CN217136632U - Noodle machine that noise at work is low - Google Patents

Abstract

The utility model provides a noodle that noise at work is low, including the host computer that is equipped with the motor, locate the process chamber on the host computer, locate the processing subassembly and the die head subassembly of processing intracavity, the host computer includes the frame and locates the fuselage of frame one side, is equipped with on the frame with the bottom complex installation mesa of process chamber, the bottom of installation mesa or process chamber is equipped with the bellying, the bottom in installation mesa and process chamber realizes interference fit through the bellying. Because the interference fit is realized through the bellying in the bottom of installation table face and process chamber, effectively restrained the work in process chamber and rocked, improved the abnormal sound that rocks between process chamber and the installation table face, reduced the noise at work of noodle, user's system face promptly and experienced the sense better.

Description

Noodle that noise at work is low

Technical Field

The utility model relates to a food processing field especially relates to a noodle that noise at work is low.

Background

The main machine of the existing household noodle maker and the processing assembly arranged on the mounting table surface of the main machine comprise a processing cavity, wherein the processing cavity comprises a stirring cavity and a noodle extruding cavity communicated with the stirring cavity. Wherein, set up the puddler that is used for kneading dough in the stirring chamber, set up extrusion screw in the crowded face chamber and be used for promoting out the face.

However, in order to facilitate the installation of users, the existing household noodle maker is provided with a clearance fit between the bottom surface of the processing cavity and the installation table-board. Because the noodle machine can produce great moment of torsion at the during operation puddler and extrusion screw, especially at the in-process of appearing, the extrusion force in extrusion screw and the crowded face chamber is great, and crowded face chamber drives stirring chamber and constantly bumps between this clearance with the installation mesa, leads to the noise at work of noodle machine great, influence user experience.

In addition, in order to ensure the use safety of users, particularly when the die head assembly is neglected to be installed, the extrusion screw cannot be exposed and driven, and a safety ejection mechanism is additionally arranged on the noodle maker. These safety ejection mechanisms act, mostly directly or indirectly, on the extrusion screw via a spring, thereby controlling whether the extrusion screw is in a drive state. However, the safety ejection mechanism is also arranged, so that when a user installs the processing cavity and the extrusion screw on the main machine, the processing cavity and the extrusion screw are easily ejected by the safety mechanism for a certain distance, and the installation of the processing cavity fails. If at this moment, the user has not found the processing chamber skew correct installation position yet, packs the puddler into the stirring intracavity back again, because the relative cup eccentric mounting of puddler to will lead to bowl cover and puddler to counterpoint smoothly, seriously reduce user's installation experience and feel.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a noodle that noise at work is low solves the noise problem that the collision produced between processing chamber and the mounting table face in the noodle working process at least to reach the effect that noise at work is low, processing chamber convenient assembling, user experience feel.

In order to solve the technical problem, the utility model provides a noodle that noise at work is low, including the host computer that is equipped with the motor, locate the process chamber on the host computer, locate the processing subassembly and the die head subassembly of processing intracavity, the host computer includes the frame and locates the fuselage of frame one side, be equipped with on the frame with the bottom complex installation table surface in process chamber, its characterized in that, the bottom in installation table surface or process chamber is equipped with the bellying, the bottom in installation table surface and process chamber is passed through interference fit is realized to the bellying.

In this scheme, the bottom of mounting table face or process chamber is equipped with the bellying. Because the bottom of mounting surface and process chamber passes through interference fit is realized to the bellying, at the system face in-process, even if puddler and extrusion screw can produce great moment of torsion, the bottom in stirring chamber also can't bump with the mounting surface, has effectively inhibited the work in process chamber and has rocked, has improved the abnormal sound that rocks between process chamber and the mounting surface, has reduced the noise at work, user system face experience sense of noodle promptly and has felt betterly.

As is known, in order to ensure the use safety of users, a safety ejection mechanism is additionally arranged on a noodle maker, and the extrusion screw cannot be exposed and cannot be driven when the die head assembly 4 is neglected. To this kind of noodle that possess safe pop-up mechanism, the bottom that sets up mounting table face and process chamber passes through interference fit is realized to the bellying for the cooperation frictional force between mounting table face and the bellying increases, perhaps the cooperation frictional force between the bottom of process chamber and the bellying increases, resists the elasticity of safe pop-up mechanism to the process chamber, effectively avoids the process chamber to be popped out by safe pop-up mechanism when the installation and assembles inefficacy, convenience of customers assembly process chamber.

Preferably, the convex parts are symmetrically arranged along the central symmetry line of the mounting table top.

Through setting up the bellying edge the central symmetry line symmetry of installation mesa sets up, the bellying can the symmetry support process chamber to difficult beat, the stability of promotion process chamber installation when guaranteeing the installation of process chamber.

Preferably, the interference amount of the installation table top and the bottom of the processing cavity in interference fit through the bulge is d, and d is more than or equal to 0mm and less than or equal to 1 mm.

The interference amount of the interference fit realized by the lug boss is d, and d is not less than 0mm and not more than 1mm, so that the installation table board and the bottom of the processing cavity can be well and tightly fixed, and the problem that the installation is difficult due to overlarge interference amount can be avoided. Specifically, when d is less than 0mm, the bottom of the processing cavity is still in clearance fit with the boss, or the mounting table top is still in clearance fit with the boss, so that the effect of tight fixation between the mounting table top and the bottom of the processing cavity cannot be achieved. When d is larger than 1mm, the interference is too large, the processing cavity cannot be arranged on the mounting table surface, even if the processing cavity is arranged between the processing cavity and the mounting table surface, the processing cavity is also greatly abraded, and the service life of the noodle maker is seriously shortened.

Preferably, the center of the mounting table top is provided with a mounting boss with an output shaft hole, and the bulge part is arranged on the mounting table top at the front side of the mounting boss; or the convex part is positioned on the mounting table top at the two sides of the mounting boss; alternatively, the protrusion is located on an upper surface of the mounting boss.

It is known that a buckling structure is arranged on one side, close to a machine body, of a machining cavity, but a structure for limiting the machining cavity is not arranged on one side of the front end of a mounting table board, so that the phenomenon that the machining cavity is in clearance fit with the mounting table board is more likely to occur. Therefore, the bulge is arranged on the mounting table surface at the front side of the mounting boss, so that the fit clearance between the mounting table surface at the front side of the mounting boss and the bottom of the processing cavity can be compensated. Or the convex parts are positioned on the mounting table surfaces on two sides of the mounting boss, the symmetrical convex parts can avoid the single-side inclination of the processing cavity, and the matching stability of the mounting table surface on the front side of the mounting boss and the bottom of the processing cavity is improved. Or the lug boss is arranged on the upper surface of the mounting boss, so that the machining cavity can be mounted with the host machine through being tightly matched with the mounting boss, and the mounting table top can not be damaged flatly and is convenient for a user to clean.

Preferably, the convex part is a strip-shaped convex rib extending forwards from the front side surface of the mounting boss to the edge of the mounting table top; or the bulge part is an arc convex rib arranged along the edge of the mounting table top; or the convex part is a strip-shaped convex rib positioned on two sides of the mounting boss.

Because the process chamber is installed when going on to the host computer, mostly goes on along horizontal rectilinear direction, is for following through setting up the bellying in this scheme the leading flank of installation boss is preceding along stretching to the protruding muscle of strip at the edge of installation table surface, and the protruding muscle of strip is unanimous with the installation direction of process chamber, to installing better guidance quality in process chamber, convenience of customers installation. Or, in order to realize the consistency of the convex rib and the edge of the mounting table surface, the arc-shaped convex rib arranged along the edge of the mounting table surface is arranged through the bulge part, so that the contact area between the arc-shaped convex rib and the bottom of the processing cavity is increased, and the mounting is more stable. Or, in order to increase the moment supported by the processing cavity between the protruding parts, the protruding parts are strip-shaped convex ribs positioned on two sides of the mounting boss, so that the mounting stability of the processing cavity is effectively improved.

Preferably, the strip-shaped convex rib and the mounting table surface are integrally formed, and the arc-shaped convex rib and the mounting table surface are integrally formed.

Through setting up the protruding muscle of strip with installation mesa integrated into one piece, the protruding muscle of arc with installation mesa integrated into one piece to promote protruding muscle structure and installation mesa's uniformity, save secondary operation technology, convenient processing. And in addition, the rib structure is prevented from slipping off from the mounting table top in the process of repeatedly disassembling and assembling the processing cavity.

Preferably, one side of the strip-shaped convex rib, which is close to the edge of the mounting table top, is provided with a guide oblique angle, and the guide oblique angle inclines downwards from the inner side of the mounting table top towards the edge of the mounting table top.

In order to improve the installation guidance of the strip-shaped convex ribs on the processing cavity, a guide oblique angle is arranged on one side, close to the edge of the mounting table top, of the strip-shaped convex ribs, and the guide oblique angle inclines downwards from the inner side of the mounting table top towards the edge of the mounting table top to facilitate the correct installation guide rail to be drawn into the processing cavity.

Preferably, the transverse width of the strip-shaped convex rib is L1, and is more than or equal to 0.5mm and less than or equal to L1 and less than or equal to 50 mm.

The transverse width of the strip-shaped convex rib is L1 between 0.5mm and 50mm, so that the stability of the machining cavity mounted on the host is improved, and the installation is convenient. Because the processing chamber needs to be repeatedly disassembled and assembled for use, when L1 is less than 0.5mm, the narrow strip-shaped convex ribs are easily worn, and the installation stability is reduced. When L1 > 50mm, the area of contact of process chamber bottom and strip protruding muscle is big, frictional force is big, and the process chamber is hard and difficult to install when installing on the installation mesa, and the installation experience feels poor.

Preferably, the bulge is flannelette, rubber, sponge or an inclined plane integrally formed with the mounting table top.

Soft materials such as flannelette, rubber or sponge are used as the convex parts, so that abrasion between the bottom of the processing cavity and the convex parts and abrasion between the mounting table top and the convex parts can be effectively avoided, and the safe service life of the noodle maker can be prolonged. When the bulge part adopts the inclined plane which is integrally formed with the mounting table top, the consistency is high, and secondary processing is not needed.

Preferably, the number of the convex parts is at least 2, the spacing distance between the adjacent convex parts is L2, and L2 is more than or equal to 5mm and less than or equal to 60 mm.

In order to strengthen the stability of the installation cooperation of the bottom of the processing cavity and the installation table surface, at least 2 convex parts are arranged. Meanwhile, the spacing distance between the adjacent protruding parts is set to be L2, L2 is larger than or equal to 5mm and smaller than or equal to 60mm, the existence of the spacing distance can avoid that the friction force between the bottom of the processing cavity and the mounting table top is too large, the mounting is laborious, the protruding parts are easily worn due to the fact that the protruding parts are too dense, and the supporting distance can be increased to ensure the mounting stability. When L2 is greater than 60mm, the distance between the protrusions easily exceeds the profile dimension of the front end of the processing chamber, so that the protrusions are exposed outside the processing chamber, and it is impossible to realize that all the protrusions are located between the bottom of the processing chamber and the mounting table. When L2 is less than 5mm, the supporting moment of the convex part to the processing cavity is too small, and the supporting stability is poor. Moreover, the protrusions are too dense, which easily causes too large friction between the bottom of the processing cavity and the mounting table, installation is laborious, and the protrusions are easily worn.

Drawings

Fig. 1 is the whole machine explosion diagram of the noodle maker of the present invention.

Fig. 2 is the whole structure cross-sectional view of the noodle maker of the present invention.

Fig. 3 is a partially enlarged view of the area a shown in fig. 2.

Fig. 4 is a schematic side view of the noodle maker of the present invention.

Fig. 5 is a partially enlarged view of the region B shown in fig. 4.

Fig. 6 is a top view of the main machine of the noodle maker of the present invention.

Fig. 7 is a schematic structural view of the processing chamber of the present invention.

Figure 8 is the utility model discloses a host computer top view on the installation boss is located to the bellying.

Figure 9 is the utility model discloses a host computer top view of the both sides of installation boss is located to the bellying.

Fig. 10 is a plan view of the main unit of the present invention when the protruding portion is an arc-shaped rib.

The numbers in the figures correspond to the names as follows:

1. a host; 11. a machine base; 111. mounting a table top; 112. a motor; 1111. mounting a boss; 1112. an output shaft hole; 12. a body; 2. a boss portion; 3. a processing cavity; 31. a stirring chamber; 311. a stirring rod; 312. a cup cover; 32. an extrusion chamber; 33. a first mating surface; 34. a second mating surface; 4. a die assembly; 41. a die cover; 42. a die head; 43. and forming the area.

Detailed Description

In order to more clearly explain the overall concept of the present application, the following detailed description is given by way of example in conjunction with the accompanying drawings. In the description of the present application, it is to be understood that the terms "central," "upper," "lower," "front," "rear," "horizontal," "inner," "outer," "axial," "radial," and the like are used in the orientations and positional relationships indicated in the drawings for the purpose of convenience and simplicity of description, and are not intended to indicate or imply that the referenced devices or elements must have a particular orientation, be constructed and operated in a particular orientation, and are therefore not to be considered limiting of the present application.

In this application, unless expressly stated or limited otherwise, the terms "mounted," "connected," "secured," and the like are to be construed broadly and can include, for example, fixed connections, removable connections, or integral parts; the connection can be mechanical connection, electrical connection or communication; either directly or indirectly through intervening media, either internally or in any other relationship. The specific meaning of the above terms in the present application can be understood by those of ordinary skill in the art as appropriate.

As shown in fig. 1-10, the utility model provides a noodle maker with low working noise, which comprises a main machine 1, a processing cavity 3 arranged on the main machine 1, a processing assembly arranged in the processing cavity 3 and a die head assembly 4. The main machine 1 comprises a machine base 11 and a machine body 12 arranged on one side of the machine base 11, and the machine base 1 is provided with an installation table board 111 matched with the bottom of the processing cavity 3. The processing cavity 3 comprises a stirring cavity 31 and an extrusion cavity 32 communicated with the stirring cavity, a cup cover 312 is detachably covered above the stirring cavity 31, and an extrusion screw (not shown) is arranged in the extrusion cavity 32. The die head assembly 4 is detachably arranged at the front end of the extrusion cavity 32, and the die head assembly 4 comprises a die head 42, a forming area 43 arranged on the die head 42 and a die head cover 41 for connecting and fixing the die head 42 and the extrusion cylinder 32. Generally, the mixing chamber 31 is used for mixing food materials such as flour with water or fruit and vegetable juice to complete the dough kneading process, and the extrusion chamber 32 is used for extruding the food materials subjected to the dough kneading process in the mixing chamber 31 and discharging the dough through the dough discharging area 43 of the die head.

When a user installs the processing cavity, the processing cavity is usually close to one side of the machine body along the installation table surface 111 and is limited and fixed with the opening position on one side of the machine body. In order to facilitate installation, the bottom of the installed processing cavity 3 is in clearance fit with the installation table 111. Like this, the noodle can produce great moment of torsion at during operation puddler 311 and extrusion screw, leads to constantly bumping between processing chamber and the mounting table face, leads to the noise at work of noodle great, influence user experience.

In order to solve the problem of collision between the bottom of the processing cavity of the noodle maker and the mounting table-board in the noodle making process, in the scheme, a protruding part is arranged at the bottom of the mounting table-board or the processing cavity, and the bottom of the mounting table-board 111 and the bottom of the processing cavity 3 are in interference fit through the protruding part 2. Because the bottom of installation table surface 111 and process chamber 3 is passed through interference fit is realized to bellying 2, at the system face in-process, even if puddler 311 and extrusion screw can produce great moment of torsion, the bottom in stirring chamber 3 also can't bump with installation table surface 111, has effectively inhibited the work of process chamber 3 and has rocked, has improved the abnormal sound that rocks between process chamber 3 and the installation table surface 111, has reduced the noise at work of noodle, user system face promptly and has experienced the sense better.

As is known, in order to ensure the use safety of users, a safety ejection mechanism is additionally arranged on a noodle maker, and the extrusion screw cannot be exposed and cannot be driven when the die head assembly 4 is neglected. To this kind of noodle that possess safe pop-up mechanism, the bottom that sets up mounting surface 111 and process chamber 3 passes through boss 2 realizes interference fit for the cooperation frictional force between mounting surface 111 and the boss 2 increases, perhaps the cooperation frictional force between the bottom of process chamber 3 and the boss 2 increases, resists the elasticity of safe pop-up mechanism to the process chamber, effectively avoids process chamber 3 to be popped out by safe pop-up mechanism and assemble inefficacy, convenience of customers assembly process chamber when the installation.

It will be appreciated that the noodle maker described herein is not limited to the type of vertical noodle maker shown in the drawings and examples. For example, the noodle maker may be a horizontal noodle maker in which the extrusion screw is coaxially provided with the stirring rod 311, or a horizontal noodle maker in which the extrusion screw is vertically provided in parallel with the stirring rod 311. For another example, it may also be a noodle maker, the forming area of the die head 41 may be detachably connected to the sidewall of the extruding cylinder, and the die head 41 is changed into a baffle structure for axially limiting the extruding screw.

Further, referring to fig. 3, the interference amount of the installation table 111 and the bottom of the processing cavity 3 in interference fit through the boss 2 is d, and d is greater than or equal to 0mm and less than or equal to 1 mm. Through setting up d between 0mm to 1mm for good inseparable fixed can be realized to the bottom of mounting table surface 111 and processing chamber 3, can avoid again that the too big problem that leads to being difficult to the installation of interference volume. Specifically, when d is less than 0mm, the bottom of the processing cavity 3 is still in clearance fit with the boss 2, or the mounting table 111 is still in clearance fit with the boss 2, so that the effect of tightly fixing the mounting table 111 and the bottom of the processing cavity 3 cannot be achieved. When d is larger than 1mm, the interference amount is too large, the processing cavity 3 cannot be arranged on the mounting table surface 111, and even if the processing cavity is arranged between the processing cavity and the mounting table surface, the processing cavity and the mounting table surface are abraded greatly, so that the service life of the noodle maker is shortened seriously.

It is understood that, when the boss 2 is provided at the bottom of the stirring chamber 31 as shown in fig. 3, the interference amount d refers to the interference amount between the bottom of the stirring chamber 31 and the mounting table 111. When the boss 2 is located at the bottom of the pressing chamber 32, the interference amount d refers to the interference amount between the bottom of the pressing chamber 32 and the mounting table 111. When the boss 2 is provided at the bottom of the stirring chamber 31 and the pressing chamber 32, the interference amount d means an average value of the interference amount between the bottom of the pressing chamber 32 and the mounting table 111 and the interference amount between the bottom of the stirring chamber 31 and the mounting table 111.

In some embodiments of the present application, referring to fig. 6, the mounting platform 111 is provided with a mounting boss 1111, which is provided with an output shaft hole 1112 connected to the stirring rod 311. The top view of the main frame 1 is provided with a central symmetry line bb ' passing through the output shaft hole 1112, and the central symmetry line bb ' is also a central symmetry line of the mounting table, specifically referring to a dotted line bb ' in fig. 6. Preferably, the protruding portions 2 are symmetrically arranged along the central symmetry line bb' of the mounting table 111, so that the protruding portions 2 can symmetrically support the bottom of the processing cavity 3, and therefore the processing cavity 3 is not prone to deflection during mounting and the mounting stability of the processing cavity 3 is improved.

It will be appreciated that when the mounting boss 1111 is not provided on the mounting deck 111, a central symmetry line bb' of the mounting deck 111 may also be provided. Alternatively, when the mounting table 111 is provided with a groove for mounting the extrusion chamber 32, a central symmetry line bb' of the mounting table 111 may be provided.

It is known that the side of the processing chamber 3 close to the machine body 12 is provided with a buckling structure, but the front end side of the mounting table 111 has no structure for limiting the processing chamber 3, and the phenomenon that the processing chamber 3 is in clearance fit with the mounting table 111 is more likely to occur here. Therefore, in some embodiments of the present application, referring to fig. 1 and 6, the center of the mounting table 111 is provided with a mounting boss 1111 having an output shaft hole 1112, and the boss 2 is provided on the mounting table 111 at the front side of the mounting boss 1111. That is, the boss 2 is provided on the mounting surface 111 in front of the mounting boss 1111, so that the fitting clearance between the mounting surface 111 in front of the mounting boss 1111 and the bottom of the processing chamber 3 can be compensated. Preferably, it means to make up for the fitting gap between the mounting surface 111 at the front side of the mounting boss 1111 and the first fitting plane 33 of the stirring chamber 31, see fig. 7.

Further, referring to fig. 6, the protrusion 2 is a strip-shaped rib extending from the front side of the mounting boss 1111 to the edge of the mounting platform 111. Because the installation of process chamber 3 to host computer 1 on, go on along horizontal rectilinear direction mostly, consequently through setting up bellying 2 for following in this scheme the leading flank of installation boss 1111 is preceding along stretching to the protruding muscle of strip at the edge of installation mesa 111, and the protruding muscle of strip is unanimous with the installation direction of process chamber 3, to the better guidance quality of installing of process chamber 3, convenience of customers installation.

Furthermore, referring to fig. 2 and 3, a guiding bevel a is disposed on a side of the strip-shaped rib close to the edge of the mounting table 111, and the guiding bevel a inclines downwards from the inner side of the mounting table 111 toward the edge of the mounting table 111, which is helpful to improve the installation guidance of the strip-shaped rib on the processing chamber 3. The oblique guide angles a are inclined downwards from the inner side of the mounting table towards the edge of the mounting table 111 to facilitate the correct scribing of the processing chamber 3 into the mounting rail. Specifically, the range of the guide bevel angle a is preferably between 0.1 ° and 45 °. When the angle is smaller, the guide angle is not available, and the guide performance is lost; when the angle is too large, the angle is too steep, and a larger force is required to guide the working chamber to dig in.

Referring to fig. 4 and 5, the transverse width of the strip-shaped convex rib is L1, and L1 is more than or equal to 0.5mm and less than or equal to 50 mm. Transverse width through setting up the protruding muscle of strip is L1 between 0.5mm to 50mm to promote the stationarity that processing chamber 3 installed to host computer 1, easy to assemble. Because the processing cavity 3 needs to be repeatedly disassembled and assembled for use, when the L1 is less than 0.5mm, the narrow strip-shaped convex ribs are easily worn, and the installation stability is reduced. When L1 > 50mm, the area of contact of processing chamber 3 bottom and strip protruding muscle is big, frictional force is big, and the processing chamber 3 is hard and difficult to install when installing on mounting table face 111, and the installation experience feels poor.

As can be understood, referring to fig. 10, in order to achieve the consistency between the rib and the edge of the mounting table 111, the convex portion 2 is an arc-shaped rib disposed along the edge of the mounting table 111, so that the contact area between the arc-shaped rib and the bottom of the processing chamber 2 is increased, and the mounting is more stable.

More preferably, the strip-shaped rib is integrally formed with the mounting table 111, and the arc-shaped rib is integrally formed with the mounting table. Through setting up the protruding muscle of strip with mounting table surface 111 integrated into one piece, the protruding muscle of arc with mounting table surface 111 integrated into one piece to promote protruding muscle structure and mounting table surface 111's uniformity, save secondary operation technology, convenient processing. And, avoid at the in-process of processing chamber repeated dismouting, protruding muscle structure slides out from the installation mesa.

In some embodiments of the present application, referring to fig. 8, the protrusion 2 is disposed on the upper surface of the mounting boss 1111, so that the processing chamber 3 can be mounted on the main body 1 by being tightly fitted with the mounting boss 111, and the mounting boss 111 is not damaged, and is easy for a user to clean. Specifically, the boss 2 is fitted to the second fitting flat surface 34 of the processing chamber 31.

Further, the protrusion 2 is a lint, rubber, or sponge on the upper surface of the mounting boss 1111. Soft materials such as flannelette, rubber or sponge are used as the convex part 2, so that abrasion between the bottom of the processing cavity 3 and the convex part 2 and abrasion between the mounting table surface 111 and the convex part 2 can be effectively avoided, and the safe service life of the noodle maker can be prolonged.

In some embodiments of the present application, referring to fig. 9, the protruding portions 2 are located on the mounting platforms 111 on both sides of the mounting boss 1111, and the symmetrical protruding portions 2 can prevent the processing chamber from inclining on one side, so as to improve the stability of the mounting platform 111 on the front side of the mounting boss 1111 matching with the bottom of the processing chamber 3.

Further, the protruding portion 2 is a flannel, rubber, sponge, or an inclined plane integrally formed with the mounting table 111 at two sides of the mounting boss 1111. The efficacy of the lint or rubber or sponge has been previously described and will not be further described herein. When the convex part 2 adopts an inclined plane which is integrally formed with the mounting table surface 111, the consistency is high, and secondary processing is not needed.

It can be understood that, in order to increase the moment that supports the processing cavity 3 between the convex parts 2, the convex parts 2 are arranged into strip-shaped convex ribs positioned at two sides of the mounting boss 1111, and the mounting stability of the processing cavity 3 is effectively improved.

Referring to fig. 5, in some embodiments of the present application, at least 2 projections are provided in order to enhance the stability of the mounting fit of the bottom of the process chamber 3 to the mounting table 111. Meanwhile, the spacing distance between the adjacent bosses 2 is set to be L2, the spacing distance is not less than 5mm and not more than L2 and not more than 60mm, the existence of the spacing distance L2 can avoid that the friction between the bottom of the processing cavity 3 and the mounting table surface 111 is too large and the mounting is laborious due to the excessively dense bosses 2, the bosses 2 are easily worn, and the supporting distance can be increased to ensure the mounting stability.

When L2 is greater than 60mm, the distance between adjacent protrusions 2 easily exceeds the dimension of the front end of the processing chamber 3 (i.e. the dimension of the front end of the stirring chamber 31), so that the protrusions 2 are exposed out of the processing chamber 3, and it is impossible to position all the protrusions 2 between the bottom of the processing chamber 3 and the mounting platform 111. When L2 is less than 5mm, the supporting moment of the convex part 2 to the processing cavity 3 is too small, and the supporting stability is poor. Moreover, the protrusions 2 are too dense, which tends to result in excessive friction between the bottom of the processing chamber 3 and the mounting surface 111, which makes the mounting laborious and the protrusions 2 are easily worn.

It can be understood that when the protrusions 2 are located on the mounting lands 111 at both sides of the mounting boss 1111, the spacing distance L2 between adjacent protrusions 2 refers to the spacing distance between the protrusions located at the same side. Alternatively, L2 may be protrusions located on different sides, with the separation distance between the closest two protrusions.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the scope of the present invention, i.e. all equivalent changes and modifications made according to the present invention are covered by the scope of the claims of the present invention, which is not illustrated herein.

Claims (10)

1. The utility model provides a noodle that noise at work is low, includes the host computer that is equipped with the motor, locate the process chamber on the host computer, locate processing subassembly and the die head subassembly in the process chamber, the host computer includes the frame and locates the fuselage of frame one side, be equipped with on the frame with the bottom complex installation table face in process chamber, a serial communication port, the bottom in installation table face or process chamber is equipped with the bellying, the bottom of installation table face and process chamber is passed through interference fit is realized to the bellying.

2. A low operating noise noodle maker as claimed in claim 1 wherein the projections are symmetrically disposed along a central symmetry line of the mounting table.

3. The noodle maker with low working noise according to claim 1, wherein the interference amount of the interference fit between the mounting table surface and the bottom of the processing cavity through the bulge is d, and d is more than or equal to 0mm and less than or equal to 1 mm.

4. A low noise noodle maker as claimed in any one of claims 1 to 3 wherein a mounting boss with an output shaft hole is provided at the center of the mounting table, and the projection is provided on the mounting table at the front side of the mounting boss; or the convex part is positioned on the mounting table top at the two sides of the mounting boss; alternatively, the protrusion is located on an upper surface of the mounting boss.

5. A low operating noise noodle maker as claimed in claim 4 wherein the raised portion is a strip rib extending forwardly from the front face of the mounting boss to the edge of the mounting table; or the bulge part is an arc convex rib arranged along the edge of the mounting table top; or the convex part is a strip-shaped convex rib positioned on two sides of the mounting boss.

6. A low operating noise noodle maker according to claim 5 wherein the bar rib is integrally formed with the mounting surface and the arcuate rib is integrally formed with the mounting surface.

7. A low operating noise noodle maker according to claim 5 wherein the side of the rib adjacent the edge of the mounting surface is provided with a guide bevel which slopes downwardly from the inside of the mounting surface towards the edge of the mounting surface.

8. A low noise noodle maker according to claim 5 wherein the transverse width of the rib is L1, 0.5mm L1 mm 50 mm.

9. A low operating noise noodle maker as claimed in claim 1 wherein the raised portion is a fleece or rubber or sponge or an inclined plane integral with the mounting table.

10. A low noise noodle maker according to claim 1 or 2, wherein the number of the projections is at least 2, and the distance between adjacent projections is L2, L2 mm 60mm is 5 mm.

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