CN106818978B

CN106818978B - Pattern machine

Info

Publication number: CN106818978B
Application number: CN201710195098.4A
Authority: CN
Inventors: 曹壬圣
Original assignee: Individual
Current assignee: Individual
Priority date: 2017-03-29
Filing date: 2017-03-29
Publication date: 2022-09-02
Anticipated expiration: 2037-03-29
Also published as: CN106818978A

Abstract

The invention discloses a chip machine, which further comprises a discharging device and a forming device, wherein the discharging device comprises a first screw conveyor, a second screw conveyor, a first screw conveyor cavity and a second screw conveyor cavity; the forming device comprises a flow distribution die, a flow guide die and a control die; the flow distribution die is provided with a first flow distribution hole and a second flow distribution hole which correspond to and are communicated with the discharge ports of the first auger cavity and the second auger cavity, the flow distribution die is fixed at the discharge ports of the first auger cavity and the second auger cavity, and the flow guide die is fixedly connected with the flow distribution die; the flow guide die is provided with a flower piece core raw material guide groove, a flower piece core raw material guide hole, a flower piece edge raw material guide groove, a flower piece edge raw material guide hole and a flower piece core raw material forming groove; the control module is fixed behind the guide mould through a fixing part.

Description

Pattern machine

Technical Field

The invention relates to food processing equipment, in particular to a chip machine.

Background

The flower slices are popular food which is offered to guests and relatives and friends at the festival of the year, and are ideal food for serving tea with wine as dish and boiling soup. The flower slices are traditional snack foods produced in various places, have a long history, and are also called cat ears, cattle ears, rabbit ears and the like due to the shapes of the cat ears, the cattle ears, the rabbit ears and the like, so that the snack foods are collectively called the flower slices.

The flower slices are made by hand, and are made by overlapping two or more kinds of dough sheets made of different materials, rolling the dough sheets into a cylinder or a cylinder, slicing the dough sheets, and frying the sliced dough sheets. Because the pure manual manufacturing is adopted, the process is complicated, the production efficiency is low, and the production cost is high. Thirdly, as the flower pieces are made by pure handwork, the patterns on the flower pieces are single and simple, the flower pieces printed with complicated shapes and patterns cannot be produced, which is inconvenient and has low economic benefit.

Disclosure of Invention

The invention aims to provide a pattern sheet machine which is convenient to use, has high production efficiency and can produce pattern sheets printed with complex shapes or patterns.

In order to solve the technical problem, the pattern piece machine further comprises a discharging device and a forming device, wherein the discharging device comprises a first auger, a second auger, a first auger cavity and a second auger cavity; the first auger and the second auger are in transmission connection with the power device and are respectively fixed in the first auger cavity and the second auger cavity through bearings; the first auger cavity and the second auger cavity are respectively provided with a feeding port and a discharging port; the forming device comprises a flow distribution die, a flow guide die and a control die; the flow splitting die is provided with a first flow splitting hole and a second flow splitting hole which correspond to and are communicated with the discharge ports of the first auger cavity and the second auger cavity, and the first flow splitting hole and the second flow splitting hole are communicated from one side of the flow splitting die to the other side of the flow splitting die; the flow dividing die is fixed at the discharge ports of the first auger cavity and the second auger cavity, so that raw materials discharged from the discharge ports of the first auger cavity and the second auger cavity are extruded along the first flow dividing hole and the second flow dividing hole respectively; the diversion mold is fixedly connected with the flow distribution mold; the flow guide die is provided with a flower piece core raw material guide groove, a flower piece core raw material guide hole, a flower piece edge raw material guide groove, a flower piece edge raw material guide hole and a flower piece core raw material forming groove; the head end of the flower piece core raw material guide groove is communicated with the outlet of the diversion hole, the tail end of the flower piece core raw material guide groove is circular or arc-shaped, and the circle center or the arc center of the circular or arc-shaped guide groove is superposed with the central point of the diversion mold; the flower piece core raw material guide hole is arranged in the tail end of the flower piece core raw material guide groove, and an outlet of the flower piece core raw material guide hole is communicated to the other side of the flow guide die, so that the raw material extruded from the shunting hole is extruded out along the flower piece core raw material guide hole; the flower piece edge raw material guide groove is arranged around the flower piece core raw material guide groove and is communicated with the outlet of the two shunting holes, and the flower piece edge raw material guide holes are distributed in the flower piece edge raw material guide groove and are communicated with the other side of the flow guide die, so that the raw materials extruded from the two shunting holes are extruded along the flower piece edge raw material guide holes; the outline shape of the flower piece core raw material forming groove is adapted to the design shape of the flower piece core; the flower piece core raw material forming groove corresponds to the flower piece core raw material guide hole and is communicated with the outlet of the flower piece core raw material guide hole; the control die is fixed behind the flow guide die through a fixing part; the control module is provided with a horn-shaped inlet and an outlet which is matched with the outline shape of the flower piece; the inlet and the outlet of the control mold are communicated through a transition arc; the control mould trumpet-shaped inlet is communicated with the flower piece side raw material guide hole and the flower piece core raw material forming groove of the guide mould, so that the flower piece core raw material and the flower piece side raw material are compressed into a whole through the control mould and extruded out along the outlet of the control mould.

The forming die is provided with a flower piece core raw material forming hole and a flower piece edge raw material forming hole; the flower piece core raw material forming hole corresponds to the flower piece core raw material guide hole and is communicated with the outlet of the flower piece core raw material guide hole; the flower piece core raw material forming groove is communicated with the outlet of the flower piece core raw material guide hole through the flower piece core raw material forming hole; the flower piece edge raw material forming hole corresponds to the flower piece edge raw material guide hole and is communicated with the outlet of the flower piece edge raw material guide hole; the outlets of the flower piece edge raw material forming holes are distributed around the flower piece core raw material forming groove.

The third auger is in transmission connection with the power device and is fixed in the third auger cavity through a bearing; the third auger cavity is provided with a feeding port and a discharging port; the shunting die is provided with three shunting holes, the three shunting holes correspond to and are communicated with the discharge hole of the second auger cavity, and raw materials discharged from the discharge hole of the third auger cavity are extruded out along the three shunting holes; the flow guide die is provided with a flower piece interlayer raw material guide groove and a flower piece interlayer raw material guide hole; the head end of the flower piece interlayer raw material guide groove is communicated with the outlets of the three shunting holes, and the tail end of the flower piece interlayer raw material guide groove is arranged around the flower piece core raw material guide groove; the flower piece interlayer raw material guide holes are distributed in the tail end of the flower piece interlayer raw material guide groove; the forming die is provided with a flower piece interlayer raw material forming hole and a flower piece interlayer raw material forming groove; the flower piece interlayer raw material forming holes correspond to the flower piece interlayer raw material guide holes and are communicated with the flower piece interlayer raw material guide hole outlets; the flower piece interlayer raw material forming holes are communicated with the flower piece interlayer raw material forming grooves, and the flower piece interlayer raw material forming grooves are arranged around the flower piece core raw material forming grooves; the outlets of the flower piece edge raw material forming holes are distributed around the flower piece interlayer raw material forming grooves.

The groove depth of the flower chip core raw material forming groove is 0.8-5 cm.

The outline shape of the flower core raw material forming groove is in a 'Fu' shape or a 'shou' shape or a flower shape or a grass shape or an animal shape.

The flower piece core raw material forming groove is detachably connected with the diversion mold or the flower piece core raw material forming groove is detachably connected with the forming mold hole.

The guide die is arranged in the control die.

By adopting the structure of the invention, as the device also comprises the discharging device and the forming device, when in use, the flower piece core raw material and the flower piece edge raw material are respectively arranged in the first auger cavity and the second auger cavity, and the flower piece core raw material enters the flower piece core raw material forming groove of the guide die through the flow dividing die and the guide die under the action of the first auger; under the action of the second screw conveyor, the flower piece edge raw material is coated in the flower piece core raw material forming groove through the flow distribution die and the flow guide die; and simultaneously pushing the flower piece core raw material and the flower piece edge raw material into the control die through the first auger and the second auger. In the process, the shape of the section forming shape of the flower piece core raw material is determined by the shape of the flower piece core raw material forming groove, when the shape of the flower piece core is required to be changed, the flower piece core raw material forming groove can be changed by only changing the outline shape of the flower piece core raw material forming groove, the use is convenient, the operation is simple, and flower pieces printed with complex shapes or patterns can be produced. The flower piece edge raw material enters the control mold and then is coated and molded under the compression effect of the control mold, the flower piece edge raw material and the molded flower piece core raw material are compressed into a whole through the control mold and form a strip shape through an outlet of the extrusion control mold, and the flower piece edge raw material and the molded flower piece core raw material are sliced into slices.

The forming die is provided with a flower piece core raw material forming hole and a flower piece edge raw material forming hole; the flower piece core raw material forming hole corresponds to the flower piece core raw material guide hole and is communicated with the outlet of the flower piece core raw material guide hole; the flower piece core raw material forming groove is communicated with the outlet of the flower piece core raw material guide hole through the flower piece core raw material forming hole; the flower piece edge raw material forming hole corresponds to the flower piece edge raw material guide hole and is communicated with the outlet of the flower piece edge raw material guide hole; the export in the flower piece limit raw materials shaping hole distributes around flower piece heart raw materials shaping groove, and production and processing is more convenient, changes flower piece heart raw materials shaping groove more simple and convenient.

The power device is connected with the first auger cavity through a transmission shaft, and the first auger cavity is fixed in the first auger cavity through a bearing; the third auger cavity is provided with a feeding port and a discharging port; the shunting die is provided with three shunting holes, the three shunting holes correspond to and are communicated with the discharge hole of the second auger cavity, and raw materials discharged from the discharge hole of the third auger cavity are extruded out along the three shunting holes; the flow guide die is provided with a flower piece interlayer raw material guide groove and a flower piece interlayer raw material guide hole; the head end of the flower piece interlayer raw material guide groove is communicated with the outlets of the three shunting holes, and the tail end of the flower piece interlayer raw material guide groove is arranged around the flower piece core raw material guide groove; the flower piece interlayer raw material guide holes are distributed in the tail end of the flower piece interlayer raw material guide groove; the forming die is provided with a flower piece interlayer raw material forming hole and a flower piece interlayer raw material forming groove; the flower piece interlayer raw material forming holes correspond to the flower piece interlayer raw material guide holes and are communicated with the flower piece interlayer raw material guide hole outlets; the flower piece interlayer raw material forming holes are communicated with the flower piece interlayer raw material forming grooves, and the flower piece interlayer raw material forming grooves are arranged around the flower piece core raw material forming grooves; the outlet of the flower piece edge raw material forming hole is distributed around the flower piece interlayer raw material forming groove, so that flower pieces with more complex shapes and patterns can be produced, the patterns and the shape patterns of the flower piece core are richer, the working efficiency is higher, and the economic benefit is higher.

Because the flower piece core raw material forming groove can be dismantled with the water conservancy diversion mould and be connected or flower piece core raw material forming groove is dismantled with the shaping nib and is connected, production and processing is simpler, and it is more convenient to use, and it is more convenient to change flower piece core raw material forming groove operation.

Because the guide die is arranged in the control die, the installation and the disassembly operations are simpler, and the use is more convenient.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic structural view of a split die of the present invention;

FIG. 3 is a schematic view of the structure of the guide mold of the present invention;

FIG. 4 is a cross-sectional view taken along line A-A of FIG. 3;

FIG. 5 is a schematic structural view of a molding die of the present invention;

FIG. 6 is a cross-sectional view taken along line B-B of FIG. 5;

FIG. 7 is a schematic structural view of another molding die of the present invention;

fig. 8 is a schematic structural view of a control mold of the present invention.

Detailed Description

The invention is described in detail below with reference to the following figures and detailed description:

as shown in fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7 and fig. 8, the cotton flake processing machine of the present invention further comprises a discharging device and a forming device, wherein the discharging device comprises a first screw conveyor 4, a second screw conveyor 3, a first screw conveyor cavity 5 and a second screw conveyor cavity 6. The first auger 4 and the second auger 3 are in transmission connection with the power device and are respectively fixed in the first auger cavity 5 and the second auger cavity 6 through bearings. The first auger cavity 5 and the second auger cavity 6 are respectively provided with a feeding port and a discharging port. The forming device comprises a flow distribution die 8, a flow guide die 13 and a control die 7. The shunting die 8 is provided with a first shunting hole 9 and a second shunting hole 10 which correspond to and are communicated with the discharge holes of the first auger cavity 5 and the second auger cavity 6, and the first shunting hole 9 and the second shunting hole 10 are led to the other side from one side of the shunting die 8. The shunting die 8 is fixed at the discharge ports of the first auger cavity 5 and the second auger cavity 6, so that raw materials discharged from the discharge ports of the first auger cavity 5 and the second auger cavity 6 are respectively extruded along the first shunting hole 9 and the second shunting hole 10. The diversion mold 13 is fixedly connected with the diversion mold 8. The guide die 13 is provided with a flower piece core raw material guide groove 14, a flower piece core raw material guide hole 15, a flower piece edge raw material guide groove, a flower piece edge raw material guide hole 12 and a flower piece core raw material forming groove 22. The head end of the flower chip core raw material guide groove 14 is communicated with the outlet of the first diversion hole 9, the tail end of the flower chip core raw material guide groove is circular or arc-shaped, and the circle center or the arc center of the circular or arc-shaped coincides with the central point of the diversion mold 13. The flower chip core raw material guide hole is arranged in the tail end of the flower chip core raw material guide groove 14, and the outlet of the flower chip core raw material guide hole is communicated with the other side of the flow guide die 13, so that the raw material extruded from the first shunting hole 9 is extruded out along the flower chip core raw material guide hole. The flower piece edge raw material guide groove is arranged around the flower piece core raw material guide groove 14 and communicated with the outlet of the flow dividing two holes 10. The flower piece edge raw material guide holes are distributed in the flower piece edge raw material guide grooves and lead to the other side of the flow guide die, so that the raw materials extruded from the flow dividing two holes 10 are extruded out along the flower piece edge raw material guide holes. The outline shape of the flower core material forming groove 22 is adapted to the design shape of the flower core. The outline shape of the flower core material forming groove 22 may be "Fu" shape, or "shou" shape, or "xi" shape, or may be other shapes, or may be a flower shape, a grass shape, an animal shape, or the like. The groove depth of the flower piece core raw material forming groove 22 is 3cm, and the preferable numerical value range of the groove depth of the flower piece core raw material forming groove 22 is 0.8-5 cm. The flower piece core raw material forming groove 22 corresponds to the flower piece core raw material guide hole 15 and is communicated with the outlet of the flower piece core raw material guide hole 15. The control mold 7 is fixed behind the guide mold 13 through a fixing part; the control mold 7 is provided with a trumpet-shaped inlet and an outlet which is matched with the outline shape of the flower piece; the inlet and the outlet of the control module 7 are communicated through a transition arc; the trumpet-shaped inlet of the control mold 7 is communicated with the flower piece side raw material guide hole 12 and the flower piece core raw material forming groove 22 of the guide mold 13, so that the flower piece core raw material and the flower piece side raw material are compressed into a whole through the control mold 7 and extruded out along the outlet of the control mold 7.

In order to make the production and processing more convenient and the replacement of the flower chip core raw material forming groove more simple and convenient, the flower chip core forming device also comprises a forming die 19. The forming die 19 is provided with a flower piece core raw material forming hole 23 and a flower piece edge raw material forming hole 18. The flower piece core raw material forming hole 23 corresponds to the flower piece core raw material guide hole 15 and is communicated with the outlet of the flower piece core raw material guide hole 15. The flower piece core raw material forming groove 22 is communicated with the outlet of the flower piece core raw material guide hole 15 through the flower piece core raw material forming hole 23. The flower piece edge raw material forming holes 18 correspond to the flower piece edge raw material guide holes 12 and are communicated with outlets of the flower piece edge raw material guide holes 12. The outlets of the sheet edge material forming holes 18 are distributed around the sheet core material forming grooves 22.

In order to produce the flower slices with more complicated shapes and patterns, the flower slice has richer patterns and shapes of the flower slice core, higher working efficiency and higher economic benefit, and the flower slice also comprises a third screw conveyor 2 and a third screw conveyor cavity 1. The third screw conveyor 2 is in transmission connection with the power device and is fixed in a third screw conveyor cavity through a bearing. The third screw feeder cavity 1 is provided with a feeding port and a discharging port. The reposition of redundant personnel mould 8 is equipped with reposition of redundant personnel three holes 11, and this reposition of redundant personnel three holes 11 correspond and communicate with the discharge gate in second screw feeder chamber 6 for the raw materials that the discharge gate in third screw feeder chamber came out extrudes along reposition of redundant personnel three holes 11. The guide die 13 is provided with a flower piece interlayer raw material guide groove 17 and a flower piece interlayer raw material guide hole 16. The head end of the flower slice interlayer raw material guide groove 17 is communicated with the outlet of the three shunting holes 11, and the tail end of the flower slice interlayer raw material guide groove is arranged around the flower slice core raw material guide groove 14. The flower piece interlayer raw material guide holes 16 are distributed in the tail end of the flower piece interlayer raw material guide groove 17. The forming die 19 is provided with a flower piece interlayer raw material forming hole 21 and a flower piece interlayer raw material forming groove 20. The flower piece interlayer raw material forming holes 21 correspond to the flower piece interlayer raw material guide holes 16 and are communicated with outlets of the flower piece interlayer raw material guide holes 16. The flower piece interlayer raw material forming holes 21 are communicated with the flower piece interlayer raw material forming grooves 20, and the flower piece interlayer raw material forming grooves 20 are arranged around the flower piece core raw material forming grooves 22. The outlets of the sheet edge raw material forming holes 18 are distributed around the sheet interlayer raw material forming grooves 20.

In order to make the production and processing simpler and the use more convenient and the operation of replacing the flower piece core raw material forming groove more convenient, the flower piece core raw material forming groove 22 is detachably connected with the guide die 13 or the flower piece core raw material forming groove 22 is detachably connected with the hole 19 of the forming die.

In order to make the mounting and dismounting operations simpler and the use more convenient, the guide die 13 is arranged in the control die 7.

Claims

1. A wafer machine which is characterized in that: the device comprises a discharging device and a forming device, wherein the discharging device comprises a first screw conveyor (4), a second screw conveyor (3), a first screw conveyor cavity (5) and a second screw conveyor cavity (6); the first auger (4) and the second auger (3) are in transmission connection with the power device and are respectively fixed in the first auger cavity (5) and the second auger cavity (6) through bearings; the first auger cavity (5) and the second auger cavity (6) are respectively provided with a feeding port and a discharging port;

the forming device comprises a flow distribution die (8), a flow guide die (13) and a control die (7); the flow dividing die (8) is provided with a first flow dividing hole (9) and a second flow dividing hole (10) which correspond to and are communicated with the discharge holes of the first auger cavity (5) and the second auger cavity (6), and the first flow dividing hole (9) and the second flow dividing hole (10) are communicated from one side to the other side of the flow dividing die (8); the flow dividing die (8) is fixed at the discharge ports of the first auger cavity (5) and the second auger cavity (6), so that raw materials discharged from the discharge ports of the first auger cavity (5) and the second auger cavity (6) are extruded out along the first flow dividing hole (9) and the second flow dividing hole (10) respectively;

the diversion mold (13) is fixedly connected with the flow distribution mold (8); the flow guide die (13) is provided with a flower piece core raw material guide groove (14), a flower piece core raw material guide hole (15), a flower piece edge raw material guide groove, a flower piece edge raw material guide hole (12) and a flower piece core raw material forming groove (22); the head end of the flower piece core raw material guide groove (14) is communicated with the outlet of the first diversion hole (9), the tail end of the flower piece core raw material guide groove is circular or arc-shaped, and the circle center or the arc center of the circular or arc is superposed with the central point of the diversion mold (13); the flower piece core raw material guide hole is arranged in the tail end of the flower piece core raw material guide groove (14), and an outlet of the flower piece core raw material guide hole is communicated to the other side of the flow guide die (13), so that the raw material extruded from the first shunting hole (9) is extruded along the flower piece core raw material guide hole; the flower piece edge raw material guide groove is arranged around the flower piece core raw material guide groove (14) and communicated with an outlet of the second diversion hole (10), and the flower piece edge raw material guide holes are distributed in the flower piece edge raw material guide groove and led to the other side of the diversion die, so that the raw materials extruded from the second diversion hole (10) are extruded along the flower piece edge raw material guide holes; the outline shape of the flower chip core raw material forming groove (22) is adapted to the design shape of the flower chip core; the flower piece core raw material forming groove (22) corresponds to the flower piece core raw material guide hole (15) and is communicated with the outlet of the flower piece core raw material guide hole (15);

the control die (7) is fixed behind the diversion die (13) through a fixing part; the control mold (7) is provided with a trumpet-shaped inlet and an outlet which is matched with the outline shape of the flower piece; the inlet and the outlet of the control module (7) are communicated through a transition arc; the horn-shaped inlet of the control mold (7) is communicated with the flower piece edge raw material guide hole (12) and the flower piece core raw material forming groove (22) of the guide mold (13), so that the flower piece core raw material and the flower piece edge raw material are compressed into a whole through the control mold (7) and extruded out along the outlet of the control mold (7);

the forming die (19) is provided with a flower piece core raw material forming hole (23) and a flower piece edge raw material forming hole (18); the flower piece core raw material forming hole (23) corresponds to the flower piece core raw material guide hole (15) and is communicated with the outlet of the flower piece core raw material guide hole (15); the flower piece core raw material forming groove (22) is communicated with the outlet of the flower piece core raw material guide hole (15) through the flower piece core raw material forming hole (23); the flower piece edge raw material forming hole (18) corresponds to the flower piece edge raw material guide hole (12) and is communicated with an outlet of the flower piece edge raw material guide hole (12); outlets of the flower piece edge raw material forming holes (18) are distributed around the flower piece core raw material forming groove (22);

the device is characterized by also comprising a third auger (2) and a third auger cavity (1), wherein the third auger (2) is in transmission connection with the power device and is fixed in the third auger cavity through a bearing; the third auger cavity (1) is provided with a feeding port and a discharging port; the shunting die (8) is provided with three shunting holes (11), the three shunting holes (11) correspond to and are communicated with the discharge hole of the second auger cavity (6), and raw materials discharged from the discharge hole of the third auger cavity are extruded out along the three shunting holes (11); the flow guide die (13) is provided with a flower piece interlayer raw material guide groove (17) and a flower piece interlayer raw material guide hole (16); the head end of the flower piece interlayer raw material guide groove (17) is communicated with the outlet of the three shunting holes (11), and the tail end of the flower piece interlayer raw material guide groove is arranged around the flower piece core raw material guide groove (14); the flower piece interlayer raw material guide holes (16) are distributed in the tail ends of the flower piece interlayer raw material guide grooves (17); the forming die (19) is provided with a flower piece interlayer raw material forming hole (21) and a flower piece interlayer raw material forming groove (20); the flower piece interlayer raw material forming holes (21) correspond to the flower piece interlayer raw material guide holes (16) and are communicated with outlets of the flower piece interlayer raw material guide holes (16); the flower piece interlayer raw material forming holes (21) are communicated with the flower piece interlayer raw material forming grooves (20), and the flower piece interlayer raw material forming grooves (20) are arranged around the flower piece core raw material forming grooves (22); outlets of the flower piece edge raw material forming holes (18) are distributed around the flower piece interlayer raw material forming grooves (20);

the guide die (13) is arranged in the control die (7).

2. The sheeter of claim 1, wherein: the groove depth of the flower chip core raw material forming groove (22) is 0.8-5 cm.

3. The sheeter of claim 1, wherein: the outline shape of the flower chip core raw material forming groove (22) is a 'Fu' shape or a 'shou' shape or a flower shape or a grass shape or an animal shape.

4. The sheeter of claim 1, wherein: the flower piece core raw material forming groove (22) is detachably connected with the diversion mold (13) or the flower piece core raw material forming groove (22) is detachably connected with the hole of the forming mold (19).