阅读说明：本技术 多功能自动压面机 (Multifunctional automatic noodle press ) 是由 陈煜生 于 2020-12-31 设计创作，主要内容包括：本发明涉公开了多功能自动压面机,包括：壳体,滚面机构,滚面机构包括两个滚面筒,两滚面筒间限定一滚面间距；以及多组切面机构,包括两个切面滚筒,每一切面滚筒上设有切面槽,相邻的切面槽之间形成有切面环；每组切面机构中,任一切面滚筒的切面槽与另一切面滚筒的切面环对齐；其中,多组切面机构的切面槽的宽度相异；其中,壳体的顶部设有滚面进口及切面进口,壳体的底部设有滚面出口及切面出口。(The invention discloses a multifunctional automatic noodle press, which comprises: the rolling mechanism comprises two rolling surface cylinders, and a rolling surface interval is limited between the two rolling surface cylinders; the multiple groups of section mechanisms comprise two section rollers, each section roller is provided with a section groove, and a section ring is formed between every two adjacent section grooves; in each group of section cutting mechanisms, the section cutting groove of any section cutting roller is aligned with the section cutting ring of the other section cutting roller; wherein, the widths of the noodle cutting grooves of the plurality of groups of noodle cutting mechanisms are different; the top of the shell is provided with a rolling surface inlet and a section inlet, and the bottom of the shell is provided with a rolling surface outlet and a section outlet.)

1. The utility model provides a multi-functional automatic oodle maker which characterized in that includes:

a housing; the rolling mechanism is arranged in the shell and comprises two rolling surface cylinders which are arranged in parallel and at intervals and limit a rolling surface interval between the two rolling surface cylinders; and

each group of tangent plane mechanism comprises two tangent plane rollers which are arranged in parallel at intervals, each tangent plane roller is provided with tangent plane grooves which surround the circumference of the tangent plane roller, and tangent plane rings are formed between the adjacent tangent plane grooves; in each group of the section cutting mechanisms, the section cutting groove of any section cutting roller is arranged in a positive alignment with the section cutting ring of the other section cutting roller; the widths of the tangent plane grooves of the tangent plane mechanisms are different;

the top of the shell is provided with a rolling surface inlet corresponding to the rolling surface mechanism, and the bottom of the shell is provided with a rolling surface outlet corresponding to the rolling surface mechanism; and

the top of the shell is provided with a section inlet corresponding to each section mechanism, and the bottom of the shell is provided with a section outlet corresponding to each section mechanism.

2. The multi-functional automatic noodle press of claim 1 further comprising a motor, said two noodle rollers comprising a driving noodle roller having opposite first and second ends and a driven noodle roller having opposite first and second ends; the first end of the driving rolling surface cylinder and the first end of the driven rolling surface cylinder are arranged in the same direction, and the second end of the driving rolling surface cylinder and the second end of the driven rolling surface cylinder are arranged in the same direction; the first end of the driving rolling surface cylinder extends out of the shell and is connected with a motor, and the motor drives the driving rolling surface cylinder to rotate; the second end of the driving rolling surface cylinder is in driving connection with the second end of the driven rolling surface cylinder, and the driving rolling surface cylinder and the driven rolling surface cylinder synchronously roll in different directions.

3. The multifunctional automatic noodle press according to claim 2, wherein the plurality of noodle cutting mechanisms comprise a first noodle cutting mechanism and a second noodle cutting mechanism, and the first and second noodle cutting mechanisms are respectively arranged on two sides of the two noodle rolling cylinders; the second end of the driving dough-cutting drum is connected with and drives one dough-cutting drum adjacent to the driving dough-cutting drum in the second dough-cutting mechanism, and the second end of the driven dough-cutting drum is connected with and drives one dough-cutting drum adjacent to the driving dough-cutting drum in the first dough-cutting mechanism.

4. The multi-function automatic noodle press of claim 3 wherein in each of said noodle mechanisms, two noodle rollers each have opposite first and second ends, the first end of each noodle roller being co-directional with the first end of the active noodle roller, the first ends of the two noodle rollers being drivingly connected to each other.

5. The multifunctional automatic noodle press according to claim 1, wherein two guide strips are provided on each side of each noodle outlet of the housing, and the two guide strips are respectively arranged along the axial extension of two noodle rollers located on each side of the noodle outlet; the guide strip is convexly provided with a plurality of guide blocks, the guide blocks are arranged at intervals along the axial direction of the guide strip, and the guide blocks and the tangent plane grooves of the tangent plane roller are respectively arranged in an aligned mode; the upper part of each guide block extends into a corresponding tangent plane groove and is abutted against the radial inner side wall of the tangent plane groove, and the lower part of each guide block extends towards the tangent plane outlet.

6. The multifunctional automatic noodle press according to claim 1, wherein two guide pieces are respectively provided on both sides of the rolling surface outlet of the housing, the two guide pieces are respectively arranged along the axial extension of two rolling surface rollers located on both sides of the rolling surface outlet, and the guide pieces are respectively attached to the two rolling surface rollers.

7. The multifunctional automatic noodle press according to claim 1, wherein in each noodle cutting mechanism, the noodle ring of any one noodle cutting roller is embedded into the noodle cutting groove of another noodle cutting roller, and the top of the noodle cutting ring is spaced from the bottom of the corresponding noodle cutting groove in the radial direction of the noodle cutting roller; and gaps are respectively arranged between two side edges of the section ring and two side walls of the corresponding section groove along the axial direction of the section roller.

8. The multi-functional automatic noodle press according to claim 2, wherein said driven roller comprises an outer sleeve and a central shaft, said central shaft being coaxially disposed with said outer sleeve; the central shaft penetrates through the outer sleeve and can rotate relative to the outer sleeve, one end of the central shaft penetrates through the end of the outer sleeve to form an operation section which is rotatably connected to the shell, and the operation section and the central shaft are eccentrically arranged; the rotation of the operation section drives the central shaft to eccentrically rotate, and the central shaft eccentrically rotates to drive the driven rolling surface cylinder to move towards or depart from the driving rolling surface cylinder.

9. The multifunctional automatic noodle press according to claim 3, further comprising a plurality of gears, a first gear fixed to the second end of the driving noodle roll, a second gear fixed to the second end of the driven noodle roll, a third gear fixed to the noodle roll drivingly connected to the second end of the driving noodle roll, a fourth gear fixed to the noodle roll drivingly connected to the second end of the driven noodle roll, the third gear, the first gear, the second gear and the fourth gear being arranged in radial sequence and meshing with each other; the first ends of the two tangent plane rollers of each tangent plane mechanism are in driving connection through one group of the gears.

10. The multifunctional automatic noodle press according to claim 9, wherein the housing comprises an upper housing and a lower housing, the lower housing is open at one side, the upper housing is adapted to be connected with the lower housing and close the opening, the upper housing and the lower housing together enclose and define a containing cavity, and the noodle rolling mechanism and the plurality of noodle cutting mechanisms are arranged in the containing cavity in parallel.

11. The multifunctional automatic noodle press according to claim 10, wherein the lower housing comprises a first mounting plate and a second mounting plate which are oppositely arranged, the first end of the driving noodle roller, the first end of the driven noodle roller and the first ends of the two noodle rollers of each noodle cutting mechanism are rotatably arranged in the first mounting plate, and the second end of the driving noodle roller, the second end of the driven noodle roller and the second ends of the two noodle rollers of each noodle cutting mechanism are rotatably arranged in the second mounting plate.

12. The multi-functional automatic noodle press of claim 11, further comprising a first panel and a second panel disposed on the lower housing, the first panel being juxtaposed and spaced from the first mounting plate, at least two intermeshing gears of the plurality of gears being disposed between the first panel and the first mounting plate; the second panel is juxtaposed with and spaced from the second mounting plate, and at least two intermeshing gears of the plurality of gears are disposed between the second panel and the second mounting plate.

13. The multi-functional automatic noodle press according to claim 1, wherein the opening cross-sectional dimensions of said dough rolling inlet and said dough slicing inlet decrease from the outside of said housing to the inside of said housing.

14. The multifunctional automatic noodle press according to claim 5, further comprising a plurality of support bars, each support bar being disposed corresponding to one of the guide bars, and each support bar and one of the noodle rollers together defining one of the guide bars between the support bar and the noodle roller.

15. The multi-functional automatic noodle press according to claim 6, further comprising two support tabs, each of said support tabs being connected to one of said guide tabs by an elastically deformable elastic member.

16. The multi-functional automatic noodle press according to claim 8, further comprising a knob fixedly connected to the operating section of the central shaft.

17. The multi-functional automatic noodle press according to claim 2, wherein the active first end has a square cross-section.

18. The multi-functional automatic noodle press according to claim 16, wherein the knob comprises a metering scale disposed thereon in a rotational direction, and the second panel comprises a pointer aligned with the metering scale.

19. The multi-functional automatic noodle press of claim 8 wherein said operating section further comprises a positioning port extending axially along said central shaft.

20. The multi-functional automatic noodle press of claim 19, wherein said first panel further comprises a protective sleeve extending axially of said active roller, said active first end of said active roller passing through and protruding from said protective sleeve.

Technical Field

The invention relates to the technical field of noodle presses, in particular to a multifunctional automatic noodle press.

Background

The wheaten food is one of staple foods in people's lives all the time, and in most areas of the world, the wheaten food is basically used as a complete staple food.

The kinds of wheaten food are many, and mainly noodles are used as main materials. By mixing flour with water and kneading, a dough is finally formed, and the dough is pulled or cut into noodles.

Among the prior art, for more efficient preparation noodless etc. various types of oodle maker has appeared on the market, and can be with the dough sheet automatic cutout of opening for noodless, improve preparation efficiency greatly, however, current oodle maker's function singleness, and can only be to the noodless preparation of single width, the suitability is relatively poor, can not satisfy the diversified preparation requirement of noodless.

Disclosure of Invention

The invention aims to provide a multifunctional automatic noodle press, and aims to solve the problems of single function and poor applicability of the noodle press in the prior art.

The invention is realized in this way, the multi-functional automatic flour-pressing machine, including: the rolling mechanism comprises two rolling surface cylinders which are arranged in parallel at intervals and limit a rolling surface interval between the two rolling surface cylinders; each tangent plane mechanism comprises two tangent plane rollers which are arranged in parallel at intervals, each tangent plane roller is provided with tangent plane grooves which surround the circumference of the tangent plane roller, and tangent plane rings are formed between the adjacent tangent plane grooves; in each group of section cutting mechanisms, the section cutting groove of any section cutting roller is arranged in a positive alignment with the section cutting ring of the other section cutting roller; wherein, the widths of the noodle cutting grooves of the plurality of groups of noodle cutting mechanisms are different; the top of the shell is provided with a rolling surface inlet corresponding to the rolling surface mechanism, and the bottom of the shell is provided with a rolling surface outlet corresponding to the rolling surface mechanism; and the top of the shell is provided with a section inlet corresponding to each section mechanism, and the bottom of the shell is provided with a section outlet corresponding to each section mechanism.

In some embodiments, the device further comprises a motor, wherein the two roller drums comprise a driving roller drum and a driven roller drum, the driving roller drum is provided with a first end and a second end which are opposite, and the driven roller drum is provided with a first end and a second end which are opposite; the first end of the driving rolling surface cylinder and the first end of the driven rolling surface cylinder are arranged in the same direction, and the second end of the driving rolling surface cylinder and the second end of the driven rolling surface cylinder are arranged in the same direction; the first end of the driving rolling surface cylinder extends out of the shell and is connected with a motor, and the motor drives the driving rolling surface cylinder to rotate; the second end of the driving rolling surface cylinder is in driving connection with the second end of the driven rolling surface cylinder, and the driving rolling surface cylinder and the driven rolling surface cylinder synchronously roll in different directions.

In some embodiments, the plurality of groups of noodle cutting mechanisms comprise a first noodle cutting mechanism and a second noodle cutting mechanism, and the first noodle cutting mechanism and the second noodle cutting mechanism are respectively arranged at two sides of the two noodle rolling cylinders; the second end of the driving dough-cutting roller is connected with and drives one dough-cutting roller adjacent to the driving dough-cutting roller in the second dough-cutting mechanism, and the second end of the driven dough-cutting roller is connected with and drives one dough-cutting roller adjacent to the driving dough-cutting roller in the first dough-cutting mechanism.

In some embodiments, in each of the slitting mechanisms, the two slitting rollers each have opposite first and second ends, the first end of each of the slitting rollers is disposed in a direction co-current with the first end of the active roller, and the first ends of the two slitting rollers are drivingly connected to each other.

In some embodiments, two guide strips are respectively arranged on two sides of each section outlet of the shell, and the two guide strips are respectively arranged along the axial extension of two section rollers positioned on two sides of the section outlet; a plurality of guide blocks are arranged on the guide strip in a protruding mode, the guide blocks are arranged at intervals along the axial direction of the guide strip, and the guide blocks are arranged in alignment with the tangent plane grooves of the tangent plane roller respectively; the upper part of each guide block extends into a corresponding tangent plane groove and is abutted against the radial inner side wall of the tangent plane groove, and the lower part of each guide block extends towards the tangent plane outlet.

In some embodiments, two guide pieces are respectively arranged on two sides of the rolling surface outlet of the shell, the two guide pieces are respectively arranged along the axial extension of the two rolling surface cylinders positioned on two sides of the rolling surface outlet, and the guide pieces are respectively attached to the two rolling surface cylinders.

In some embodiments, in each section mechanism, the section ring of any section roller is embedded into the section groove of another section roller, and the top of the section ring is spaced from the bottom of the corresponding section groove along the radial direction of the section roller; in the axial direction of the section roller, gaps are respectively arranged between two side edges of the section ring and two side walls of the corresponding section groove.

In some embodiments, the driven rolling surface cartridge comprises an outer sleeve and a central shaft, the central shaft being arranged coaxially with the outer sleeve; the central shaft penetrates through the outer sleeve and can rotate relative to the outer sleeve, one end of the central shaft penetrates through the end of the outer sleeve to form an operation section which is rotatably connected to the shell, and the operation section and the central shaft are eccentrically arranged; the rotation of the operation section drives the central shaft to eccentrically rotate, and the central shaft eccentrically rotates to drive the driven rolling surface cylinder to move towards or depart from the driving rolling surface cylinder.

In some embodiments, the cutting device further comprises a plurality of gears, wherein a first gear is fixed at the second end of the driving rolling surface cylinder, a second gear is fixed at the second end of the driven rolling surface cylinder, a third gear is fixed on the tangent plane roller in driving connection with the second end of the driving rolling surface cylinder, a fourth gear is fixed on the tangent plane roller in driving connection with the second end of the driven rolling surface cylinder, and the third gear, the first gear, the second gear and the fourth gear are sequentially arranged in the radial direction and are mutually meshed; wherein, the first ends of the two tangent plane rollers of each tangent plane mechanism are in driving connection through one group of a plurality of gears.

In some embodiments, the housing comprises an upper shell and a lower shell, one side of the lower shell is open, the upper shell is suitable for being connected with the lower shell and closing the opening, the upper shell and the lower shell jointly surround and define a containing cavity, and the rolling surface mechanism and the plurality of tangent plane mechanisms are arranged in the containing cavity in parallel.

In some embodiments, the lower casing includes a first mounting plate and a second mounting plate which are oppositely arranged, the first end of the driving dough-rolling cylinder, the first end of the driven dough-rolling cylinder and the first ends of the two dough-cutting rollers of each dough-cutting mechanism are rotatably arranged in the first mounting plate, and the second end of the driving dough-rolling cylinder, the second end of the driven dough-rolling cylinder and the second ends of the two dough-cutting rollers of each dough-cutting mechanism are rotatably arranged in the second mounting plate.

In some embodiments, the case further comprises a first panel and a second panel disposed on the lower case, the first panel being juxtaposed and spaced apart from the first mounting plate, at least two intermeshing gears of the plurality of gears being disposed between the first panel and the first mounting plate; the second panel is side by side with the second mounting panel and interval, and the gear setting of two at least intermeshing in a plurality of gears is between second panel and second mounting panel.

In some embodiments, the open cross-sectional dimension of the roll-face inlet and the tangential-face inlet decreases from the outside of the housing to the inside of the housing.

In some embodiments, the cutting machine further comprises a plurality of supporting rods, each supporting rod is arranged corresponding to one guide strip, and each supporting rod and one section roller define one guide strip between each supporting rod and each section roller.

In some embodiments, the device further comprises two support plates, and each support plate is connected with one guide plate through one elastic piece capable of elastic deformation.

In some embodiments, the device further comprises a knob, and the knob is fixedly connected with the operation section of the central shaft.

In some embodiments, the active first end is square in cross-section.

In some embodiments, the knob includes a metering scale disposed thereon in the rotational direction, and the second panel has a pointer disposed thereon in alignment with the metering scale.

In some embodiments, the operating section further comprises a positioning port extending axially along the central axis.

In some embodiments, the first panel further comprises a protective sleeve extending in an axial direction of the active roller, the active first end of the active roller passing through and protruding from the protective sleeve. .

Compared with the prior art, the multifunctional automatic noodle press provided by the invention has the advantages that the dough can be rolled into a dough sheet by arranging the two noodle rolling cylinders, and the noodle cutting mechanisms are arranged in a plurality of groups, and the noodle cutting grooves of the noodle cutting mechanisms are different and different, so that the noodle cutting can be carried out by using the appropriate noodle cutting mechanism according to actual needs, and the noodle press and the noodles with different widths can be manufactured on the same noodle press, so that the multifunctional automatic noodle press is diversified in function and wide in applicability.

Drawings

FIG. 1 is a schematic top perspective view of one embodiment of the multi-functional automatic noodle press provided by the present invention;

FIG. 2 is a bottom perspective view of the multi-functional automatic noodle press of FIG. 1;

FIG. 3 is an exploded perspective view of the multi-functional automatic noodle press of FIG. 1;

FIG. 4 is another exploded perspective view of the multi-functional automatic noodle press of FIG. 1;

FIG. 5 is a cross-sectional view of the multi-functional automatic noodle press of FIG. 1;

FIG. 6 is a front view of the multi-function automatic noodle press of FIG. 1 with the second panel and knob removed;

FIG. 7 is a rear view of the multi-function automatic noodle press of FIG. 1 with the first panel removed;

FIG. 8 is another cross-sectional view of the multi-functional automatic noodle press of FIG. 1;

FIG. 9 is a perspective view of a first dough cutting mechanism portion of the multi-function automatic dough press of FIG. 1;

FIG. 10 is a perspective view of a second cutting mechanism portion of the multi-function automatic noodle press of FIG. 1;

fig. 11 is a schematic view of the multifunctional automatic noodle maker of fig. 1 connected to a motor.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

The following describes the implementation of the present invention in detail with reference to specific embodiments.

The same or similar reference numerals in the drawings of the present embodiment correspond to the same or similar components; in the description of the present invention, it should be understood that if there is an orientation or positional relationship indicated by the terms "upper", "lower", "left", "right", etc. based on the orientation or positional relationship shown in the drawings, it is only for convenience of describing the present invention and simplifying the description, but it is not intended to indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and therefore, the terms describing the positional relationship in the drawings are only used for illustrative purposes and are not to be construed as limiting the present patent, and the specific meaning of the terms may be understood by those skilled in the art according to specific circumstances.

Fig. 1 to 4 show a multifunctional automatic noodle maker 100 according to an embodiment of the present invention, wherein the multifunctional automatic noodle maker 100 comprises a housing 10, in this embodiment, the housing 10 is approximately rectangular, and a noodle rolling mechanism 30 and a plurality of noodle cutting mechanisms 20 and 40 are arranged inside the housing 10. In the embodiment, the cutting device comprises a first cutting mechanism 20 and a second cutting mechanism 40, which are respectively located at two sides of the rolling mechanism. The rolling mechanism 30 includes a driving roller 34 and a driven roller 32, which are parallel and spaced apart and are substantially cylindrical. The first slitting mechanism 20 and the second slitting mechanism 40 each comprise two parallel and spaced-apart slitting drums, the first slitting mechanism 20 comprises a first slitting drum 22 and a second slitting drum 24, and the second slitting mechanism 40 comprises a third slitting drum 42 and a fourth slitting drum 44. In the present embodiment, the first cutting drum 22, the second cutting drum 24, the driven cutting drum 32, the driving cutting drum 34, the third cutting drum 42 and the fourth cutting drum 44 are sequentially arranged in parallel with each other and spaced apart from each other on the same plane.

The top and the bottom of the casing 10 are respectively provided with a dough inlet 124 and a dough outlet 144 corresponding to the dough rolling mechanism, the dough inlet 124 is used for the dough to enter, and the dough outlet 144 is used for the molded dough sheet to exit. The top and the bottom of the casing 10 are respectively provided with a noodle inlet 122, 126 and a noodle outlet 142, 146 corresponding to each noodle cutting mechanism 20,40, the noodle inlet 122, 126 is used for the dough sheet to enter, and the noodle outlet 142, 146 is used for the cut noodles to come out. Referring to fig. 5 and 9, fig. 9 is a perspective view of the first dough cutting mechanism 20 of the present embodiment, wherein the first dough cutting roller 22 and the second dough cutting roller 24 are substantially cylindrical, and each of the first dough cutting roller and the second dough cutting roller has an annular dough cutting groove 244 circumferentially disposed around the barrel, and a dough cutting ring 242 is formed between adjacent dough cutting grooves 244. In the first tangent plane mechanism 20, the tangent plane groove 244 of each tangent plane roller 22 is aligned with the tangent plane ring 242 of the other tangent plane roller 24, and each tangent plane ring 242 extends into the corresponding tangent plane groove 244, and the width of the tangent plane ring 242 is slightly smaller than the width of the tangent plane groove 244 in the axial direction, so that gaps are formed between two side edges of the tangent plane ring 242 and two side walls of the corresponding tangent plane groove 244. In addition, in the radial direction of the first or second tangential roller, there is a space between the top of the tangential ring 242 and the bottom of the corresponding tangential groove 244, and the size and shape of the space can define the size and shape of the cut noodles.

Similarly, fig. 10 shows a perspective view of the second noodle cutting mechanism 40 in the present embodiment, wherein the second noodle cutting mechanism 40 has a substantially same structure as the first noodle cutting mechanism 20, and the third and fourth noodle cutting drums 42, 44 of the second noodle cutting mechanism 40 also have a substantially cylindrical shape, and are provided with noodle cutting grooves 444, and noodle cutting rings 442 are formed between the adjacent noodle cutting grooves 444, each noodle cutting ring 442 is aligned with and extends into the noodle cutting groove 444 of the other noodle cutting drum, except that the widths of the noodle cutting rings 442 and the noodle cutting grooves 444 of the third and fourth noodle cutting drums 42, 44 are greater than the widths of the noodle cutting grooves 244 and the noodle cutting rings 242 of the first and second noodle cutting drums 22, 24, and therefore, the noodle strips cut by the second noodle cutting mechanism 40 are wider than the noodle strips cut by the first noodle cutting mechanism 20.

Referring to fig. 8, 9 and 10, two guide bars 21 are respectively disposed at the bottom of the first tangent plane roller 22 and the second tangent plane roller 24 and are parallel to the axial direction of the first tangent plane roller 22 and the second tangent plane roller 24, a plurality of guide blocks 212 are convexly disposed on the guide bars 21, the plurality of guide blocks 212 are arranged at intervals along the axial direction of the guide bars 21, the plurality of guide blocks 212 are respectively aligned with a plurality of tangent plane grooves 244 of the first tangent plane roller 22 and the second tangent plane roller 24, the upper portion of each guide block 212 extends towards the tangent plane inlet 122 and into one corresponding tangent plane groove 244 and abuts against the radial inner side wall of the tangent plane groove 244, and the lower portion of each guide block 212 extends away from the upper portion of the guide block 212 towards the tangent plane outlet 142. A support bar 50 is correspondingly disposed below each guide bar 21, the support bar 50 is arranged in parallel with the guide bar 21, and each support bar 50 and one of the first tangent-plane roller 22 and the second tangent-plane roller 24 together limit the corresponding guide bar 21 therebetween, thereby limiting the position of the guide bar 21. Similarly, two guide bars 41 are respectively arranged at the bottom of the third tangent-plane roller 42 and the fourth tangent-plane roller 44 and are parallel to the axial direction of the third tangent-plane roller 42 and the fourth tangent-plane roller 44, the structure of the guide bars 41 is also similar to that of the guide bars 21, a plurality of guide blocks 412 which are arranged at intervals along the axial direction of the guide bars 41 are convexly arranged on the guide bars 41, the plurality of guide blocks 412 are respectively aligned with the tangent-plane grooves 444 of the third tangent-plane roller 42 and the fourth tangent-plane roller 44, the upper parts of the guide blocks 412 extend towards the tangent-plane inlet 126 and are abutted against the inner sides of the tangent-plane grooves 444, and the lower parts of the guide blocks 412 extend. Except that the guide blocks 412 of the guide bars 41 have a width greater than that of the guide blocks 212 of the guide bars 21, and each guide bar 41 is confined between the corresponding support bar 50 and the bottom of one of the third and fourth tangent-plane rollers 42 and 44. The guide block 212 and the guide block 412 are used to provide a guide for the cut noodles such that the cut noodles are discharged from between the first and second cutting drums 22 and 24 or between the third and fourth cutting drums 42 and 44. Wherein the position of the tangent inlet 122 and tangent outlet 142 is aligned with the middle of the first tangent plane roller 22 and the second tangent plane roller 24, and the position of the tangent inlet 126 and tangent outlet 146 is aligned with the middle of the third tangent plane roller 42 and the fourth tangent plane roller 44. This allows the dough sheet to enter through the dough inlet 122 or 126, drive the dough between the two dough rollers by the first or second dough cutting mechanism 20 or 40, and cut the dough into noodles, which are then discharged through the dough outlet 146 or 142.

In the present embodiment, the opening cross-sectional dimensions of the rolling inlet 124 and the tangential inlets 122, 126 gradually decrease from the outside of the casing 10 to the inside of the casing 10. Thus, after the dough sheet enters between the two dough cutting cylinders of the first dough cutting mechanism 20 and the second dough cutting mechanism 40, the dough sheet is extruded in the dough cutting groove and is extruded and cut by the two sides of the dough cutting ring, so that the dough sheet is cut into a plurality of dough strips, the thickness of the dough strips is related to the depth of the dough cutting groove, and the width of the dough strips is related to the width of the dough cutting ring. The thickness of the noodle strip can be changed by adjusting the distance between the noodle cutting ring and the bottom of the noodle cutting groove.

The bottom of the driving roller 34 is further provided with a substantially sheet-shaped guide piece 394, the bottom of the driven roller 32 is further provided with a substantially sheet-shaped guide piece 384, the guide piece 394 and the guide piece 384 extend in the axial direction of the driving roller 34 and the driven roller 32 and are oppositely arranged, the guide piece 394 and the guide piece 384 respectively fit the outer peripheries of the driving roller 34 and the driven roller 32, and the guide piece 394 and the guide piece 384 are used for guiding the rolled dough sheet so that the manufactured dough sheet is discharged from the space between the driving roller 34 and the driven roller 32. The support piece 382 and the support piece 392, which are plate-shaped, are fixedly connected to the housing 10, wherein the support piece 382 is connected to the guide piece 384 by an elastically deformable elastic member 383, and the support piece 392 is connected to the guide piece 394 by an elastically deformable elastic member 393, so that the guide piece 384 and the guide piece 394 are elastically supported.

A rolling surface spacing 320 is defined between the driving roller 34 and the driven roller 32, wherein the location of the rolling surface entry 124 and the rolling surface exit 144 are aligned with the intermediate rolling surface spacing 320 of the driving roller 34 and the driven roller 32. Thus, dough enters through the dough inlet 124, travels through the dough gap 320 under the drive of the two dough rollers, is extruded into a sheet under the extrusion of the two dough rollers, and exits through the dough outlet 144. Referring to fig. 3 to 5, in the present embodiment, the housing 10 includes an upper shell 12 and a lower shell 14, the lower shell 14 is substantially in the shape of a rectangular parallelepiped shell with one side open, the upper shell 12 is adapted to close the opening, the upper shell 12 and the lower shell 14 together define a housing chamber 148, and the first tangent-plane roller 22, the second tangent-plane roller 24, the driven tangent-plane roller 32, the driving tangent-plane roller 34, the third tangent-plane roller 42 and the fourth tangent-plane roller 44 are sequentially disposed in parallel in the housing chamber 148. The lower shell 14 further includes a first mounting plate 18 and a second mounting plate 19, wherein the first mounting plate 18 and the second mounting plate 19 are respectively disposed at two axial sides of the driving dough roller 34, the driving dough roller 34 and the driven dough roller 32, and two dough cutting rollers of the first dough cutting mechanism 20 and the second dough cutting mechanism 40 are respectively disposed between the first mounting plate 18 and the second mounting plate 19, and the two dough cutting rollers of the driving dough roller 34, the driven dough roller 32, the first dough cutting mechanism 20, and the second dough cutting mechanism 40 respectively have a first end and a second end, the first ends of the plurality of rollers, and the first end 344 of the driving dough roller 34 and the first end 328 of the driven dough roller 32 are rotatably inserted into the first mounting plate 18, and the second ends of the plurality of dough rollers and the rollers are rotatably inserted into the second mounting plate 19.

Referring additionally to fig. 6 and 7, the first end 226 of the first tangent-plane roller 22, the first end 246 of the second tangent-plane roller 24, the first end 426 of the third tangent-plane roller 42, and the first end 446 of the fourth tangent-plane roller 44 all project axially from the first mounting plate 18. A first gear set 26 and a second gear set 46 are further disposed on the outer side of the first mounting plate 18, wherein the first gear set 26 includes two gears engaged with each other, and the two gears are fixedly connected to the first end 226 of the first tangent plane roller 22 and the first end 246 of the second tangent plane roller 24, respectively; and the second gear set 46 comprises two intermeshing gears fixedly connected to the first end 426 of the third tangent-surface cylinder 42 and the first end 446 of the fourth tangent-surface cylinder 44, respectively. The second end 342 of the driving facet cylinder 34, the second end 324 of the driven facet cylinder 32, the second end 248 of the second facet cylinder 24, and the second end 428 of the third facet cylinder 42 all project axially from the second mounting plate 19. A first gear 37, a second gear 35, a third gear 48 and a fourth gear 28 are arranged on the outer side of the second mounting plate 19, wherein the first gear 37 is fixedly connected with the second end 342 of the driving roller 34, the second gear 35 is fixedly connected with the second end 324 of the driven roller 32, the third gear 48 is fixedly connected with the second end 248 of the second tangent-plane roller 24, and the fourth gear 28 is fixedly connected with the second end 428 of the third tangent-plane roller 42. The third gear 48, the first gear 37, the second gear 35 and the fourth gear 28 are sequentially engaged with each other in a radial direction, so that the rotation of the driving dough roller 34 can cause the rotation of the driven dough roller 32 and the third dough cutting roller 42 respectively through the engagement of the first gear 37 with the second gear 35 and the third gear 48, and the rotation of the second gear 35 in turn causes the rotation of the second dough cutting roller 24 through the engagement thereof with the fourth gear 28, further, the rotation of the third dough cutting roller 42 is transmitted to the fourth dough cutting roller 44 through the second gear set 46, and the rotation of the second dough cutting roller 24 is transmitted to the first dough cutting roller 22 through the first gear set 26. Therefore, synchronous rotation in different directions between the driving roller 34 and the driven roller 32 can be realized, and the first noodle cutting mechanism 20 and the second noodle cutting mechanism 40 can be driven by the rotation of the driving roller 34, so that synchronous rotation in different directions is formed between the two noodle cutting cylinders of the first noodle cutting mechanism 20 and the second noodle cutting mechanism 40. Thus, for the two tangent cylinders of the first tangent mechanism 20 and the second tangent mechanism 40, the first end is driven by the driving roller 34 or the driven roller 32, and the second end is meshed with each other through the first gear set 26 or the second gear set 46, so that the distribution of the engaging force between the two tangent cylinders along the axial direction of the tangent cylinders is more uniform, and better tangent effect is achieved.

In this embodiment, a first panel 145 and a second panel 147 are further fixedly disposed on the outer side of the lower shell 14, the first panel 145 and the first mounting plate 18 are disposed side by side and spaced apart from each other, the first gear set 26 and the second gear set 46 are disposed between the first panel 145 and the first mounting plate 18, and the first gear set 26 and the second gear set 46 are defined on the first ends of the tangent plane rollers by a plurality of clamp springs 46; the second panel 147 is juxtaposed to and spaced from the second mounting plate 19, the first gear 37, the second gear 35, the third gear 48 and the fourth gear 28 are disposed between the second panel 147 and the second mounting plate 19, and the first gear 37, the second gear 35, the third gear 48 and the fourth gear 28 are defined on the second end of the plurality of tangent or roll cylinders by a plurality of circlips 27. Preferably, the first or second end of the tangent-surface roller or roller-surface rollers forms an anti-rotation positive fit with the respective gear wheel. The first panel 145 further includes a protective cylinder 143 extending in an axial direction of the active roller 34, and an active first end 344 of the active roller 34 passes through and protrudes from the protective cylinder 143.

Referring to fig. 6, the driven roller barrel 32 includes an outer sleeve 329 movably arranged and a central shaft 322, the central shaft 322 is inserted into the outer sleeve 329 and coaxially arranged with the outer sleeve 329, and the central shaft 322 can rotate relative to the outer sleeve 329; one end of the central shaft 322 passes through the end of the outer sleeve 329 to form an operation section 325 rotatably connected to the housing 10, and the operation section 325 is eccentrically arranged with respect to the central shaft 322; rotation of the operating section 325 causes the central shaft 322 to rotate eccentrically, which central shaft 322 rotates eccentrically to drive the driven roller 32 toward or away from the driving roller 34. Thus, by rotating the operation segment 325, the user can drive the driven roller 32 to move towards or away from the driving roller 34, so as to realize the change of the rolling distance 320 between the driving roller 34 and the driven roller 32 and control the thickness of the dough sheet.

Referring to fig. 1 again, in the present embodiment, a knob 80 is fixedly connected to the operation section 325. The operation section 325 is movably disposed through the knob 80, and the operation section 325 is provided with a positioning opening 327 for limiting the rotation of the knob 80 relative to the operation section 325, the positioning opening 327 is a notch formed at an end of the operation section 325 and extending along an axial direction, and the knob 80 is provided with a receiving groove matched with the notch in shape, so as to prevent the knob 80 and the operation section 325 from rotating relative to each other. Preferably, the knob 80 is provided with a scale 81, and the housing 10 is fixedly provided with a pointer 149, so that when the pointer 149 corresponds to different scales 81, the rolling surface interval 320 is different in size, which is convenient for a user to adjust.

Referring to fig. 1 and 11, a first end 344 of the driving roller 34 extends out of the housing 10, the first end 344 of the driving roller 34 is connected to the motor 70, and the motor 70 is used to drive the driving roller 34 to rotate, thereby causing the rotation of the two dough cutting cylinders of the first dough cutting mechanism 20 and the second dough cutting mechanism 40. In this embodiment, the first end 344 of the active roller 34 is square in radial cross-section to facilitate connection to an output shaft or coupling of a motor, although it will be appreciated that the first end may include other shapes, such as splined or externally threaded. And between the driving roller and the driven roller, the motor driving part and the gear meshing part are separately arranged, so that the rolling force between the driving roller and the driven roller is more balanced, and the thickness of the rolled dough sheet is more uniform. And the same motor is used for driving a plurality of dough rolling cylinders and a plurality of dough cutting mechanisms to rotate, so that the number of required motors is reduced, and the structure of the whole automatic dough pressing machine is more compact.

Above-mentioned multi-functional automatic oodle maker that provides can be the dough piece with the dough roll extrusion through setting up dough rolling mechanism, and sets up multiunit tangent plane mechanism, and the tangent plane groove of multiunit tangent plane mechanism is different, the diverse, like this, then can be according to actual need, the tangent plane mechanism that needs to be fit for carries out the tangent plane, on same oodle maker, then can carry out the preparation of oodle maker and different width noodless simultaneously, the function is diversified, extensive applicability.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents and improvements made within the spirit and principle of the present invention are intended to be included within the scope of the present invention.