CN220326659U - Noodle machine capable of preventing adhesion of noodles - Google Patents

Abstract

The utility model discloses a noodle machine for preventing adhesion of a noodle surface, which comprises: host computer, crowded face pole and play face section of thick bamboo, play face section of thick bamboo is provided with a plurality of play face holes, and fan subassembly is installed to the host computer, and fan subassembly includes: a fan and an air outlet cover; the air outlet cover is provided with a longitudinal maximum air outlet angle alpha and a transverse maximum air outlet angle beta; the vertical lines of the plurality of face holes fall in the area of the transverse maximum air outlet angle beta, and the vertical lines of the plurality of face holes are not overlapped in the air outlet direction; when the noodle is out of the noodle, the noodle falls vertically under the action of gravity, the noodle is acted by wind force of the fan assembly in the falling process, and as the vertical lines of the plurality of noodle outlet holes are not overlapped in the air outlet direction, namely each noodle is not overlapped in the air outlet direction, each noodle can be acted by wind force in the area of the transverse maximum air outlet angle beta, and in the falling process, the noodle can be acted by wind force in a certain vertical distance, and the anti-adhesion effect of the noodle is achieved through the non-overlapping and wide-angle air outlet among the noodles.

Description

Noodle machine capable of preventing adhesion of noodles

Technical Field

The utility model relates to the technical field of noodle machines, in particular to a noodle machine with an anti-adhesion surface.

Background

The noodle machine in the current market has the functions of kneading dough and extruding to prepare noodles, and when the noodle machine is used, raw materials (water, flour and the like) are only needed to be added into the noodle machine manually, so that the noodles can be automatically prepared, but one disadvantage of the existing noodle machine is that the prepared noodles are stacked in the discharging process or the receiving tray, are easy to adhere, and are not easy to shake when the noodles are processed later. Therefore, in the prior art, the purpose of preventing adhesion is achieved by changing the distribution of the holes of the noodle, such as Chinese patent number: 201420208048.7 an anti-adhesion noodle machine comprises a main machine, wherein the main machine is provided with a noodle extruding cylinder, a die head for noodle surface is fixed on the noodle extruding cylinder, the die head is provided with a plurality of noodle outlet holes, the noodle extruding cylinder and the die head are transversely arranged, the vertical lines passing through the centers of two adjacent noodle outlet holes are not overlapped, so that every two adjacent noodle outlet holes are staggered in the vertical direction, and round surfaces are hardly adhered together; the above-mentioned technique is through crisscross distribution with the hole that appears to reduce the overlapping of noodless, reaches the purpose of preventing the adhesion, but in the full-automatic noodless machine, the dough that just prepares, the noodless moisture ratio of making is great, even overlap the part less, and its possibility of adhesion is also higher, consequently, need increase the fan function on the noodless machine, weathers noodless.

Disclosure of Invention

In view of the above, the utility model provides a noodle machine with crisscross wide-angle air outlet and staggered surface holes for preventing surface adhesion.

In order to achieve the above purpose, the present utility model adopts the following technical scheme: a noodle machine for preventing sticking on a noodle surface, comprising: host computer, crowded face pole and play face section of thick bamboo, be provided with a plurality of play face holes of a face section of thick bamboo, crowded face pole is to dough propelling movement extrusion out the noodless through the face hole, fan subassembly is installed to the host computer, and fan subassembly acts on play face hole below, and fan subassembly includes: a fan and an air outlet cover;

the air outlet cover is provided with a longitudinal maximum air outlet angle alpha and a transverse maximum air outlet angle beta; the vertical lines of the plurality of face holes fall in the area of the transverse maximum air outlet angle beta, and the vertical lines of the plurality of face holes are not overlapped in the air outlet direction;

when the noodle of this technical scheme was out face, the noodless were vertical whereabouts under the action of gravity, whereabouts in-process received the wind-force effect of fan subassembly, because the perpendicular line of a plurality of play face holes is non-overlapping in the air-out direction, every noodless are non-overlapping in the air-out direction promptly, in the region of horizontal biggest air-out angle beta, every noodless all can receive the wind-force effect, and in whereabouts in-process, noodless all can receive the wind-force effect in one section vertical distance, consequently, do not overlap and wide angle air-out between the noodless, weather the noodless, reach the effect of preventing adhesion of appearing.

As a preferable scheme of the utility model, the distance between the centers of the two adjacent outlet holes in the direction perpendicular to the air outlet direction is L1, and the distance between the centers of the two adjacent outlet holes in the horizontal direction is L2; the circle center distance between the adjacent surface holes is enough so that the surfaces are not overlapped, and each noodle can be blown dry by wind.

As a preferable solution of the present utility model, the air outlet end of the air outlet cover is in a grid shape, and a plurality of air outlets a arranged horizontally and a plurality of air outlets B arranged longitudinally are provided, so that the air outlet cover has a longitudinal maximum air outlet angle α and a transverse maximum air outlet angle β, where: alpha is more than or equal to 40 degrees and less than or equal to 45 degrees, beta is more than or equal to 5 degrees and less than or equal to 10 degrees; the wall surfaces of the air outlet A and the air outlet B are obliquely arranged to increase the air outlet angle; the wall surfaces of the air outlet A and the air outlet B gradually expand outwards.

As a preferable scheme of the utility model, the fan is assembled on the air outlet cover through a fan bracket, and the air outlet cover is assembled on the host;

the front end of the air outlet cover is in a grid shape to form an air outlet A and an air outlet B, the fan bracket is assembled at the tail end of the air outlet cover, an air inlet is formed in the fan bracket, and the fan is positioned in the air outlet cover and corresponds to the air inlet; through the structure, the fan assembly can be stably arranged inside the host, and the assembly structure is simple and compact.

As a preferable scheme of the utility model, the main machine is provided with a dough stirring container, a dough stirring rod and a charging barrel, and the dough stirring rod, the charging barrel, the dough extruding rod and the dough discharging barrel are coaxially arranged;

the surface hole is arranged on the peripheral wall of the surface cylinder and is downward in opening;

the stirring rod is arranged in the stirring container and driven to rotate by the driving device, and stirring arms with different specifications are radially extended from the stirring rod; the charging barrel is partially inserted into the stirring surface container for communication, and the surface discharging barrel is connected and communicated with the charging barrel;

the dough extruding rod is assembled in a space formed by the dough discharging barrel and the charging barrel, and is connected and linked with the dough stirring rod; through the structure, when the dough stirring device is used, water and flour can be put into the dough stirring container, dough is made through stirring of the dough stirring rod, the made dough is fed into the charging barrel, the noodles are extruded from the surface hole through extrusion of the dough extruding rod in the charging barrel, and the whole making process is carried out fully automatically except feeding.

As a preferable scheme of the utility model, the charging barrel is horizontally arranged and connected with the stirring surface container, the side wall of the charging barrel is provided with a charging port, and the charging port is upwards opened and positioned in the stirring surface container;

a baffle plate is arranged in the stirring face container corresponding to the upper part of the feeding hole;

the dough stirring rod is provided with a hook-shaped stirring arm, the rotating track of the hook-shaped stirring arm passes through the upper part of the baffle plate, and dough is scraped by the baffle plate; through the structure, dough can automatically fall into the charging barrel after being made, the dough is not required to be manually put into the charging barrel, and the degree of automation is higher.

As a preferable scheme of the utility model, one end of the dough extruding rod is coaxially inserted with the dough stirring rod, the other end of the dough extruding rod is connected with the inner wall of the dough discharging barrel, and the dough discharging barrel is arranged at the front end of the charging barrel and limited with the charging barrel through a rotary cover; the dough stirring rod is connected with a driving device inside the host.

As a preferable mode of the present utility model, the driving device and a power board are disposed in the host; the noodle outlet barrel horizontally protrudes out of the main machine, and a material basin can be placed below the noodle outlet barrel to contain noodles.

Compared with the prior art, the utility model has the following beneficial technical effects: the noodle machine has the main effects that the fan component forms longitudinal wide-angle blowing and has a longitudinal maximum air outlet angle alpha and a transverse maximum air outlet angle beta; the distribution of the noodle outlet holes is reasonable, the noodle outlet holes are not overlapped in the blowing direction, each noodle is enabled to be subjected to wind force, the blowing range is wide, the noodle is dried, the whole noodle covering noodle of the noodle machine is enabled to be air-dried and air-dried without shielding, and the effect of preventing adhesion of the noodle outlet is achieved.

Drawings

In order to more clearly illustrate the embodiments of the present utility model or the technical solutions in the prior art, the drawings that are required to be used in the embodiments or the description of the prior art will be briefly described below, and it is obvious that the drawings in the following description are only embodiments of the present utility model, and that other drawings can be obtained according to the provided drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic view of a noodle machine according to the present utility model;

FIG. 2 is a schematic cross-sectional view of the noodle machine of the present utility model;

FIG. 3 is an exploded view of the noodle machine of the present utility model;

FIG. 4 is a schematic diagram of the structure of the air outlet cover according to the present utility model;

FIG. 5 is a schematic diagram of an air outlet area of an air outlet cover according to the present utility model;

FIG. 6 is a schematic view of a longitudinal maximum air outlet angle of an air outlet cover according to the present utility model;

FIG. 7 is a schematic diagram of a lateral maximum air outlet angle of an air outlet cover according to the present utility model;

FIG. 8 is a schematic view of the noodle machine of the present utility model in operation;

fig. 9 is a schematic distribution diagram of the area of the outlet holes with the maximum air outlet angle β in the transverse direction.

Reference numerals illustrate:

host 100	Housing 110	Base 120	Drive device 130
				Motor 131	Gear case 132	Power panel 140
Noodle extruding rod 200	Rod body 210	Screw portion 220
				Out-of-plane barrel 300	Outlet hole 310
Blower assembly 400	Blower 410	Air outlet cover 420	Air outlet A421
				Air outlet B422	Fan bracket 430	Air inlet 431	Panel 432
Supporting leg 433
				Flour stirring container 500	Opening 501	Cover 510	Fixed cover 520
Flour-mixing rod 600	Stirring arm 610	Stirring arm A611	Scraper arm 612
				Cartridge 700	Feed inlet 710	Baffle 720	Baffle 730
Rotating cover 740

Detailed Description

The utility model will now be described in further detail with reference to the accompanying drawings. The drawings are simplified schematic representations which merely illustrate the basic structure of the utility model and therefore show only the structures which are relevant to the utility model.

A noodle machine with anti-blocking surface, as shown in fig. 1-3, comprising: host computer 100, crowded face pole 200 and play face section of thick bamboo 300, play face section of thick bamboo 300 is provided with a plurality of play face holes 310, crowded face pole 200 is pushed dough and is extruded out the noodless through play face hole 310, fan assembly 400 is installed to host computer 100, and fan assembly 400 acts on play face hole 310 below, and fan assembly 400 includes: blower 410 and air outlet cover 420;

the air outlet cover 420 has a longitudinal maximum air outlet angle α and a transverse maximum air outlet angle β; the perpendicular lines of the plurality of outlet holes 310 fall within the area of the lateral maximum outlet angle β, and the perpendicular lines of the plurality of outlet holes do not overlap in the outlet direction.

Specifically, the host 100 has a housing 110 and a base 120, the housing 110 is mounted on the base 120, and the whole machine can be stably placed on a plane through the base 120; the main machine 100 may have only a dough extruding function, that is, the dough is put into the dough cylinder 300, and extruded by the dough extruding rod 200 to vertically and downwardly send out noodles from the dough outlet 310; alternatively, the main machine 100 may have a dough making and extruding function, and is a fully automatic noodle machine, flour and water are put into the main machine 100 to automatically make dough, the dough enters the noodle cylinder 300, and the noodle is extruded by the noodle extruding rod 200 and sent out from the noodle hole 310 vertically downwards.

The noodle rod 200 includes: the rod body 210 and the spiral part 220 arranged on the rod body 210, the spiral part 220 is spirally distributed around the side wall of the rod body 210, the noodle cylinder 300 and the noodle extrusion rod 200 are horizontally arranged in the direction shown in fig. 2, the noodle cylinder 300 protrudes out of the host 100, a plurality of noodle outlet holes 310 are distributed on the noodle cylinder 300, the noodle outlet holes 310 are specifically positioned on the side surface of the noodle cylinder 300 and positioned at the bottom of the noodle cylinder 300 shown in the direction shown in fig. 2, dough is pushed to move and extruded by the noodle extrusion rod 200 in the rotating process of the noodle extrusion rod 200, and the noodles vertically drop through the noodle outlet holes 310 of the noodle cylinder 300.

The fan assembly 400 is installed in the host 100, the air outlet end of the air outlet cover 420 is located on one surface of the host 100, and when the fan 410 rotates, the air flow is blown from left to right as shown in fig. 2;

as shown in fig. 9, the projection of the plane holes 310 falls in the area of the transverse maximum air outlet angle β, the center of the plane holes 310 in fig. 9 is perpendicular to the paper surface, the dotted line part in fig. 9 is the air outlet direction of the air beam, and it can be seen that in the air outlet direction, the perpendicular lines of each plane hole 310 are not overlapped, therefore, when the plane strips are processed, each plane strip can be regarded as the cross section of each plane strip in fig. 9, and each plane strip can be acted by wind force in the area of the transverse maximum air outlet angle β; further, as shown in fig. 8, in the process of the vertical falling of the noodles, the noodles are blown for a period of time from the area entering the longitudinal maximum air outlet angle alpha to the area leaving the longitudinal maximum air outlet angle alpha, so that the noodles are dried and prevented from adhering.

In one embodiment, as shown in fig. 9, the plane holes 310 are projected in the area of the maximum air outlet angle β, the distance between the centers of two adjacent plane holes 310 in the direction perpendicular to the air outlet direction is L1, the distance between the centers of two adjacent plane holes 310 in the horizontal direction is L2, and each noodle can be subjected to wind force during the plane, so as to ensure the air drying effect of the noodle.

In one embodiment, as shown in fig. 4-5, the air outlet end of the air outlet cover 420 is in a grid shape, and a plurality of air outlets a421 arranged horizontally and a plurality of air outlets B422 arranged longitudinally are provided, so that the air outlet cover 420 has a longitudinal maximum air outlet angle α and a transverse maximum air outlet angle β, where: alpha is more than or equal to 40 degrees and less than or equal to 45 degrees, beta is more than or equal to 5 degrees and less than or equal to 10 degrees;

preferably, α=45°, β=10°, and the outlet angle is the widest.

In one embodiment, the wall surfaces of the air outlet a421 and the air outlet B422 are obliquely arranged to increase the air outlet angle, and the air outlet a421 and the air outlet B422 are distributed outwards along the center of the air outlet cover 420, as shown in fig. 5:

the left side and the right side are provided with air outlets A421, and the air outlets A421 are in a vertical strip shape and are distributed in a horizontal direction;

the upper side and the lower side are provided with air outlets B422, and the air outlets B422 are in a transverse strip shape and are distributed in a vertical direction;

as shown in fig. 4, the wall surfaces of the air outlet a421 and the air outlet B422 are inclined in an outward expansion manner, as shown in fig. 6, the air outlet B422 on the outermost side of the upper and lower positions of the air outlet cover 420 is parallel to the air outlet direction, so as to obtain a longitudinal maximum air outlet angle α; as shown in fig. 7, the air outlet a421 at the outermost side of the left and right direction of the air outlet cover 420 is parallel to the air outlet direction, so as to obtain the maximum air outlet angle β.

In one embodiment, the fan 410 is mounted to the air outlet cover 420 through a fan bracket 430, and the air outlet cover 420 is mounted to the host 100;

the front end of the air outlet cover 420 is in a grid shape to form the air outlet A and the air outlet B, the fan bracket 430 is assembled at the tail end of the air outlet cover 420, the fan bracket 430 is provided with an air inlet 431, and the fan 410 is positioned inside the air outlet cover 420 and corresponds to the air inlet 431.

As shown in fig. 2-3, the air outlet cover 420 is approximately box-shaped, an air outlet grid is formed at the front end of the air outlet cover 420, the air outlet a421 and the air outlet B422 are formed on the air outlet grid, a panel 432 of the fan bracket 430 is locked at the tail end of the air outlet cover 420 through screws, the air inlet 431 is formed on the panel 432, the fan bracket 430 is also provided with supporting legs 433 for supporting and limiting the fan 410, the fan 410 is installed in the air outlet cover 420 through the fan bracket 430, and the fan 410 is opposite to the air inlet 431; at the time of assembly, the entire fan assembly 400 may be preassembled and then installed in the host 100.

In one embodiment, the noodle machine of the present example is a fully automatic noodle machine, and thus further comprises a dough making unit.

The main machine 100 is provided with a dough stirring container 500, a dough stirring rod 600 and a charging barrel 700, and the dough stirring rod 600, the charging barrel 700, the dough extruding rod 200 and the dough discharging barrel 300 are coaxially arranged;

the stirring rod 600 is installed in the stirring container 500 and driven to rotate by the driving device 130, and stirring arms 610 with different specifications are radially extended from the stirring rod 600;

the charging barrel 700 is partially inserted into the stirring surface container 500 for communication, and the surface barrel 300 is connected and communicated with the charging barrel 700;

the noodle rod 200 is assembled in the space formed by the noodle cylinder 300 and the charging cylinder 700, and the noodle rod 200 is connected and linked with the noodle stirring rod 600.

Specifically, as shown in fig. 1 to 3, a position for mounting the dough stirring vessel 500 is formed on the housing 110, the dough stirring vessel 500 is box-type, and the dough stirring vessel 500 is limited on the housing 110 by a fixing cover 520. The top of the dough stirring container 500 is provided with a feeding port, and a cover 510 is arranged corresponding to the feeding port, when the dough stirring container 500 is used, the cover 510 is taken out, and after raw materials for making dough such as flour, water and the like are put into the dough stirring container 500, the cover 510 is reinstalled at the top of the dough stirring container 500.

The dough stirring rod 600 is installed in the dough stirring container 500, the dough stirring rod 600 is horizontally installed, and the dough stirring rod 600 passes through the dough stirring container 500 and the casing 110 of the host 100 to be connected with the driving device 130 installed in the host 100, and is driven to rotate by the driving device 130; the dough stirring rod 600 stirs raw materials such as water, flour and the like into dough when rotating;

after the dough is made, the dough is fed into the charging barrel 700, when the dough extruding rod 200 rotates, the dough is pushed and extruded, and finally the noodles are sent out from the flour outlet 310 of the flour barrel 300; the noodle falls down in-process and is weathered by wind power, and then the adhesion of the noodle is prevented.

In one embodiment, the barrel 700 is horizontally installed and connected with the stirring surface container 500, the side wall of the barrel 700 is provided with a feed inlet 710, and the feed inlet 710 is upward and positioned in the stirring surface container 500; as shown in fig. 2, the end of the cartridge 700 is inserted into the stirring surface container 500, the front surface of the stirring surface container 500 is provided with an opening 701 into which the cartridge 700 is inserted, the cartridge 700 is radially provided with a baffle 720, and the baffle 720 is tightly attached to the front surface of the stirring surface container 500 to cover the opening 701;

a baffle 730 is disposed in the stirring container 500 and above the feed inlet 710, and the baffle 730 may be disposed in the stirring container 500 or disposed on the barrel 700 and inserted into the stirring container 500 along with the insertion of the barrel 700 into the stirring container 500;

the stirring rod 600 is provided with a hook-shaped stirring arm, and the hook-shaped stirring arm includes: the stirring arm A611 extending along the radial direction of the stirring rod 600, and the scraping arm 612 extending along the axial direction of the stirring rod 600 at the tail end of the stirring arm A611, wherein the rotating track of the scraping arm 612 passes over the baffle plate 730, after dough is made, the scraping arm 612 drives the dough to move, the dough is scraped by the baffle plate 730 when passing the baffle plate 730, and the dough is automatically fed into the charging barrel 700 just to the charging hole 710 after being hung.

In one embodiment, one end of the extruding rod 200 is coaxially inserted into the stirring rod 600, the other end of the extruding rod 200 is connected with the inner wall of the extruding cylinder 300, and the extruding cylinder 300 is mounted at the front end of the cylinder 700 and is limited with the cylinder 700 through a rotary cover 740; the kneading bars 600 are connected to the driving device 130 inside the main machine 100.

The driving device 130 includes: a motor 131 and a gear box 132 to drive the rotation of the kneading bars 600. The motor 131 and the gear case 132 are commonly used driving structures, and detailed descriptions thereof are omitted.

The host 100 is internally provided with a power board 140, when in use, the power is turned on, and the noodle can be fully automatically manufactured through the control of the control panel.

When the noodle making machine is used, the noodles can be fully dried by the wind power of the fan assembly 400 in the falling process of the noodles, so that the noodles are prevented from being adhered, and the noodles are easy to shake out when being manually processed later.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present utility model. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the utility model. Thus, the present utility model is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (9)

1. A noodle machine for preventing sticking on a noodle surface, comprising: the dough extruding machine comprises a main machine, a dough extruding rod and a dough extruding barrel, wherein the dough extruding barrel is provided with a plurality of dough extruding holes, dough is pushed and extruded by the dough extruding rod to be extruded out of the noodles through the dough extruding holes, and the dough extruding machine is characterized in that:

the fan subassembly is installed to the host computer, and the fan subassembly acts on out face hole below, and the fan subassembly includes: a fan and an air outlet cover;

the air outlet cover is provided with a longitudinal maximum air outlet angle alpha and a transverse maximum air outlet angle beta; the perpendicular lines of the plurality of face holes fall in the area of the transverse maximum air outlet angle beta, and the perpendicular lines of the plurality of face holes are not overlapped in the air outlet direction.

2. A noodle machine for preventing sticking to a surface according to claim 1, wherein: the distance between the circle centers of two adjacent outlet holes in the direction perpendicular to the air outlet direction is L1, and the distance between the circle centers of two adjacent outlet holes in the horizontal direction is L2.

3. A noodle machine for preventing sticking to a surface according to claim 1, wherein: the air outlet end of the air outlet cover is in a grid shape, and a plurality of air outlets A which are transversely arranged and a plurality of air outlets B which are longitudinally arranged are arranged, so that the air outlet cover has a longitudinal maximum air outlet angle alpha and a transverse maximum air outlet angle beta, wherein: alpha is more than or equal to 40 degrees and less than or equal to 45 degrees, beta is more than or equal to 5 degrees and less than or equal to 10 degrees.

4. A noodle machine for preventing sticking to a surface according to claim 3, wherein: the wall surfaces of the air outlet A and the air outlet B are obliquely arranged to increase the air outlet angle.

5. A noodle machine for preventing sticking to a surface according to claim 3, wherein: the fan is assembled on the air outlet cover through a fan bracket, and the air outlet cover is assembled on the host;

the front end of the air outlet cover is in a grid shape to form the air outlet A and the air outlet B, the fan support is assembled at the tail end of the air outlet cover, the fan support is provided with an air inlet, and the fan is positioned inside the air outlet cover and corresponds to the air inlet.

6. A noodle machine for preventing sticking to a surface according to claim 1, wherein: the main machine is provided with a dough stirring container, a dough stirring rod and a charging barrel, and the dough stirring rod, the charging barrel, the dough extruding rod and the dough discharging barrel are coaxially arranged;

the surface hole is arranged on the peripheral wall of the surface cylinder and is downward in opening;

the stirring rod is arranged in the stirring container and driven to rotate by the driving device, and stirring arms with different specifications are radially extended from the stirring rod;

the charging barrel is partially inserted into the stirring surface container for communication, and the surface discharging barrel is connected and communicated with the charging barrel;

the noodle extruding rod is assembled in a space formed by the noodle cylinder and the charging barrel, and is connected and linked with the noodle stirring rod.

7. A noodle machine for preventing stickiness of a noodle as defined in claim 6, wherein: the feed cylinder is horizontally arranged and connected with the stirring surface container, the side wall of the feed cylinder is provided with a feed inlet, and the feed inlet is upwards opened and positioned in the stirring surface container;

a baffle plate is arranged in the stirring face container corresponding to the upper part of the feeding hole;

the dough stirring rod is provided with a hook-shaped stirring arm, the rotating track of the hook-shaped stirring arm passes through the upper part of the baffle plate, and dough is scraped through the baffle plate.

8. A noodle machine for preventing stickiness of a noodle as defined in claim 7, wherein: one end of the dough extruding rod is coaxially inserted into the dough stirring rod, the other end of the dough extruding rod is connected with the inner wall of the dough discharging barrel, and the dough discharging barrel is arranged at the front end of the charging barrel and limited with the charging barrel through a rotary cover; the dough stirring rod is connected with a driving device inside the host.

9. A noodle machine for preventing stickiness of a noodle as defined in claim 6, wherein: the driving device and a power panel are arranged in the host; the surface cylinder horizontally protrudes out of the host machine.