move intracavity right side inner wall fixedly connected with move slider right-hand member fixed connection's the right side on the right side and move the spring, move slider right-hand member fixedly connected with brake rope, two press from both sides tight rope the other end of ejecting rope to the right side.

Further, the conveying mechanism comprises a rotating cavity which is provided with a right opening and communicated with the machine cavity, the left inner wall of the machine cavity is provided with the rotating cavity, the rotating cavity is internally connected with a rotating block in a sliding manner, the right end of the rotating block is fixedly provided with a rotating shaft, the right end of the rotating shaft is positioned in the machine cavity, a rotating gear and a rotating bevel gear are fixedly arranged in the rotating shaft, the front inner wall and the rear inner wall of the machine cavity are rotatably provided with a rotating shaft, a linkage shaft and a driving shaft which are distributed on the left and the right in the same horizontal plane, the rotating shaft is fixedly provided with a power gear, a rotating gear and a rotating bevel gear, the rotating bevel gear is meshed with the rotating bevel gear, the driving shaft is fixedly connected with a driving gear, the rotating gear and the driving gear are connected by a conveying belt in a power matching manner, the rear, linkage intracavity sliding connection has the front end to be located the linkage slider of quick-witted intracavity, linkage intracavity rear wall fixedly connected with linkage slider rear end fixed connection's linkage spring, linkage slider rear end fixed connection has the other end of braking rope, be equipped with opening and intercommunication left in the linkage slider the gear chamber in quick-witted chamber, be equipped with the torsional spring chamber that the opening is backward in the universal driving shaft, the fixed rear end that is equipped with of torsional spring chamber front inner wall with quick-witted chamber rear wall fixed connection's braking torsional spring, splined connection has the linkage gear on the universal driving shaft, the linkage gear right-hand member is located gear intracavity and sliding connection with it.

Further, the crushing mechanism comprises a motor block fixedly arranged on the left inner wall of the crushing cavity, a motor cavity is arranged in the motor block, two synchronous motors which are distributed in the front and back direction and rotate in opposite directions are fixedly arranged on the left inner wall of the motor cavity, the right ends of the two synchronous motors are both in power connection with driving shafts, driving gears and crushing gears which are positioned in the motor cavity and are meshed with each other are fixedly arranged on the two driving shafts, two driven shafts which penetrate through the motor cavity and the crushing cavity are rotatably connected on the left inner wall of the motor cavity and the right inner wall of the crushing cavity, driven gears and shaping gears which are positioned in the motor cavity and are meshed with the driving gears are fixedly arranged on the two driven shafts, a braking gear which is positioned in the motor cavity is fixedly arranged on the front driven shaft, an upper inner wall which is arranged on the lower inner wall of the motor cavity is communicated with a belt cavity of which is communicated with, the brake gear with the running gear is connected by driving belt power fit, the piece is deposited to fixed being equipped with on the inner wall behind the machine chamber, it upwards just communicates to be equipped with the opening in the piece to deposit the chamber of machine chamber, it has a jar body and slurcam to deposit intracavity sliding connection, deposit chamber back inner wall fixedly connected with slurcam rear end fixed connection's the spring of depositing, deposit under the chamber inner wall be equipped with run through from top to bottom deposit the piece and with deposit the rotatory chamber of chamber, machine chamber intercommunication, the inner wall all rotates around the rotatory chamber and is connected with the clamping shaft, the clamping shaft about both ends with the end wall is by clamping torsional spring fixed connection about the rotatory chamber, fixedly connected with clamping plate in the clamping shaft, clamping plate lower extreme fixedly connected with the other end of clamping rope.

Further, the elasticity of the spring that moves to the right is greater than ejecting spring's elasticity the elasticity and two of linkage spring clamping spring's elasticity with, chucking spring's elasticity is greater than the torsion of chucking torsional spring, the gravity behind the feed is filled to the jar body is greater than two chucking spring's elasticity and two chucking spring's torsion with, the torsion of braking torsional spring is greater than push down spring's elasticity, push down the slider can with the bottle lid is inhaled mutually, jar body upside outer wall be equipped with the arcwall face can with the bottle lid blocks mutually.

The invention has the beneficial effects that: the automatic canning machine is simple in structure and convenient and fast to operate, when automatic canning is needed, only raw materials of feed need to be put into the crushed material cavity in advance, automatic canning can be completed through mechanical transmission, when the feed tank needs to be capped, automatic capping can be achieved through mechanical transmission, and processed feed cans can be automatically taken out through mechanical transmission, so that the workload of workers is reduced.

Drawings

In order to more clearly illustrate the embodiments of the 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 invention, and it is obvious for those skilled in the art that other drawings can be obtained based on these drawings without creative efforts.

FIG. 1 is a schematic structural diagram of an embodiment of the present invention;

FIG. 2 is a schematic structural diagram at A-A in FIG. 1 according to an embodiment of the present invention;

FIG. 3 is a schematic structural diagram at B-B in FIG. 1 according to an embodiment of the present invention;

FIG. 4 is a schematic structural diagram at C-C in FIG. 1 according to an embodiment of the present invention;

fig. 5 is a schematic structural diagram at D in fig. 2 according to an embodiment of the present invention.

Detailed Description

The invention will now be described in detail with reference to fig. 1-4, wherein for ease of description the orientations described hereinafter are now defined as follows: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

The feed machine capable of being automatically canned, which is described with reference to fig. 1-4, comprises a casing 10, a machine cavity 96 is arranged in the casing 10, a crushed material block 11 is fixedly arranged on the left inner wall of the machine cavity 96, a crushed material cavity 12 which penetrates through the crushed material block 11 from top to bottom and is communicated with the outside and the machine cavity 96 is arranged in the crushed material cavity 12, a crushed material mechanism 92 is arranged in the crushed material cavity 12, a conveying mechanism 93 is arranged on the lower side of the machine cavity 96, a cover sealing mechanism 94 is arranged on the right side of the machine cavity 96, a push-out mechanism 95 is arranged on the upper side of the conveying mechanism 93, the push-out mechanism 95 comprises a push-out block 62 which is fixedly connected with the rear inner wall of the machine cavity 96, a push-out cavity 64 which is provided with a forward opening and is communicated with the machine cavity 96 is arranged in the push-out cavity 64, a driving block 65 and a driven block 48 which are distributed forward and backward are, the front end of the driving block 65 is fixedly connected with a power rope 33, the front end of the driving block 65 is fixedly connected with a driven spring 73 fixedly connected with the rear end of the driven block 48, the left and right inner walls of the push-out cavity 64 are provided with a driving cavity 67 with bilateral symmetry openings towards the center of the push-out cavity 64 and a driven cavity 70 with bilateral symmetry openings towards the center of the push-out cavity 64, the driving cavity 67 is internally and slidably connected with a driving clamping block 66 with one end positioned in the push-out cavity 64, the inner wall of the driving cavity 67 far away from the center of the push-out cavity 64 is fixedly connected with a clamping spring 69 fixedly connected with the driving clamping block 66 far away from the center of the push-out cavity 64, the driving clamping block 66 far away from the center of the push-out cavity 64 is fixedly connected with a clamping rope 68, and the driven clamping block 74 with one end positioned in the push-out, the inner wall of the driven cavity 70 far away from the center of the push-out cavity 64 is fixedly connected with a clamping spring 72 fixedly connected with the driven fixture block 74 far away from the center of the push-out cavity 64, the driven fixture block 74 far away from the center of the push-out cavity 64 is fixedly connected with a clamping rope 42, and the front inner wall of the machine cavity 96 is provided with a taking-out cavity 91 penetrating through the machine shell 10 and communicated with the outside.

Beneficially, the cover closing mechanism 94 includes a cover closing block 36 fixedly arranged on the upper side of the right inner wall of the machine cavity 96, a cover closing cavity 35 with an opening facing upward and penetrating through the upper end of the machine shell 10 and communicating with the outside is arranged in the cover closing block 36, 13 bottle caps 34 are slidably arranged in the cover closing cavity 35, an ejection cavity 37 with an opening facing the crushing mechanism 92 and communicating with the machine cavity 96 is arranged on the right inner wall of the cover closing cavity 35, an ejection block 38 is slidably connected in the ejection cavity 37, an ejection spring 39 fixedly connected with the right end of the ejection block 38 is fixedly connected to the right inner wall of the ejection cavity 38, an ejection rope 40 is fixedly connected to the right end of the ejection block 38, a lower pressing block 29 is fixedly arranged on the upper inner wall of the machine cavity 96, a lower pressing cavity 30 with an opening facing downward and communicating with the machine cavity 96 is arranged in the lower pressing block 29, a lower pressing slider 31 with a lower end positioned in the machine cavity, inner wall fixedly connected with push down 31 upper end fixed connection's push down spring 32 on the chamber 30 down, push down 31 upper end fixedly connected with push down rope 50 slider 33's the other end, the fixed block 97 that moves to the right that is equipped with of quick-witted chamber 96, it just communicates to be equipped with the opening left in the block 97 to move to the right the chamber 45 is moved to the right of quick-witted chamber 96, it is located to move the right sliding connection right-hand member in the chamber 45 to move to the right side slider 46 that moves in the quick-witted chamber 96 to move to the right side, move the chamber 45 right side inner wall fixedly connected with move the right side spring 43 that moves slider 46 right-hand member fixed connection to the right side, move slider 46 right-hand member fixedly connected with brake rope 41, two press from both sides tight rope 42 the.

Beneficially, the conveying mechanism 93 includes a rotating cavity 57 with a right opening on the left inner wall of the machine cavity 96 and communicated with the machine cavity 96, a rotating block 55 is slidably connected in the rotating cavity 57, a rotating shaft 54 with a right end located in the machine cavity 96 is fixedly arranged at the right end of the rotating block 55, a rotating gear 53 and a rotating bevel gear 52 are fixedly arranged in the rotating shaft 54, a rotating shaft 51, a linkage shaft 84 and a driving shaft 44 which are distributed on the same horizontal plane in a left-right direction are rotatably arranged on the front inner wall and the rear inner wall of the machine cavity 96, a power gear 59, a rotating gear 56 and a rotating bevel gear 58 are fixedly arranged on the rotating shaft 51, the rotating bevel gear 58 is meshed with the rotating bevel gear 52, a driving gear 75 is fixedly connected on the driving shaft 44, the rotating gear 56 and the driving gear 75 are connected by a conveying belt 47 in a power fit manner, a linkage block 61 is fixedly arranged, be equipped with the opening in linkage piece 61 and communicate forward the linkage chamber 87 of quick-witted chamber 96, sliding connection has the front end to be located in linkage chamber 87 linkage slider 60 in quick-witted chamber 96, linkage chamber 87 rear inner wall fixedly connected with linkage slider 60 rear end fixed connection's linkage spring 89, linkage slider 60 rear end fixed connection has the other end of braking rope 41, be equipped with opening left and intercommunication in the linkage slider 60 the gear chamber 90 of quick-witted chamber 96, be equipped with opening torsional spring chamber 85 backward in the universal driving shaft 84, torsional spring chamber 85 front inner wall fixed be equipped with the rear end with quick-witted chamber 96 rear inner wall fixed connection's braking torsional spring 86, the splined connection has linkage gear 49 on the universal driving shaft 84, linkage gear 49 right-hand member is located in gear chamber 90 and sliding connection with it.

Beneficially, the crushing mechanism 92 comprises a motor block 15 fixedly arranged on the left inner wall of the crushing cavity 12, a motor cavity 16 is arranged in the motor block 15, two synchronous motors 19 which are distributed back and forth and rotate in opposite directions are fixedly arranged on the left inner wall of the motor cavity 16, driving shafts 20 are respectively and dynamically connected to the right ends of the two synchronous motors 19, driving gears 22 and crushing gears 23 which are positioned in the motor cavity 16 and are engaged with each other are respectively and fixedly arranged on the two driving shafts 20, two driven shafts 17 which penetrate through the motor cavity 16 and the crushing cavity 12 are respectively and rotatably connected to the left inner wall of the motor cavity 16 and the right inner wall of the crushing cavity 12, a driven gear 21 and a shaping gear 24 which are positioned in the motor cavity 16 and are engaged with the driving gear 22 are respectively and fixedly arranged on the two driven shafts 17, a braking gear 18 which is positioned in the motor cavity 16 is fixedly arranged on the front driven shaft 17, the inner wall intercommunication under the electric shock chamber 16 is equipped with on the inner wall under the motor chamber 16 the belt chamber 14 of machine chamber 96, brake gear 18 with the running gear 53 is connected by driving belt 13 power fit, fixed being equipped with on the inner wall behind machine chamber 96 deposits piece 79, it upwards just communicates to be equipped with the opening in the piece 79 deposit chamber 82 of machine chamber 96, it has 4 jar bodies 80 and pushing plate 81 to deposit intracavity 82 sliding connection, deposit chamber 82 back inner wall fixedly connected with pushing plate 81 rear end fixed connection's deposit spring 83, deposit chamber 82 lower inner wall be equipped with run through from top to bottom deposit piece 79 and with deposit chamber 82, the rotatory chamber 76 of machine chamber 96 intercommunication, the inner wall all rotates around rotatory chamber 76 and is connected with blocking axle 71, blocking axle 71 about both ends and rotatory chamber 76 about by blocking torsional spring 78 fixed connection, the clamping shaft 71 is fixedly connected with a clamping plate 77, and the lower end of the clamping plate 77 is fixedly connected with the other end of the clamping rope 68.

Advantageously, the elastic force of the right-moving spring 43 is greater than the sum of the elastic force of the ejecting spring 39, the elastic force of the linkage spring 89 and the elastic force of the two clamping springs 72, the elastic force of the clamping spring 69 is greater than the sum of the elastic force of the clamping springs 78, the gravity of the filled feed in the tank 80 is greater than the sum of the elastic force of the two clamping springs 69 and the torsion force of the two clamping springs 78, the torsion force of the braking spring 86 is greater than the elastic force of the pressing spring 32, the pressing slider 31 can be attracted to the bottle cap 34, and the outer wall of the upper side of the tank 80 is provided with an arc surface which can be clamped to the bottle cap 34.

In the initial state, the push-down spring 32 is compressed, the eject spring 39 is compressed, the interlocking spring 89 is compressed, and the storage spring 83 is compressed.

During automatic charging, put into the crushed aggregates chamber 12 with raw and other materials, start synchronous machine 19, synchronous machine 19 works and drives driving shaft 20 and rotate, driving shaft 20 rotates and drives driving gear 22, crushed aggregates gear 23 rotates, raw and other materials play the effect of smashing through the rotation of two crushed aggregates gears 23, driving gear 22 rotates and drives driven gear 21 and rotate, driven gear 21 rotates and drives driven shaft 17 and rotate, thereby drive design gear 24 and rotate, thereby the effect of design fodder is played through the rotation of two design gears 24 to the raw and other materials of smashing, the fodder of accomplishing processing falls into jar body 80 from crushed aggregates chamber 12, after filling with the fodder, because two blocks of clamping plate 77 of gravity influence overturn downwards, thereby make jar body 80 fall on conveyer 47 downwards, thereby accomplish automatic charging.

When the automatic capping is carried out, the front driven shaft 17 rotates to drive the brake gear 18 to rotate, the brake gear 18 rotates to drive the rotating gear 53 which is in power connection with the brake gear and drive the belt 13 to rotate, the rotating gear 53 rotates to drive the rotating shaft 54 and the rotating bevel gear 52 to rotate, the rotating bevel gear 52 rotates to drive the rotating bevel gear 58 which is meshed with the rotating bevel gear to rotate, so as to drive the rotating shaft 51, the power gear 59 and the rotating gear 56 to rotate, the power gear 56 rotates to drive the conveying belt 47 and the driving gear 75 to rotate, the conveying belt 47 rotates to drive the tank body 80 to move rightwards, the tank body 80 moves rightwards and collides with the right moving slide block 46 to push rightwards, the right moving slide block 46 moves rightwards, so that the right moving spring 43 is compressed, the two clamping ropes 42 are loosened, the brake rope 41 is loosened, the ejection rope 40 is loosened, therefore, the bottle cap 34 moves leftwards to be separated from the cap sealing cavity 35 and is attracted with the downward-pressing sliding block 31, the brake rope 41 is loosened to enable the linkage spring 89 to reset, the linkage sliding block 60 moves forwards to drive the linkage gear 49 to move forwards and to be meshed with the power gear 59, the power gear 59 rotates to drive the linkage gear 49 to rotate and the linkage shaft 84 to rotate, the downward-pressing rope 50 is loosened, the brake torsion spring 86 is rotated in a working mode, the power rope 33 is pulled, the downward-pressing spring 32 resets, the downward-pressing block 31 moves downwards to drive the bottle cap 34 to move downwards to the tank 80 and clamp the tank 80, and automatic cap sealing is completed.

When the feed tank is taken out, the power rope 33 is pulled to drive the driving block 65 to move downwards, the driving block 65 moves downwards to collide with the two driven clamping blocks 74 at the rear side and push the two driven clamping blocks 74 away from the center of the push-out cavity 64, so that the clamping spring 69 is compressed, the clamping rope 68 is loosened, the driving block 65 continues to move downwards without being limited by the driven clamping blocks 74, the driving spring 63 is stretched, the driven spring 73 is compressed to push the driven block 48 to move forwards, the synchronous motor 19 is reversed, the braking gear 18 is reversed, the rotating gear 53 is reversed, the belt 13 is reversed, the rotating shaft 54 is reversed, the rotating bevel gear 52 is reversed, the rotating bevel gear 58 is reversed, the rotating shaft 51 is driven to reverse, the power gear 59 is reversed, the rotating gear 56 is reversed, the conveying belt 47 is reversed to drive the tank 80 to move leftwards, thereby enabling the right moving slide 46 to move leftwards, enabling the right moving spring 43 to reset, the two clamping ropes 42 to be pulled, the braking rope 41 to be pulled, the ejecting rope 40 to be pulled, the braking rope 41 to be pulled, enabling the linkage spring 89 to be compressed, the linkage slide 60 to move backwards, enabling the linkage gear 49 to move backwards to be separated from the power gear 59, enabling the braking torsion spring 86 to reset, the pressing rope 50 to be pulled, enabling the pressing spring 32 to be compressed, the pressing block 31 to move upwards, enabling the two clamping ropes 42 to be pulled, enabling the two clamping springs 72 to be compressed, enabling the two driven clamping blocks 74 on the lower side to move towards the center direction of the ejecting cavity 64, enabling the driven block 48 not to be limited by the driven clamping blocks 74 to continue to move forwards, and pushing the tank 80 out from the ejecting cavity 91, and completing the process of ejecting the tank 80, when the can body 80 falls down from the storage cavity 82 again, the two clamping plates 77 are turned downwards to pull the clamping rope 68, so that the clamping spring 69 is compressed, the two driven clamping blocks 74 on the upper side move towards the direction away from the center of the push-out cavity 64, the driving block 65 is not limited by the driven clamping blocks 74, the driving spring 63 is reset, the driving block 65 moves backwards, and the driven spring 73 moves backwards and resets the driven block 48 to move backwards. Thereby completing the taking out of the feed tank and resetting the feed machine.

The above embodiments are merely illustrative of the technical ideas and features of the present invention, and the purpose thereof is to enable those skilled in the art to understand the contents of the present invention and implement the present invention, and not to limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered within the protection scope of the present invention.