CN221128625U

CN221128625U - Multistation forming assembly

Info

Publication number: CN221128625U
Application number: CN202323088232.0U
Authority: CN
Inventors: 刘珏
Original assignee: Zhejiang Hanjue Precision Machinery Co ltd
Current assignee: Zhejiang Hanjue Precision Machinery Co ltd
Priority date: 2023-11-15
Filing date: 2023-11-15
Publication date: 2024-06-14
Anticipated expiration: 2033-11-15

Abstract

The multi-station forming assembly comprises a first forming assembly and a second forming assembly, wherein the second forming assembly is positioned below the first forming assembly, the first forming assembly and the second forming assembly can move up and down, the first forming assembly is used for forming the top surface of a cake blank, a radial sliding mechanism is arranged on the periphery of the second forming assembly, a forming cavity is formed in the middle of the second forming assembly, and the forming cavity is used for forming the peripheral wall of the cake blank; when the cake blank slides to the position right below the second molding assembly, the second molding assembly moves downwards, so that the cake blank is positioned in a cavity surrounded by the radial sliding mechanism, then the radial sliding mechanism moves inwards in the radial direction, the molding cavity is folded along with the movement, the peripheral wall of the cake blank is molded, then the inner mold in the first molding assembly descends, and the top surface of the cake blank is molded. The utility model can mold the three-dimensional cake once, thereby saving excessive manual participation, greatly improving the production efficiency and effectively reducing the production and manufacturing cost.

Description

Multistation forming assembly

Technical Field

The utility model relates to the technical field of food processing machinery, in particular to a multi-station forming assembly.

Background

As is well known, the cake with exquisite shape (such as moon cake, mung bean cake, sweet osmanthus cake and the like) is a traditional food in China, is popular with people, and is especially an indispensable food for people when meeting traditional holidays.

The existing automatic encrusting machine and matched cake forming equipment are generally suitable for producing Cantonese moon cakes and traditional baking type cakes with stuffing (the cake is flat with certain thickness), in order to increase the attractiveness of the cakes, patterns and wavy patterns (such as moon cakes seen in the current market) are always stamped on the top plane and the vertical peripheral wall of the cake, but with the continuous improvement of the living standard of people, the existing shaped cakes are difficult to meet the daily and lunar aesthetic demands of vast consumers, and therefore, the inventor carries out great innovation on the shape of the existing cakes and develops a stereoscopic cake (3D cake), and the cake shape shown in the attached figure 1 is developed. The cake is called as a stereoscopic cake because the whole cake is not in a conventional flat shape, but in an inverted circular arc transition cone shape 100 with a larger fall around, the top surface of the cake is a hemispherical transition surface 101 with a middle drum and a bottom edge, petal-shaped grains 102 are pressed on the hemispherical transition surface 101, arc-shaped transition grooves 103 with large top and small bottom are also pressed on the circumference of the peripheral wall of the cone shape 100, the transition grooves 103 are large and small, the circumferences are distributed in a staggered manner, the stereoscopic impression of the whole cake is very strong, the original rich taste of the cake is maintained through innovation of the shape, and the whole aesthetic feeling and grade of the cake are improved.

For the innovation of the cake, the traditional cake forming equipment can not produce the cake, and can only be formed step by a manual handheld forming die at present, so that the whole operation process is complex and troublesome, and the continuity is poor, thereby greatly increasing the work load of workers in cake making and seriously affecting the production efficiency.

Disclosure of utility model

The utility model aims to solve the technical problem of providing a multi-station forming assembly which can form a stereoscopic cake at one time, save excessive manual participation and fully improve the production efficiency so as to solve the technical problem existing in the current production and processing of the stereoscopic cake.

The technical scheme includes that the multi-station forming assembly comprises a first forming assembly and a second forming assembly, wherein the second forming assembly is located below the first forming assembly and can move up and down, the first forming assembly is used for forming the top surface of a cake blank, a radial sliding mechanism is arranged on the periphery of the second forming assembly, a forming cavity is formed in the middle of the second forming assembly, and the forming cavity is used for forming the peripheral wall of the cake blank; when the cake blank slides to the position right below the second molding assembly, the second molding assembly moves downwards, so that the cake blank is positioned in a cavity surrounded by the radial sliding mechanism, then the radial sliding mechanism moves inwards in the radial direction, the molding cavity is folded along with the movement, the peripheral wall of the cake blank is molded, then the inner mold in the first molding assembly descends, and the top surface of the cake blank is molded.

The utility model discloses a multi-station forming assembly, which comprises a first driving device, a base and a radial sliding mechanism, wherein the radial sliding mechanism comprises a lower die and a second driving device, the lower die is positioned below the base, a forming cavity is arranged in the middle of the lower die and is used for forming the outer wall of a cake blank, at least two parts of the lower die are spliced to form the lower die, the rear part of each part of the lower die is provided with the second driving device which is used for synchronously driving each part of the lower die to slide radially, the second driving device is arranged on the base, and the first driving device is arranged on a bracket and is used for driving the base to lift.

The utility model discloses a multi-station forming assembly, which comprises a third driving device, an inner die and an outer die, wherein the outer die is arranged at the top of a base, an inner cavity of the outer die is communicated with a forming cavity of a lower die, the inner die is positioned in the inner cavity of the outer die and is connected with the outer die in an up-down sliding manner, the bottom of the inner die is a forming part for forming the top surface of a cake blank, and the third driving device is arranged on a bracket and is used for driving the inner die to lift.

The multi-station forming assembly comprises an inner die and an outer die, wherein the inner die and the outer die are connected in an up-down sliding mode through a spline structure.

The utility model relates to a multi-station forming assembly, wherein each part of lower die is arranged at the bottom of a base through a sliding rail assembly.

The utility model discloses a multi-station forming assembly, wherein a bracket comprises a connecting plate I, a supporting column I, a connecting plate II and a supporting column II, the supporting column I and the supporting column II are vertically arranged, the connecting plate I is arranged at the top of the supporting column I, the bottom of the supporting column I is arranged on the connecting plate II, the connecting plate II is arranged at the top of the supporting column II, a first driving device is arranged on the connecting plate I, a telescopic rod of the first driving device extends downwards, a connecting plate III is arranged at the head of the telescopic rod, a vertical rod is arranged on the connecting plate III, a connecting plate IV is arranged at the bottom of the vertical rod, a guide rod is arranged on the bottom surface of the connecting plate IV, the guide rod vertically arranged, the bottom of the guide rod downwards passes through the connecting plate II and is connected with a base, and a guide sleeve is arranged between the guide rod and the connecting plate II; the third driving device is positioned below the first driving device, the connecting plate II is arranged after penetrating through the through hole formed in the connecting plate IV, the telescopic rod of the first driving device extends downwards, and the head part of the telescopic rod is connected with the inner die.

After adopting above structure, compared with the prior art, the multi-station forming assembly has the following advantages: unlike the manual molding of the three-dimensional cake by the manual mold, the utility model designs the first molding component for molding the top surface of the cake blank and the second molding component for molding the peripheral wall of the cake blank, and the two molding components can continuously work under the driving of the driving device.

Drawings

Fig. 1 is a schematic view of a three-dimensional enlarged structure of a conventional three-dimensional pastry;

FIG. 2 is a schematic perspective view of a multi-station forming assembly according to the present utility model;

FIG. 3 is a schematic perspective view of the first molding assembly shown in FIG. 2;

FIG. 4 is a partially exploded perspective enlarged schematic view of the base and radial slip mechanism of FIG. 3;

FIG. 5 is a schematic view of a perspective partially exploded view of the first molding assembly of FIG. 2;

Fig. 6 is a schematic perspective view of a multi-station forming assembly of the present utility model mounted to a cookie making forming apparatus.

Detailed Description

The utility model relates to a multi-station forming assembly, which is further described in detail below with reference to the accompanying drawings and detailed description:

As shown in fig. 2 and 3, in this embodiment, a multi-station forming assembly of the present utility model includes a first forming assembly 2 and a second forming assembly 3, the second forming assembly 3 is located below the first forming assembly 2, and the first forming assembly 2 and the second forming assembly 3 can move up and down, and the first forming assembly 2 is used for forming the top surface of a cake blank; the circumference of the second molding assembly 3 is provided with a radial sliding mechanism 33, and the middle part is provided with a molding cavity for molding the circumference wall of the cake blank.

With reference to fig. 3 and 4, the second molding assembly 3 includes a first driving device 31, a base 32, and a radial sliding mechanism 33, and the radial sliding mechanism 33 includes a lower mold 331 and a second driving device 332. The lower die 331 is positioned below the base 32, and a forming cavity is arranged in the middle of the lower die and is used for forming the outer wall of the cake blank; the lower die 331 is formed by combining at least two parts of the circumference Xiang Pin, the lower die 331 is divided into four parts, one part is used for every 90 degrees, and a forming cavity for forming the circumferential wall of the cake blank is formed by splicing together; the rear part of each part of the lower die 331 is provided with a second driving device 332 for synchronously driving each part of the lower die 331 to slide radially, the second driving device 332 is arranged on the base 32, and the first driving device 31 is arranged on the bracket 4 for driving the base 32 to lift. The second molding member 3 is not limited to the above-described structure as long as the radial sliding split and separation of the lower mold 331 can be achieved and a molded cavity is formed after the split.

Referring to fig. 5, the first molding assembly 2 includes a third driving device 21, an inner mold 22 and an outer mold 23, the outer mold 23 is mounted on the top of the base 32, the inner cavity of the outer mold 23 is communicated with the molding cavity of the lower mold 331, the inner mold 22 is located in the inner cavity of the outer mold 23 and is slidably connected with the outer mold 23 up and down, the bottom of the inner mold 22 is a molding part for molding the top surface of the cake blank, and the third driving device 21 is mounted on the support 4 and is used for driving the inner mold 22 to lift.

The first driving device 31, the second driving device 332 and the third driving device 21 may be air cylinders, electric push rods, or other driving devices, which belong to commercial products, and can be selected by a person skilled in the art according to their own needs. In addition, the present utility model is not limited to the production of the cake with the shape shown in fig. 1, and the cake with other patterns or designs, or other cakes with external shapes, such as cake with small upper part, big middle part and small bottom, cake with big upper part, small middle part and big bottom, cake with upper part being bigger than bottom and unable to be vertically demolded, etc., can be realized by changing the forming cavity of the lower mold 331 and the forming part of the inner mold 22, and how to change the structure of the forming cavity and the forming part is known in the art and is not repeated.

For cakes with groove shapes on the top surface and the peripheral wall, in order to prevent the dislocation of the groove on the top surface and the groove on the peripheral wall during molding, the inner die 22 and the outer die 23 are connected in a vertical sliding way through a spline structure, so that slight rotation can be prevented when the inner die 22 moves downwards, and the alignment of the groove on the top surface of the molded cake and the end part of the groove on the peripheral wall is further ensured; similarly, in order to prevent the dislocation of each part of the lower die 331 during the sliding movement along the radial direction inwards, the formed cake is prevented from being skewed, and the precision is ensured, so that each part of the lower die 331 is mounted at the bottom of the base 32 through the sliding rail assembly 333, and the design is mainly used for ensuring the exquisite degree of the formed cake.

As an embodiment of the present utility model, the above-mentioned bracket 4 is configured as follows: the vertical type lifting device comprises a connecting plate I40, a supporting column I42, a connecting plate II 45 and a supporting column II 47, wherein the supporting column I42 and the supporting column II 47 are vertically arranged, the connecting plate I40 is arranged at the top of the supporting column I42, the bottom of the supporting column I42 is arranged on the connecting plate II 45, the connecting plate II 45 is arranged at the top of the supporting column II 47, a first driving device 31 is arranged on the connecting plate I40, a telescopic rod of the first driving device 31 extends downwards, a connecting plate III 41 is arranged at the head part of the first driving device, a vertical rod 43 is arranged on the connecting plate III 41, a connecting plate IV 44 is arranged at the bottom of the vertical rod 43, a guide rod 46 is arranged at the bottom surface of the connecting plate IV 44, the guide rod 46 is vertically arranged, the bottom of the guide rod passes through the connecting plate II 45 downwards and is connected with a base 32, and a guide sleeve 48 is arranged between the guide rod 46 and the connecting plate II 45; the third driving device 21 is located below the first driving device 31, and is installed on a connecting plate II 45 after passing through a through hole formed in the connecting plate IV 44, the telescopic rod of the first driving device 31 extends downwards, and the head is connected with the inner die 22. Of course, other structures may be adopted for the bracket 4, as long as the first molding assembly 2 and the second molding assembly 3 can be reliably supported, and the operation sequence thereof is not hindered.

Normally, the present utility model is mounted on the cookie making apparatus 200 by support posts ii 47, see fig. 6, zhou Juanwei having a protective cover, but hidden from view for the purpose of illustrating the principle. Referring again to fig. 3, the working principle of the utility model is as follows: the cake blank is continuously conveyed leftwards by the conveyor belt on the cake forming device 200, when the cake blank slides to the position right below the second forming component 3, the second forming component 3 moves downwards to enable the cake blank to be located in a forming cavity surrounded by the lower die 331, then the lower die 331 moves inwards in the radial direction under the driving of the second driving device 332, the forming cavity is folded along with the lower die, the peripheral wall of the cake blank is formed, then the inner die 22 in the first forming component 2 descends to form the top surface of the cake blank, then the first forming component 2 and the second forming component 3 are reset, the formed cake is continuously conveyed leftwards by the conveyor belt, and when the next cake blank is located right below the second forming component 3, the steps are repeated to continuously form the cake, so that the reciprocating is realized, continuous one-step forming of the stereoscopic cake is realized in the whole process, the cake blank is not required to be manually formed step by step, the production efficiency is greatly improved, and the production cost of the stereoscopic cake is reduced.

The above examples are merely illustrative of the preferred embodiments of the present utility model and are not intended to limit the scope of the present utility model, and various modifications and improvements made by those skilled in the art to the technical solution of the present utility model should fall within the protection scope of the present utility model without departing from the design spirit of the present utility model.

Claims

1. A multi-station forming assembly comprising a first forming assembly (2) and a second forming assembly (3), characterized in that: the second molding assembly (3) is positioned below the first molding assembly (2), the first molding assembly (2) and the second molding assembly (3) can move up and down, the first molding assembly (2) is used for molding the top surface of the cake blank, a radial sliding mechanism (33) is arranged on the periphery of the second molding assembly (3), and a molding cavity is formed in the middle of the second molding assembly, and is used for molding the peripheral wall of the cake blank;

When the cake blank slides to the position right below the second molding assembly (3), the second molding assembly (3) moves downwards to enable the cake blank to be located in a molding cavity surrounded by the radial sliding mechanism (33), then the radial sliding mechanism (33) moves inwards in the radial direction, the molding cavity is folded along with the radial sliding mechanism, the peripheral wall of the cake blank is molded, then the inner mold (22) in the first molding assembly (2) descends, and the top surface of the cake blank is molded.

2. A multi-station molding assembly as defined in claim 1, wherein: the second molding assembly (3) comprises a first driving device (31), a base (32) and a radial sliding mechanism (33), the radial sliding mechanism (33) comprises a lower die (331) and a second driving device (332), the lower die (331) is located below the base (32), a molding cavity is formed in the middle of the lower die and used for molding the outer wall of a cake blank, the lower die (331) is formed by combining at least two parts, the rear part of each part of the lower die (331) is provided with the second driving device (332) and used for synchronously driving each part of the lower die (331) to slide radially, the second driving device (332) is arranged on the base (32), and the first driving device (31) is arranged on a support (4) and used for driving the base (32) to lift.

3. A multi-station molding assembly as defined in claim 2, wherein: the first molding assembly (2) comprises a third driving device (21), an inner mold (22) and an outer mold (23), wherein the outer mold (23) is arranged at the top of the base (32), an inner cavity of the outer mold (23) is communicated with a molding cavity of the lower mold (331), the inner mold (22) is positioned in the inner cavity of the outer mold (23) and is connected with the outer mold (23) in an up-down sliding manner, the bottom of the inner mold (22) is a molding part for molding the top surface of a cake blank, and the third driving device (21) is arranged on the support (4) and is used for driving the inner mold (22) to lift.

4. A multi-station molding assembly according to claim 3, wherein: the inner die (22) and the outer die (23) are connected in an up-and-down sliding mode through a spline structure.

5. A multi-station molding assembly according to any one of claims 2 to 4, wherein: each part of the lower die (331) is arranged at the bottom of the base (32) through a sliding rail component (333).

6. A multi-station molding assembly as defined in claim 4, wherein: the support (4) comprises a connecting plate I (40), a supporting column I (42), a connecting plate II (45) and a supporting column II (47), wherein the supporting column I (42) and the supporting column II (47) are vertically arranged, the connecting plate I (40) is arranged at the top of the supporting column I (42), the bottom of the supporting column I (42) is arranged on the connecting plate II (45), the connecting plate II (45) is arranged at the top of the supporting column II (47), a first driving device (31) is arranged on the connecting plate I (40), a telescopic rod of the first driving device (31) extends downwards, a connecting plate III (41) is arranged at the head part, a vertical rod (43) is arranged on the connecting plate III (41), a connecting plate IV (44) is arranged at the bottom of the vertical rod (43), a guide rod (46) is arranged on the bottom surface of the connecting plate IV (44), the bottom of the guide rod is downwards penetrated through the connecting plate II (45) and then is connected with a base (32), and a guide sleeve (48) is arranged between the guide rod (46) and the connecting plate II (45);

The third driving device (21) is positioned below the first driving device (31), a connecting plate II (45) is arranged after passing through a through hole formed in the connecting plate IV (44), a telescopic rod of the first driving device (31) extends downwards, and the head part of the telescopic rod is connected with the inner die (22).