CN115553363A - Chain forming machine for candy production - Google Patents

Abstract

The utility model belongs to the technical field of the technique of candy processing and specifically relates to a candy production is with chain make-up machine is related to, including the frame, be provided with feed inlet and discharge gate in the frame, feed inlet department is provided with the feeding guide rail. And the rack is provided with a conveying mechanism, a forming mechanism and a cleaning mechanism, and the conveying mechanism is close to the feeding guide rail. The forming mechanism is arranged between the feeding guide rail and the discharge port and comprises a chain type conveying assembly, a cutter assembly and a forming module, and the chain type conveying assembly is arranged between the feeding guide rail and the discharge port. Cutter unit spare, shaping module set up respectively on chain convey subassembly, and the shaping module includes forming die, and forming die sets up on chain convey subassembly. The cleaning mechanism is arranged at the discharge port and used for cleaning the forming die. The present application has the effect of reducing the likelihood of a reduction in the quality of the processed confectionery.

Description

Chain type forming machine for producing candy

Technical Field

The application relates to the technical field of candy processing, in particular to a chain type forming machine for candy production.

Background

At present, the candy products can flow into the market after the technological processes of material picking, sugar melting, filtering, vacuum boiling, cooling, auxiliary material adding, blending, forming, screening, inner packaging, finished product inspection, outer packaging, warehousing and the like are generally needed. In many processes, the forming process of the confectionery product determines the specific shape of the confectionery, which is an extremely important step.

The forming of the candy product is generally finished by processing the prepared massecuite by using a forming machine, one of key parts of the forming machine is a forming die which determines the shape of the processed candy, so that the quality of the forming die can directly influence the quality of the processed candy.

For the related art among the above: after the forming machine works for a long time, sugar residues are easy to remain in the forming die and are not easy to remove, so that the quality of the processed candies is easy to reduce.

Disclosure of Invention

In order to reduce the possibility of the quality of the processed candies being reduced, the application provides a chain type forming machine for producing candies.

The application provides a candy production is with chain forming machine adopts following technical scheme:

the utility model provides a candy production is with chain make-up machine, includes the frame, be provided with feed inlet and discharge gate in the frame, feed inlet department is provided with the feeding guide rail, be provided with in the frame:

the conveying mechanism is arranged close to the feeding guide rail;

the forming mechanism is arranged between the feeding guide rail and the discharging port and comprises a chain type conveying assembly, a cutter assembly and a forming module, the chain type conveying assembly is arranged between the feeding guide rail and the discharging port, the cutter assembly and the forming module are respectively arranged on the chain type conveying assembly, the forming module comprises a forming die, and the forming die is arranged on the chain type conveying assembly; and

and the cleaning mechanism is arranged at the discharge port and is used for cleaning the forming die.

Through adopting above-mentioned technical scheme, conveying mechanism can carry the massecuite for forming mechanism through the feeding guide rail, and forming die can carry out moulding to the massecuite to be convenient for process into specific shape with the massecuite, and clean mechanism can clean forming die, and then be favorable to reducing the interior sugar sediment that remains of forming die, the possibility that leads to the quality of the candy that processes to reduce.

Optionally, the conveying mechanism includes a guide strip wheel and a guide wheel assembly, the guide strip wheel and the guide wheel assembly are respectively mounted on the frame, the guide wheel assembly includes a first guide wheel and a second guide wheel, the first guide wheel and the second guide wheel are respectively rotatably mounted on the frame, the second guide wheel is detachably connected to the frame, one side of the guide strip wheel close to the frame is abutted to one side of the second guide wheel away from the frame, and the feeding guide rail is located between the first guide wheel and the second guide wheel.

Through adopting above-mentioned technical scheme, first guide pulley and second guide pulley are mutually supported to be convenient for carry forming mechanism with the massecuite on the feeding guide rail.

Optionally, the chain conveyor subassembly includes first chain conveyor and second chain conveyor, first chain conveyor with the second chain conveyor installs respectively in the frame, first chain conveyor with the relative transmission of second chain conveyor, the cutter subassembly is installed respectively first chain conveyor with on the second chain conveyor, the shaping module is installed on the first chain conveyor.

Through adopting above-mentioned technical scheme, first chain conveyor rotates with second chain conveyor relatively to be convenient for drive massecuite and remove to the discharge gate, and forming die is located first chain conveyor, and then is favorable to improving the machining efficiency to massecuite.

Optionally, a lubricating assembly is installed on the rack, the lubricating assembly includes a first oil injection pipe and a second oil injection pipe, the first oil injection pipe and the second oil injection pipe are installed on the rack respectively, the first oil injection pipe is located on one side of the first chain conveyor belt, which is far away from the second chain conveyor belt, and the second oil injection pipe is located on one side of the second chain conveyor belt, which is close to the feeding guide rail.

Through adopting above-mentioned technical scheme, first spout oil pipe can be to spraying lubricating oil on the first chain conveyer, and the oil pipe can be to spraying lubricating oil between first chain conveyer and the second chain conveyer to be convenient for make first chain conveyer and second chain conveyer normally rotate, and then be favorable to improving the machining efficiency to the massecuite to the second oil pipe.

Optionally, the cutter assembly comprises a first cutter and a second cutter, the first cutter is mounted on the first chain conveyor belt, the second cutter is mounted on the second chain conveyor belt, and one end of the first cutter, which is far away from the first chain conveyor belt, is abutted against one end of the second cutter, which is far away from the second chain conveyor belt.

Through adopting above-mentioned technical scheme, when first chain conveyor and second chain conveyor were close to each other, first cutter contradicted each other with the second cutter to be convenient for cut off the massecuite between first chain conveyor and the second chain conveyor.

Optionally, the forming module comprises a positioning frame, a sliding rod and a guide rod, the positioning frame is installed on the first chain type conveying belt, a sliding groove is formed in the positioning frame in a penetrating mode, the sliding rod is arranged in the sliding groove in a sliding penetrating mode, one end, close to the first chain type conveying belt, of the sliding rod is connected with the forming mold, a guide groove is further formed in the positioning frame in a penetrating mode, the forming direction of the guide groove is perpendicular to the sliding groove, the guide rod is inserted in the guide groove, and one end, inserted in the guide groove, of the guide rod is connected with the sliding rod.

Through adopting above-mentioned technical scheme, when the massecuite got into between first chain conveyor and the second chain conveyor, the massecuite extrudees forming die for forming die removes to the direction that is close to the slide bar, and forming die drives slide bar and guide bar and removes to relevant position, thereby makes the massecuite extrude completely into forming die in, and then is convenient for process into specific shape with the massecuite.

Optionally, forming mechanism still includes the spacing adjustment subassembly, the spacing adjustment unit mount is in the frame, the spacing adjustment subassembly includes stopper and guide block, the stopper the guide block is installed respectively in proper order in the frame, the guide block is close to the discharge gate sets up, the stopper with the slide bar is kept away from forming die's one end is contradicted, the guide block with the guide bar is kept away from the one end of slide bar is contradicted, the guide block is contradicted the guide bar is close to one side forming die.

Through adopting above-mentioned technical scheme, when first chain conveyor drives the slide bar to stopper department, the stopper can play limiting displacement to the slide bar for forming die is difficult for removing, thereby is convenient for carry out moulding to the massecuite, when first chain conveyor drives the guide bar to guide block department, the guide block plays the guide effect to the guide bar, makes the guide bar can drive forming die and removes to the direction that is close to the slide bar, and then is convenient for make the massecuite break away from forming die.

Optionally, the limiting adjustment assembly further comprises a reset block, the reset block is rotatably installed on the rack, the reset block is arranged between the guide block and the discharge port, and the reset block is abutted to one end, away from the sliding rod, of the forming die.

Through adopting above-mentioned technical scheme, when first chain conveyor belt drives the slide bar to reset block department, the reset block can play the guide effect to the slide bar for the slide bar can be to the direction removal that is close to forming die, and the slide bar drives forming die and removes, thereby is convenient for remove forming die to initial position.

Optionally, clean mechanism includes drive assembly, supporting component, drive assembly and clean subassembly, drive assembly the supporting component is installed respectively in the frame, drive assembly installs on the supporting component, drive assembly is close to forming die sets up, clean unit mount drive assembly is close to forming die's one end, clean subassembly includes rotating chain, sprocket and scraper blade, the rotating chain the sprocket is installed respectively the supporting component is close to forming die's one end, the rotating chain with drive assembly connects, the sprocket sets up in the rotating chain, the sprocket with the rotating chain is connected, the scraper blade sets up the rotating chain is close to forming die's one side, the scraper blade is used for right forming die cleans.

Through adopting above-mentioned technical scheme, drive assembly can drive assembly and rotate on supporting component, and drive assembly can transfer the rotating chain and rotate, and the rotating chain can drive the scraper blade and rotate to be convenient for utilize the scraper blade to clean inside the forming die, and then be favorable to reducing the interior sugar sediment that remains of forming die, the possibility that leads to the quality reduction of the candy of processing out.

Optionally, drive assembly includes first drive assembly and second drive assembly, first drive assembly second drive assembly installs respectively in the frame, support assembly includes axis of rotation and backup pad, the one end of axis of rotation with first drive assembly connects, the other end of axis of rotation with the frame rotates to be connected, the backup pad slides and installs in the axis of rotation, the backup pad is kept away from the one end of axis of rotation is close to forming die sets up, second drive assembly with the backup pad is connected, the one end of drive assembly slides and sets up in the axis of rotation, drive assembly is close to the one end of axis of rotation with the backup pad rotates to be connected, drive assembly's the other end rotates to set up the backup pad is close to forming die's one end.

Through adopting above-mentioned technical scheme, accomplish the clean back to forming die when the scraper blade, second drive assembly can drive the backup pad and slide in the axis of rotation, and the backup pad can drive transmission assembly and rotating chain and remove to be convenient for utilize the backup pad to drive the scraper blade and break away from forming die.

In summary, the present application includes at least one of the following beneficial technical effects:

1. the conveying mechanism, the forming mechanism and the cleaning mechanism are matched with each other, so that the massecuite is conveniently processed into a specific shape, and the possibility of reducing the quality of processed candies due to the fact that the sugar residues are left in the forming die is reduced;

2. the first chain type conveyor belt, the second chain type conveyor belt, the first cutter, the second cutter and the forming die are matched with each other, so that the massecuite is conveniently processed in the process that the massecuite moves to the discharge hole, and the processing efficiency of the massecuite is improved;

3. through the mutual matching of the forming die, the positioning frame, the sliding rod, the guide rod, the limiting block and the guide block, the massecuite can be extruded into the forming die, so that the massecuite can be conveniently molded into a specific shape;

4. through mutually supporting of drive assembly, supporting component, drive assembly and clean subassembly, can clean the dregs of sugar in the forming die to be favorable to reducing the interior pond sediment that remains of forming die, lead to the possibility that the quality of the candy that the processing reduces.

Drawings

Fig. 1 is a schematic view of the overall structure of a candy production chain molding machine according to an embodiment of the present application.

Fig. 2 is a schematic structural view of a chain type molding machine for producing candies without a shield according to an embodiment of the present application.

Fig. 3 is a schematic view of another perspective of a candy production chain forming machine without a protective cover according to an embodiment of the present application.

Fig. 4 is a schematic structural view of a molding mechanism according to an embodiment of the present application.

Fig. 5 is a schematic structural diagram of a cutter assembly according to an embodiment of the present application.

Fig. 6 is a schematic structural diagram of a molding module according to an embodiment of the present application.

Fig. 7 is a schematic structural diagram of a limit adjustment assembly according to an embodiment of the present application.

Fig. 8 is a schematic structural view of a cleaning mechanism according to an embodiment of the present application.

FIG. 9 is a schematic structural diagram of a transmission assembly and a cleaning assembly according to an embodiment of the present application.

Description of reference numerals:

1. a frame; 11. a feed inlet; 12. a discharge port; 13. a feed guide rail; 131. a first guide rail; 132. a second guide rail; 14. a discharge guide rail; 2. a conveying mechanism; 21. a guide wheel assembly; 211. a first guide wheel; 212. a second guide wheel; 22. a guide bar wheel; 3. a molding mechanism; 31. a load bearing assembly; 311. a bearing seat; 312. carrying a plate; 32. a chain conveyor assembly; 321. a first chain conveyor; 322. a second chain conveyor; 33. a cutter assembly; 331. a first cutter; 332. a second cutter; 34. a molding module; 341. a positioning frame; 3411. a chute; 3412. a guide groove; 342. a slide bar; 343. forming a mold; 344. a guide bar; 35. a limit adjusting component; 351. a limiting block; 352. a guide block; 353. a reset block; 354. adjusting the cylinder; 4. a cleaning mechanism; 41. a drive assembly; 411. a first drive assembly; 412. a second drive assembly; 42. a support assembly; 421. a rotating shaft; 422. a support plate; 43. a transmission assembly; 431. a first gear; 432. a chain; 44. a cleaning assembly; 441. a rotating chain; 442. a sprocket; 443. a squeegee; 5. a lubrication assembly; 51. a first oil jet pipe; 52. a second oil jet pipe; 6. a dust cover.

Detailed Description

The present application is described in further detail below with reference to figures 1-9.

The embodiment of the application discloses chain type forming machine for candy production.

Referring to fig. 1 and 2, the candy production chain forming machine includes a frame 1, a conveying mechanism 2, a forming mechanism 3, and a cleaning mechanism 4. The machine frame 1 is installed on the ground, the conveying mechanism 2, the forming mechanism 3 and the cleaning mechanism 4 are sequentially and respectively installed on the machine frame 1, the conveying mechanism 2 is used for conveying massecuite to the forming mechanism 3, the forming mechanism 3 is used for processing the massecuite into a specific shape, and the cleaning mechanism 4 is used for cleaning the forming mechanism 3.

Referring to fig. 2, a feed inlet 11 and a discharge outlet 12 are arranged on the frame 1, a feed guide rail 13 is detachably mounted on the frame 1, the feed guide rail 13 is arranged at the feed inlet 11, and the feed guide rail 13 includes a first guide rail 131 and a second guide rail 132. The first guide rail 131 is detachably mounted on one side of the conveying mechanism 2 away from the forming mechanism 3 through a buckle, and the second guide rail 132 is detachably mounted on one side of the conveying mechanism 2 close to the forming mechanism 3 through a buckle.

Referring to fig. 2, one end of the first guide rail 131, which is far away from the frame 1, is provided in a fan shape, and the other end of the first guide rail 131 extends to the conveying mechanism 2, so that the massecuite is conveniently guided to the conveying mechanism 2.

Referring to fig. 2, one end of the second rail 132 extends to a side of the conveying mechanism 2 away from the first rail 131, and the other end of the second rail 132 extends to a side of the forming mechanism 3 close to the conveying mechanism 2. After the massecuite passes through the conveying mechanism 2, the massecuite can enter the second guide rail 132, thereby facilitating the direction of the massecuite to the forming mechanism 3.

Referring to fig. 2, a discharging guide rail 14 is fixedly installed on the frame 1, and the discharging guide rail 14 is arranged at the discharging port 12.

Referring to fig. 2, the conveying mechanism 2 includes a guide wheel assembly 21 and a guide roller 22, and the guide wheel assembly 21 and the guide roller 22 are respectively mounted on the frame 1. Guide wheel assembly 21 includes first guide wheel 211 and second guide wheel 212, first guide wheel 211, second guide wheel 212 are installed on frame 1 rotatably respectively, one end of first guide rail 131 close to second guide rail 132 is located between first guide wheel 211 and second guide wheel 212, and one end of second guide rail 132 close to first guide rail 131 is also located between first guide wheel 211 and second guide wheel 212.

Referring to fig. 2, guide roller 22 is bolted to frame 1, and second guide roller 212 is located between guide roller 22 and frame 1, and the side of guide roller 22 close to frame 1 is abutted against the side of second guide roller 212 far from frame 1. Second guide wheel 212 is detachably connected with machine frame 1, so that guide wheel 22 can fix second guide wheel 212 on machine frame 1, and disassembly and replacement of second guide wheel 212 are facilitated.

Referring to fig. 2, a guide wheel driving device is disposed in the frame 1, and is used for driving the first guide wheel 211 and the second guide wheel 212 to rotate relatively.

Referring to fig. 2, the forming mechanism 3 is located on one side of the conveying mechanism 2 close to the discharge port 12, and one side of the forming mechanism 3 close to the ground is connected with the frame 1 through a buckle, so that the forming mechanism 3 can be separated from the frame 1, and the forming mechanism 3 is convenient to overhaul and maintain.

Referring to fig. 3 and 4, the forming mechanism 3 includes a carrier assembly 31, a chain conveyor assembly 32, a cutter assembly 33, a forming module 34, and a limit adjusting assembly 35. The carrier assembly 31 is used for carrying the chain conveyor assembly 32, the cutter assembly 33, the forming module 34 and the limit adjusting assembly 35, and the carrier assembly 31 includes a carrier seat 311 and a carrier plate 312.

Referring to fig. 3, the bearing seat 311 is fixedly mounted on the frame 1 by a buckle, the bearing plates 312 are vertically mounted on the bearing seat 311, at least two bearing plates 312 are provided, and the two bearing plates 312 are symmetrically arranged.

Referring to FIG. 4, the chain conveyor assembly 32 is mounted between two carrier plates 312. The chain conveyor assembly 32 includes a first chain conveyor 321 and a second chain conveyor 322, and the first chain conveyor 321 and the second chain conveyor 322 are driven relatively.

Referring to fig. 2 and 4, an end of the second guide rail 132, which is away from the first guide rail 131, extends to a position between the first chain conveyor 321 and the second chain conveyor 322, so that the massecuite conveyed by the second guide rail 132 can be conveyed from the second guide rail 132 to the discharging hole 12 by the cooperation of the first chain conveyor 321 and the second chain conveyor 322.

Referring to fig. 3 and 4, a conveyor belt driving mechanism is installed in the frame 1, and the conveyor belt driving mechanism can penetrate through the bearing plate 312 and is connected with the first chain conveyor 321 and the second chain conveyor 322 respectively, and the conveyor belt driving mechanism is used for driving the first chain conveyor 321 and the second chain conveyor 322 to rotate.

Referring to fig. 4 and 5, the cutter assembly 33 includes a first cutter 331 and a second cutter 332, and the first cutter 331 is fixedly installed at an outer side of the first chain conveyor 321. The first cutting blades 331 are provided in plural, and the plural first cutting blades 331 are evenly distributed on the first chain conveyor 321.

Referring to fig. 4 and 5, the second cutter 332 is fixedly installed at an outer side of the second chain conveyor 322, and the second cutter 332 may be provided in plurality, and the plurality of second cutters 332 are uniformly distributed on the second chain conveyor 322. When the first chain conveyor 321 and the second chain conveyor 322 rotate relatively to approach each other, the end face of the first cutter 331 far away from the first chain conveyor 321 and the end face of the second cutter 332 far away from the second chain conveyor 322 are mutually abutted, so that the massecuite is conveniently cut off.

Referring to fig. 4, the molding module 34 is fixedly installed on the first chain conveyor 321. The molding modules 34 may be provided in plurality, and the plurality of molding modules 34 may be provided in two sets, two sets of molding modules 34 being evenly distributed on the first chain conveyor 321, and two sets of molding modules 34 being disposed opposite to each other.

Referring to fig. 4 and 6, the molding die set 34 includes a jig 341, a slide rod 342, a molding die 343, and a guide rod 344, and the jig 341 is coupled to the first chain conveyor 321 by bolts. The shape of the positioning frame 341 can be set in various ways, and the positioning frame 341 in this embodiment is set in a U shape.

Referring to fig. 6, the positioning frame 341 has a sliding groove 3411 extending therethrough, and the sliding groove 3411 extends through both ends of the opening of the positioning frame 341. The sliding rod 342 is slidably inserted in the sliding groove 3411, and two ends of the sliding rod 342 respectively penetrate through the sliding groove 3411.

Referring to fig. 4, one end of the sliding rod 342 close to the first chain conveyor 321 is fixedly connected to the forming mold 343, and a gap exists between two sets of forming molds 343 which are oppositely arranged. The shape of the forming die 343 may be various, and the forming die 343 with different shapes can be used for processing candies with different shapes.

Referring to fig. 6, a guide groove 3412 is formed in the positioning frame 341 in a penetrating manner, and an opening direction of the guide groove 3412 is perpendicular to an opening direction of the sliding groove 3411. The guide rod 344 is slidably inserted into the guide groove 3412, and a circumferential side wall of the guide rod 344 abuts against an inner wall of the guide groove 3412. One end of the guide rod 344 inserted into the guide groove 3412 is fixedly connected to the slide rod 342, and the guide rod 344 is slidable in the guide groove 3412 in the axial direction of the slide rod 342.

Referring to fig. 4, the limiting adjustment assemblies 35 are fixedly mounted on the bearing plate 312, and at least two limiting adjustment assemblies 35 are disposed, two limiting adjustment assemblies 35 are symmetrically disposed, and one limiting adjustment assembly 35 is disposed on one bearing plate 312.

Referring to fig. 4 and 7, the limit adjustment assembly 35 includes a limit block 351, a guide block 352, and a reset block 353. The limiting block 351 is installed on one side of the bearing plate 312 close to the first chain conveyor 321, and the limiting block 351 is arranged at a position close to the middle of the first chain conveyor 321.

Referring to fig. 4 and 7, when the first chain conveyor 321 and the second chain conveyor 322 drive the massecuite to move together, one end of the slide bar 342 far away from the forming mold 343 can be abutted against one side of the limit block 351 far away from the bearing plate 312, so that the limit block 351 can limit the slide bar 342, the massecuite is difficult to push the slide bar 342 to slide through the forming mold 343, and the massecuite is convenient to be completely filled into the forming mold 343.

Referring to fig. 4 and 7, the limiting adjustment assembly 35 further includes an adjustment cylinder 354, the adjustment cylinder 354 and the limiting block 351 are fixedly connected to one side of the bearing plate 312, the adjustment cylinder 354 can adjust the distance between the limiting block 351 and the bearing plate 312, so that the limiting block 351 can limit the sliding rod 342 at different positions, and further, the adjustment cylinder is beneficial to adjusting the size of the volume of the massecuite processed by the forming die 343.

Referring to fig. 3 and 7, two limit adjustment assemblies 35 are respectively provided with an adjustment cylinder 354, one adjustment cylinder 354 is fixedly mounted on the bearing plate 312, and the other adjustment cylinder 354 is fixedly mounted on the frame 1.

Referring to fig. 4 and 7, the guide block 352 is fixedly installed at one side of the loading plate 312 close to the first chain conveyor 321, one end of the guide block 352 is disposed close to the stopper 351, and the other end of the guide block 352 is disposed close to the discharge hole 12 (refer to fig. 3). An arc-shaped guide surface is arranged on the guide block 352, and the guide surface is arranged away from the second chain conveyor 322.

Referring to fig. 4 and 7, when the first chain conveyor 321 and the second chain conveyor 322 drive the massecuite to move to a position close to the discharging hole 12 (refer to fig. 3), one end of the guide rod 344 far away from the sliding rod 342 abuts against a guide surface on the guide block 352, so that the guide block 352 can guide the guide rod 344, and the guide rod 344 can drive the forming die 343 to move towards the direction close to the bearing plate 312 through the sliding rod 342.

Referring to fig. 4 and 7, the two guide blocks 352 can simultaneously guide the two sets of guide rods 344, thereby facilitating the increase of the distance between the two sets of forming dies 343 and facilitating the falling of the massecuite off the forming dies 343 onto the discharge rail 14 (see fig. 3).

Referring to fig. 4 and 7, the reset block 353 is fixedly installed at one end of the loading plate 312 far from the loading seat 311, and the reset block 353 is provided with an inclined guide surface. When the first chain conveyor 321 drives the sliding rod 342 to pass through the discharge port 12 (refer to fig. 3), one end of the sliding rod 342, which is far away from the forming die 343, can be abutted against the reset block 353, so that the guide surface on the reset block 353 can guide the sliding rod 342, and the sliding rod 342 can drive the forming die 343 to move back to the original position.

Referring to fig. 4 and 7, two reset blocks 353 can simultaneously guide the two sets of slide bars 342 so as to facilitate the movement of the two sets of mold blocks 343 back to their original positions.

Referring to fig. 3 and 8, the cleaning mechanism 4 is located above the outfeed rail 14, and the cleaning mechanism 4 includes a drive assembly 41, a support assembly 42, a transmission assembly 43, and a cleaning assembly 44.

Referring to fig. 3 and 8, the driving assembly 41 includes a first driving assembly 411 and a second driving assembly 412. The first driving assembly 411 may be provided in various manners, in this embodiment, the first driving assembly 411 is a driving motor, and the first driving assembly 411 is fixedly installed in the frame 1.

Referring to fig. 3 and 8, the second driving assembly 412 may be provided in various forms, and the second driving assembly 412 in this embodiment is a driving cylinder. The number of the second driving assemblies 412 is at least two, and the two second driving assemblies 412 are oppositely arranged. One of the second driving assemblies 412 is fixedly installed in the rack 1, and the other second driving assembly 412 is fixedly installed on the bearing plate 312.

Referring to fig. 3 and 8, the supporting member 42 includes a rotating shaft 421 and a supporting plate 422, one end of the rotating shaft 421 is fixedly connected to the first driving member 411, and the other end of the rotating shaft 421 is rotatably connected to the supporting plate 312, so that the first driving member 411 can drive the rotating shaft 421 to rotate.

Referring to fig. 3 and 8, one end of the supporting plate 422 is slidably sleeved on the rotating shaft 421, and the other end of the supporting plate 422 is disposed close to the forming mold 343. The number of the supporting plates 422 is at least two, and the two supporting plates 422 are symmetrically distributed on the rotating shaft 421.

Referring to fig. 3 and 8, one supporting plate 422 is fixedly connected to the second driving assembly 412 installed in the frame 1, and the other supporting plate 422 is fixedly connected to the second driving assembly 412 installed on the bearing plate 312, so that the second driving assembly 412 can drive the supporting plate 422 to move on the rotating shaft 421 along the axis of the rotating shaft 421, and the second driving assembly 412 can simultaneously drive the two sets of molding dies 343 to approach or separate from each other.

Referring to fig. 8 and 9, at least two transmission assemblies 43 are provided, two transmission assemblies 43 are symmetrically provided, and one transmission assembly 43 is connected to one support plate 422.

Referring to fig. 8 and 9, the transmission assembly 43 may be provided in various forms, and the transmission assembly 43 in this embodiment includes a first gear 431 and a chain 432. The first gear 431 is slidably sleeved on the rotating shaft 421, the first gear 431 is in key connection with the rotating shaft 421, and the first gear 431 is rotatably connected with the supporting plate 422. An end of the chain 432 remote from the first gear 431 is sleeved on the cleaning assembly 44.

Referring to fig. 8 and 9, when the first driving assembly 411 drives the rotation shaft 421 to rotate, the rotation shaft 421 drives the first gear 431 to rotate, and the first gear 431 can drive the cleaning assembly 44 to rotate through the chain 432.

Referring to fig. 8 and 9, one end of the second driving assembly 412 connected to the supporting plate 422 can pass through the middle of the chain 432, so that the second driving assembly 412 is not easily interfered with the chain 432, and the second driving assembly 412 can drive the supporting plate 422 to move on the rotating shaft 421 along the axial direction of the rotating shaft 421.

Referring to fig. 8 and 9, a cleaning assembly 44 is disposed adjacent to the molding die 343, and the cleaning assembly 44 includes a rotating chain 441, a sprocket 442, and a scraper 443. The rotating chain 441 is disposed inside the chain 432, and the outer side of the rotating chain 441 abuts against the inner side of the chain 432.

Referring to fig. 8 and 9, at least two chain wheels 442 are provided, two chain wheels 442 are rotatably connected to the support plate 422, two chain wheels 442 are located inside the rotating chain 441, and two chain wheels 442 are rotatably connected to the rotating chain 441, so that the chain wheels 442 can support the rotating chain 441, and the chain 432 can drive the rotating chain 441 to rotate.

Referring to fig. 8 and 9, when the second driving assembly 412 drives the supporting plate 422 to move, the supporting plate 422 can drive the first gear 431 and the sprocket 442 to move simultaneously, the sprocket 442 can drive the rotating chain 441 to move, and the rotating chain 441 can drive the chain 432 to move, so as to facilitate the synchronous adjustment of the positions of the transmission assembly 43 and the cleaning assembly 44.

Referring to fig. 8 and 9, a scraper 443 is fixedly installed at a side of the rotating chain 441 close to the molding die 343, and the scraper 443 is capable of rotating with the rotating chain 441. An end of the scraper 443 remote from the rotating chain 441 can extend to the inside of the molding die 343, and an outer wall of the scraper 443 can abut against the inside of the molding die 343.

Referring to fig. 8 and 9, the shape of the scraper 443 is adapted to the shape design of the molding die 343. When the rotating chain 441 rotates, the scraper 443 can rotate in the forming mold 343, so that residual slag in the forming mold 343 can be scraped by the scraper 443, and the purpose of cleaning the residual slag in the forming mold 343 is achieved.

Referring to fig. 8 and 9, when the mold 343 needs to be cleaned, the operation of the molding mechanism 3 (see fig. 3) is stopped. The second driving assembly 412 is used to drive the supporting plate 422 to move toward the forming mold 343, so that the end of the scraping plate 443 away from the rotating chain 441 is inserted into the forming mold 343. Then, the first driving assembly 411 is started, the first driving assembly 411 drives the first gear 431 to rotate through the rotating shaft 421, the first gear 431 drives the rotating chain 441 to rotate through the chain 432, and the rotating chain 441 drives the scraping plate 443 to rotate, so that the scraping plate 443 removes the pond residues remaining in the molding die 343. Finally, the second driving assembly 412 is used to drive the supporting plate 422 to move away from the molding die 343, so that the scraper 443 is separated from the molding die 343. The above process is repeated to complete the cleaning of the molding die 343.

Referring to fig. 2 and 4, a lubricating assembly 5 is fixedly mounted on the frame 1, the lubricating assembly 5 includes a first oil spraying pipe 51 and a second oil spraying pipe 52, the first oil spraying pipe 51 is fixedly mounted on the frame 1, and an oil spraying port of the first oil spraying pipe 51 is arranged on one side of the first chain conveyor 321 away from the second chain conveyor 322.

Referring to fig. 2 and 4, the second oil jet pipe 52 is fixedly mounted on the frame 1, the second oil jet pipe 52 is disposed near the second guide rail 132, and the second oil jet pipe 52 is disposed below the second guide rail 132. The oil jet of the second oil jet pipe 52 is provided near one side of the second chain conveyor 322 near the first chain conveyor 321.

Referring to fig. 2 and 4, the first oil jet pipe 51 can spray lubricating oil to the first chain conveyor belt 321, thereby facilitating the operation of the first chain conveyor belt 321. The second oil spout pipe 52 can spray the lubricating oil to the second chain conveyor 322, thereby facilitating the operation of the second chain conveyor 322. And the lubricating oil sprayed by the first oil spraying pipe 51 and the second oil spraying pipe 52 is food-grade lubricating oil.

Referring to fig. 1 and 2, a dust cover 6 is connected to the frame 1 through a bolt, and the dust cover 6 is sleeved outside the forming mechanism 3, so that the possibility that foreign impurities such as dust enter the forming mechanism 3 and pollute the processed candies is reduced.

The implementation principle of this application embodiment chain forming machine for candy production does: when the massecuite needs to be processed into a specific shape, the massecuite is firstly conveyed from the first guide rail 131 to the guide wheel assembly 21, the guide wheel driving device is used for driving the first guide wheel 211 and the second guide wheel 212 to rotate, so that the first guide wheel 211 and the second guide wheel 212 can convey the massecuite to the chain type conveying assembly 32 through the second guide rail 132, and then the chain type conveying assembly 32 drives the massecuite to the discharge guide rail 14 from the second guide rail 132.

Then, during the process of passing through the chain conveyor assembly 32, the massecuite is first pressed into a position between the two sets of forming molds 343, and a pushing force is applied to the forming molds 343, so that the forming molds 343 move in a direction close to the carrying plate 312. When the forming die 343 moves to be close to the limiting block 351 along with the first chain conveyor 321, the limiting block 351 limits the forming die 343 through the sliding rod 342, so that the massecuite can be completely extruded and filled into the forming die 343. Meanwhile, the end surfaces of the first and second cutters 331 and 332 abut against each other, thereby cutting the massecuite.

Finally, when the first chain conveyor 321 is close to the discharging guide rail 14, the guide rod 344 and the guide block 352 are mutually abutted, and the guide block 352 can guide the guide rod 344, so that the guide rod 344 can drive the forming mold 343 to move towards the direction close to the bearing plate 312 through the slide rod 342, thereby facilitating the increase of the distance between the two forming molds 343, facilitating the separation of the massecuite from the forming mold 343, and the massecuite falls onto the discharging guide rail 14, and further completing the processing of the massecuite.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (10)

1. The utility model provides a candy production is with chain make-up machine, includes frame (1), be provided with feed inlet (11) and discharge gate (12) in frame (1), feed inlet (11) department is provided with feeding guide rail (13), its characterized in that, be provided with in frame (1):

the conveying mechanism (2), the conveying mechanism (2) is close to the feeding guide rail (13);

the forming mechanism (3) is arranged between the feeding guide rail (13) and the discharging port (12), the forming mechanism (3) comprises a chain type conveying assembly (32), a cutter assembly (33) and a forming module (34), the chain type conveying assembly (32) is arranged between the feeding guide rail (13) and the discharging port (12), the cutter assembly (33) and the forming module (34) are respectively arranged on the chain type conveying assembly (32), the forming module (34) comprises a forming die (343), and the forming die (343) is arranged on the chain type conveying assembly (32); and

the cleaning mechanism (4), the cleaning mechanism (4) is arranged at the discharge port (12), and the cleaning mechanism (4) is used for cleaning the forming die (343).

2. The candy production chain forming machine according to claim 1, wherein the conveying mechanism (2) comprises a guide bar wheel (22) and a guide wheel assembly (21), the guide bar wheel (22) and the guide wheel assembly (21) are respectively mounted on the frame (1), the guide wheel assembly (21) comprises a first guide wheel (211) and a second guide wheel (212), the first guide wheel (211) and the second guide wheel (212) are respectively rotatably mounted on the frame (1), the second guide wheel (212) is detachably connected with the frame (1), one side of the guide bar wheel (22) close to the frame (1) is abutted to one side of the second guide wheel (212) away from the frame (1), and the feeding guide rail (13) is located between the first guide wheel (211) and the second guide wheel (212).

3. The machine according to claim 1, wherein the chain conveyor assembly (32) comprises a first chain conveyor belt (321) and a second chain conveyor belt (322), the first chain conveyor belt (321) and the second chain conveyor belt (322) are respectively mounted on the frame (1), the first chain conveyor belt (321) and the second chain conveyor belt (322) are in relative transmission, the cutter assembly (33) is respectively mounted on the first chain conveyor belt (321) and the second chain conveyor belt (322), and the forming module (34) is mounted on the first chain conveyor belt (321).

4. The chain forming machine for producing candies as described in claim 3, wherein a lubricating assembly (5) is mounted on said frame (1), said lubricating assembly (5) comprises a first oil spray pipe (51) and a second oil spray pipe (52), said first oil spray pipe (51) and said second oil spray pipe (52) are respectively mounted on said frame (1), said first oil spray pipe (51) is located on a side of said first chain conveyor (321) away from said second chain conveyor (322), and said second oil spray pipe (52) is located on a side of said second chain conveyor (322) close to said feeding guide rail (13).

5. The chain type molding machine for producing confectionary according to claim 3, wherein the cutter assembly (33) comprises a first cutter (331) and a second cutter (332), the first cutter (331) is installed on the first chain conveyor (321), the second cutter (332) is installed on the second chain conveyor (322), and an end of the first cutter (331) away from the first chain conveyor (321) and an end of the second cutter (332) away from the second chain conveyor (322) interfere with each other.

6. The chain forming machine for producing candies as described in claim 5, wherein said forming die set (34) comprises a positioning frame (341), a sliding rod (342) and a guiding rod (344), said positioning frame (341) is installed on said first chain conveyor (321), a sliding slot (3411) is formed through said positioning frame (341), said sliding rod (342) is slidably disposed in said sliding slot (3411), one end of said sliding rod (342) close to said first chain conveyor (321) is connected to said forming die (343), a guiding slot (3412) is further formed through said positioning frame (341), said guiding slot (3412) is formed in a direction perpendicular to said sliding slot (3411), said guiding rod (344) is inserted into said guiding slot (3412), and one end of said guiding rod (344) inserted into said guiding slot (3412) is connected to said sliding rod (342).

7. The candy production chain molding machine according to claim 6, wherein the molding mechanism (3) further comprises a limit adjusting assembly (35), the limit adjusting assembly (35) is mounted on the frame (1), the limit adjusting assembly (35) comprises a limit block (351) and a guide block (352), the limit block (351) and the guide block (352) are sequentially mounted on the frame (1), the guide block (352) is disposed near the discharge port (12), the limit block (351) is abutted against one end of the slide rod (342) far away from the molding mold (343), the guide block (352) is abutted against one end of the guide rod (344) far away from the slide rod (342), and the guide block (352) is abutted against one side of the guide rod (344) near the molding mold (343).

8. The candy production chain molding machine according to claim 7, wherein the limiting adjustment assembly (35) further comprises a reset block (353), the reset block (353) is rotatably mounted on the frame (1), the reset block (353) is arranged between the guide block (352) and the discharge hole (12), and the reset block (353) abuts against one end of the sliding rod (342) away from the molding die (343).

9. Chain forming machine for the production of confectionery, according to claim 1, characterized in that said cleaning means (4) comprise a driving assembly (41), a supporting assembly (42), a transmission assembly (43) and a cleaning assembly (44), the driving component (41) and the supporting component (42) are respectively arranged on the frame (1), the transmission component (43) is arranged on the supporting component (42), the transmission assembly (43) is arranged close to the forming die (343), the cleaning component (44) is arranged at one end of the transmission component (43) close to the forming die (343), the cleaning component (44) comprises a rotating chain (441), a chain wheel (442) and a scraper (443), the rotating chain (441) and the chain wheel (442) are respectively arranged at one end of the supporting component (42) close to the forming die (343), the rotating chain (441) is connected with the transmission component (43), the sprocket (442) being disposed inside the rotating chain (441), the sprocket (442) being connected to the rotating chain (441), the scraper (443) is arranged on one side of the rotating chain (441) close to the forming die (343), the scraper (443) is used for cleaning the molding die (343).

10. The chain type forming machine for producing candies as recited in claim 9, wherein said driving assembly (41) comprises a first driving assembly (411) and a second driving assembly (412), said first driving assembly (411) and said second driving assembly (412) are respectively mounted on said frame (1), said supporting assembly (42) comprises a rotating shaft (421) and a supporting plate (422), one end of said rotating shaft (421) is connected to said first driving assembly (411), the other end of said rotating shaft (421) is rotatably connected to said frame (1), said supporting plate (422) is slidably mounted on said rotating shaft (421), one end of said supporting plate (422) far from said rotating shaft (421) is rotatably connected to said supporting plate (422), said second driving assembly (412) is connected to said supporting plate (422), one end of said transmission assembly (43) is slidably mounted on said rotating shaft (421), one end of said transmission assembly (43) near said rotating shaft (421) is rotatably connected to said supporting plate (422), and the other end of said transmission assembly (43) is rotatably mounted on one end of said supporting plate (422) near said forming mold (343).

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