CN109648637B - Walking stick candy rotary shearing synchronous mechanism - Google Patents

Abstract

The invention discloses a crutch sugar rotation and shearing synchronous mechanism which comprises a support, a synchronous rotation assembly and a synchronous shearing assembly; the synchronous rotating assembly and the synchronous shearing assembly are both arranged on the support; two sides of the synchronous rotating assembly are respectively provided with a synchronous shearing assembly; the synchronous rotating assembly comprises a rotating cylinder and a driving gear; the synchronous shearing assembly comprises a shearing gear, a rotating shaft and a shearing plate; the invention improves the shearing efficiency of the shearing plate through the cooperative operation of the gears, and simultaneously, the rotation of the rotary drum is utilized to drive the sugar body to rotate, so that the synchronism of rotation and shearing is improved, and the possibility of distortion and deformation of the crutch sugar during shearing is further reduced.

Description

Walking stick candy rotary shearing synchronous mechanism

Technical Field

The invention relates to a crutch sugar rotation and shearing synchronous mechanism.

Background

At present, along with the improvement of living standard, people select candies without being limited to the taste, the taste and the characteristics of the candies

The art candy of the type is becoming more and more popular with more consumers for its good visual effect. To adapt to the consumption concept of people

Is designed and manufactured by candy manufacturers to form various artistic candies, wherein the thin plate candy has beautiful appearance and good taste

The advantages of good quality and the like are more and more popular in the candy sales market. According to the process flow of manufacturing the thin plate candy, the thin plate candy is thin

The plate candy is produced by strip making and strip rubbing by a former device, and is manufactured into an elongated candy strip with color spiral textures, and the candy strip is cut into corresponding lengths according to the specification and gram weight of the manufactured candy; however, in the existing intercepting process, the strip-shaped sugar body is in a rotating form when being rubbed, and deformation and distortion of the strip-shaped sugar body can be caused due to shearing resistance when shearing is achieved, so that if the crutch sugar can be sheared in a fully rotating form, the synchronism of rotation and shearing is achieved, and the deformation and distortion of the crutch sugar can be greatly reduced.

Disclosure of Invention

Aiming at the defects of the prior art, the invention solves the problems that: the crutch sugar rotary shearing synchronization mechanism can realize shearing and rotary synchronization.

In order to solve the problems, the invention adopts the following technical scheme:

a crutch candy rotating and shearing synchronous mechanism comprises a support, a synchronous rotating assembly and a synchronous shearing assembly; the synchronous rotating assembly and the synchronous shearing assembly are both arranged on the support; two sides of the synchronous rotating assembly are respectively provided with a synchronous shearing assembly; the synchronous rotating assembly comprises a rotating cylinder and a driving gear; the rotary cylinder is inserted and rotatably connected to the support; the driving gear is fixed on the outer side around one end of the rotary cylinder; the synchronous shearing assembly comprises a shearing gear, a rotating shaft and a shearing plate; the rotating shaft is rotationally inserted on the support; two sides of the rotary drum are respectively provided with a rotary shaft; one end of the rotating shaft is fixedly provided with a shearing gear, and the other end of the rotating shaft is fixedly provided with a shearing plate; the two sides of the driving gear are respectively connected with a shearing gear in a gear engagement way; two shearing plates are respectively distributed on two sides of the rotary drum; the two shearing plates are driven by the shearing gear to horizontally overlap and shear and rotate.

Further, the synchronous shearing assembly also comprises a rotary connecting plate; the other end of the rotating shaft is fixedly provided with a rotating connecting plate; the shearing plate is arranged on the outer side of the rotary connecting plate.

Further, the rotary connecting plate is in a circular structure; the inside of the rotary cylinder is a cavity with a cylindrical structure; the center of the rotary connecting plate and the axle center of the rotary cylinder are positioned on the same horizontal line.

Further, the shearing plate is horizontally and radially arranged on the outer side of the rotary connecting plate; one end of the shearing plate is fixed on the rotary connecting plate, and the other end of the shearing plate extends to the outer side of the rotary cylinder; the other ends of the two shearing plates are in front-back overlapped rotary motion; the positions of the front and back overlapping of the other ends of the two shearing plates are located on the outer side of the axis of the rotary cylinder.

Further, the other end of the shearing plate is provided with a shearing notch; the shearing notches on the two shearing plates are arranged in opposite directions.

Further, the shearing notch is in a semicircular structure.

Further, the synchronous rotating assembly also comprises a power gear; the power gear is arranged on the outer side of the driving gear.

The beneficial effects of the invention are that

The invention improves the shearing efficiency of the shearing plate through the cooperative operation of the gears, and simultaneously, the rotation of the rotary drum is utilized to drive the sugar body to rotate, so that the synchronism of rotation and shearing is improved, and the possibility of distortion and deformation of the crutch sugar during shearing is further reduced.

Drawings

Fig. 1 is a schematic diagram of a split structure of one side of the present invention.

Fig. 2 is a schematic view of the structure of the other side shear plate according to the present invention when the other side shear plate starts to rotate.

Fig. 3 is a schematic view of the structure of the other side shear plate of the present invention after rotation.

Fig. 4 is a schematic structural view of the other side shear plate according to the present invention when shearing occurs.

Fig. 5 is a schematic view of a structure of a side-mounted power gear of the present invention.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

As shown in fig. 1 to 5, a crutch sugar rotation and shearing synchronous mechanism comprises a support 1, a synchronous rotation assembly 2 and a synchronous shearing assembly 3. The synchronous rotating assembly 2 and the synchronous shearing assembly 3 are both mounted on the support 1. Two sides of the synchronous rotating assembly 2 are respectively provided with a synchronous shearing assembly 3. The synchronous rotating component 2 can drive the synchronous cutting component 3 at two sides to synchronously move. The synchronous rotation assembly 2 comprises a rotation cylinder 22 and a driving gear 21. The rotary cylinder 22 is inserted and rotatably connected to the support 1, and both ends of the rotary cylinder 22 extend to the outside of both sides of the support 1. The rotary cylinder 22 has a structure in which both ends of the inner cavity are opened. The driving gear 21 is fixed to the outer side around one end of the rotary cylinder 22. The driving gear 21 rotates to drive the rotary drum 22 to rotate together. The synchronous shear assembly 3 includes a shear gear 31, a rotary shaft 32, and a shear plate 34. The rotary shaft 32 is rotatably inserted into the holder 1. Two sides of the rotary drum 22 are respectively provided with a rotary shaft 32. One end of the rotating shaft 32 is fixedly provided with a shearing gear 31, and the other end of the rotating shaft 32 is fixedly provided with a shearing plate 34. The two sides of the driving gear 21 are respectively connected with one shearing gear 31 in a gear engagement way, so that when the driving gear 21 rotates, the two shearing gears 31 can be synchronously driven to synchronously rotate. Two shearing plates 34 are respectively distributed on two sides of one end of the rotary cylinder 22, the shearing plates 34 are of a strip-shaped structure, and the two shearing plates 34 are driven by the shearing gear 31 to horizontally overlap and shear and rotate.

As shown in fig. 1 to 5, in order to facilitate the installation of the shear plates 34, it is further preferred that the synchronous shear assembly 3 further comprises a swivel connection plate 33; the other end of the rotating shaft 32 is fixedly provided with a rotating connecting plate 33, and the shearing plate 34 is arranged on the outer side of the rotating connecting plate 33. Further preferably, the rotary connecting plate 33 has a circular structure, the interior of the rotary cylinder 22 is a cavity with a cylindrical structure, and the center of the rotary connecting plate 33 and the axis of the rotary cylinder 22 are located on the same horizontal line. Further preferably, the shearing plate 34 is horizontally and radially arranged on the outer side of the rotary connecting plate 33, one end of the shearing plate 34 is fixed on the rotary connecting plate 33, and the other end of the shearing plate 34 extends to the outer side of the rotary cylinder 22; the other ends of the two shear plates 34 are rotated in tandem. The specific installation can be designed as follows: one shear plate 34 can be mounted on the rotary connecting plate 33 through screws and the distance between the shear plate 34 and the rotary connecting plate 33 is controlled to be A, the other shear plate 34 can be mounted on the rotary connecting plate 33 through screws and the distance between the shear plate 34 and the rotary connecting plate 33 is controlled to be B, and the distance A is controlled to be larger than the distance B, so that the longitudinal staggered heterofacial distribution of the one shear plate and the other shear plate is realized, and further, the front-back periodical overlapping rotary movement of the two shear plates 34 is realized. The overlapping position of the other ends of the two shear plates 34 is located outside the axial center of the rotary cylinder 22. Further preferably, the other end of the shear plate 34 is provided with a shear notch 341, and the shear notches 341 on the two shear plates 34 are arranged in opposite directions, that is, when the other ends of the two shear plates 34 are both rotated to the upper side and the lower side of the rotary drum 22, the shear notch 341 of the shear plate rotating downward is located at the lower side of the shear plate, and the shear notch 341 of the shear plate rotating upward is located at the upper side of the shear plate, so that the shear notch 341 of the two shear plates can form a form of closing the shear to the center of the rotary drum 22. Further preferably, the shearing notch 341 has a semicircular structure. Further preferably, the synchronous rotation assembly 2 further comprises a power gear; the power gear 23 is arranged on the outer side of the driving gear 21, so that the power gear 23 is driven to rotate by an external driving motor, the driving gear 21 is driven to rotate by the power gear 23, and finally, the shearing gears 31 on two sides are synchronously driven to rotate by the driving gear 21, so that shearing is realized.

The operation process of the invention is as follows: the power gear 23 drives the drive gear 21 to rotate, the drive gear 21 synchronously drives the shearing gears 31 on two sides to rotate, the shearing gears 31 drive the rotating shafts 32 connected with each other to rotate, the rotating shafts 32 drive the rotating connecting plates 33 connected with the other ends to rotate, the rotating connecting plates 33 drive the shearing plates 34 arranged on the rotating plates to rotate, so that the shearing gaps 341 at the other ends of the two shearing plates 34 are overlapped and intersected on the outer side of the rotating cylinder 22 periodically to shear the strip-shaped sugar bodies passing through the rotating cylinder 22, meanwhile, the drive gear 21 also continuously rotates, and the drive gear 21 drives the rotating cylinder 22 to continuously rotate, so that the strip-shaped sugar bodies after rubbing enter the rotating cylinder 22 to rotate along with the rotating cylinder 22, the rotating cylinder 22 provides a rotating power for the strip-shaped sugar bodies, the strip-shaped sugar bodies can be sheared while rotating, the synchronism of rotation and shearing is realized, and the defect that the sugar bodies are distorted and deformed during cutting is solved while the efficiency of cutting the sugar bodies is improved.

The foregoing description of the preferred embodiments of the invention is not intended to be limiting, but rather is intended to cover all modifications, equivalents, alternatives, and improvements that fall within the spirit and scope of the invention.

Claims (3)

1. The crutch candy rotating and shearing synchronous mechanism is characterized by comprising a support, a synchronous rotating assembly and a synchronous shearing assembly; the synchronous rotating assembly and the synchronous shearing assembly are both arranged on the support; two sides of the synchronous rotating assembly are respectively provided with a synchronous shearing assembly; the synchronous rotating assembly comprises a rotating cylinder and a driving gear; the rotary cylinder is inserted and rotatably connected to the support; the driving gear is fixed on the outer side around one end of the rotary cylinder; the synchronous shearing assembly comprises a shearing gear, a rotating shaft and a shearing plate; the rotating shaft is rotationally inserted on the support; two sides of the rotary drum are respectively provided with a rotary shaft; one end of the rotating shaft is fixedly provided with a shearing gear, and the other end of the rotating shaft is fixedly provided with a shearing plate; the two sides of the driving gear are respectively connected with a shearing gear in a gear engagement way; two shearing plates are respectively distributed on two sides of the rotary drum; the two shearing plates are driven by the shearing gear to horizontally overlap and shear and rotate; the synchronous shearing assembly also comprises a rotary connecting plate; the other end of the rotating shaft is fixedly provided with a rotating connecting plate; the shearing plate is arranged on the outer side of the rotary connecting plate; the rotary connecting plate is in a circular structure; the inside of the rotary cylinder is a cavity with a cylindrical structure; the center of the rotary connecting plate and the axle center of the rotary drum are positioned on the same horizontal line; the shearing plate is horizontally and radially arranged on the outer side of the rotary connecting plate; one end of the shearing plate is fixed on the rotary connecting plate, and the other end of the shearing plate extends to the outer side of the rotary cylinder; the other ends of the two shearing plates are in front-back overlapped rotary motion; the front-back overlapped positions of the other ends of the two shearing plates are positioned at the outer side of the axle center of the rotary cylinder; the synchronous rotating assembly also comprises a power gear; the power gear is arranged on the outer side of the driving gear.

2. The mechanism of claim 1, wherein the other end of the shear plate is provided with a shear notch; the shearing notches on the two shearing plates are arranged in opposite directions.

3. The mechanism of claim 2, wherein the shear notch is semi-circular in configuration.