CN112602739B - Noodle extrusion device capable of adjusting water content of noodles - Google Patents

Abstract

The invention relates to the relevant field of extruders, and discloses a noodle extruding device capable of adjusting the water content of noodles, which comprises a main box body, wherein a kneading cavity with an upward opening is arranged in the main box body, the lower side of the kneading cavity is communicated with a noodle extruding cavity with a rightward opening, the left side of the kneading cavity is communicated with a water discharging cavity, the left side of the water discharging cavity is communicated with a water pump fixedly connected with the main box body, the left end surface of the main box body is fixedly connected with an external water pipe, the left side of the water pump is communicated with a water inlet cavity extending to the external water pipe leftwards, water is slowly added while flour is stirred, so that the flour and the water are mixed more thoroughly, the dough can be kneaded and formed more quickly, the noodle production efficiency is improved, meanwhile, the water can be automatically stopped being supplied to the kneading cavity during dough forming, the dough cannot be formed due to excessive water, the noodle forming quality is ensured, and the noodles can be formed according to the taste required by different noodles, the water content of the dough during forming is adjusted, and the applicability of the device is greatly improved.

Description

Noodle extrusion device capable of adjusting water content of noodles

Technical Field

The invention relates to the field related to an extruder, in particular to a noodle extruding device capable of adjusting the water content of noodles.

Background

The noodle maker is a device for mixing and kneading flour and water into dough and extruding the dough into noodles through a die, the existing noodle maker is generally characterized in that the flour and the water are all poured into the device for kneading, the ratio of the flour to the water is mainly controlled by the experience of people, so that the people without kneading experience can not use the device well, and meanwhile, the flour and the water are all mixed for kneading, so that the mixing degree of the flour and the water is uneven, the kneading time is increased, and the noodle production efficiency is reduced.

Disclosure of Invention

The invention aims to provide a noodle extruding device capable of adjusting the water content of noodles, which can overcome the defects of the prior art and improve the practicability of equipment.

The technical scheme adopted by the invention for solving the technical problems is as follows: the invention relates to a noodle extruding device capable of adjusting the water content of noodles, which comprises a main box body, wherein a noodle kneading cavity with an upward opening is arranged in the main box body, the lower side of the noodle kneading cavity is communicated with a noodle extruding cavity with a rightward opening, the left side of the noodle kneading cavity is communicated with a water discharging cavity, the left side of the water discharging cavity is communicated with a water pump fixedly connected with the main box body, the left end surface of the main box body is fixedly connected with an external water pipe, the left side of the water pump is communicated with a water inlet cavity extending leftwards into the external water pipe, the left side of the noodle kneading cavity is provided with a power transmission belt cavity positioned at the lower side of the water pump, the right side of the noodle kneading cavity is provided with a driven gear cavity, the right end wall of the driven gear cavity is rotationally and cooperatively connected with a driving transmission shaft extending leftwards to penetrate through the noodle kneading cavity to the power transmission belt cavity, and the driving transmission shaft is fixedly connected with a stirring screw rod positioned in the noodle kneading cavity, a face tooth transmission cavity is arranged on the right side of the power transmission belt cavity, a driven transmission shaft which extends rightwards into the face tooth transmission cavity and leftwards into the power transmission belt cavity is connected in a rotating fit manner on the right end wall of the power transmission belt cavity, a power transmission belt is connected between the left end of the driven transmission shaft and the left end of the driving transmission shaft in a power matching way, the driven transmission shaft is connected with an end face tooth shaft sleeve positioned in the end face tooth transmission cavity in a spline fit manner, the tail end of the right side of the end surface tooth shaft sleeve is connected with a magnetic connecting rod in a rotating fit mode, the tail end of the left side of the end surface tooth shaft sleeve is fixedly connected with a sliding end surface tooth, the noodle extruding device is characterized in that a synchronous transmission belt cavity is arranged on the right side of the end face tooth transmission cavity, and a helical blade shaft which extends leftwards to the inside of the end face tooth transmission cavity extends rightwards to penetrate through the inside of the end face tooth transmission cavity is connected with the end face tooth transmission cavity in a rotating fit mode.

On the basis of the technical scheme, the terminal fixedly connected with in the left side of the driven transmission shaft can be engaged with the driving end face teeth of the sliding end face teeth, the end face teeth transmission cavity left end wall is connected with the synchronous transmission shaft which extends through the end face teeth transmission cavity to the synchronous transmission belt cavity rightwards in a rotating fit manner, the magnetic connecting rod is connected with the sliding gear shaft sleeve in a rotating fit manner and is connected with the synchronous transmission shaft in a spline fit manner, the terminal fixedly connected with in the left side of the sliding gear shaft sleeve can be engaged with the sliding gear of the driving end face teeth, the helical blade shaft and the synchronous transmission shaft are connected with the synchronous transmission belt positioned in the synchronous transmission belt cavity in a power fit manner, the helical blade shaft is fixedly connected with helical blades positioned in the noodle extrusion cavity, and the noodle extrusion cavity inner wall is fixedly connected with a noodle forming die, be equipped with a plurality of noodless that link up about in the noodless forming die and extrude the hole, fixedly connected with connecting rod electro-magnet in the terminal surface tooth transmission chamber right-hand member wall, magnetism connecting rod right-hand member face with fixedly connected with terminal surface tooth spring between the terminal surface tooth transmission chamber right-hand member wall, driven gear chamber upside intercommunication is equipped with straight gear drive chamber.

On the basis of the technical scheme, the right side of the straight gear transmission cavity is provided with a motor fixedly connected with the main box body, the left end face of the motor is fixedly connected with a motor shaft which extends to the inside of the straight gear transmission cavity leftwards, the left end of the motor shaft is fixedly connected with a driving straight gear, the left side of the driven gear cavity is communicated with an annular magnetic through cavity which is arranged by taking the driving transmission shaft as a central ring, the right side of the annular magnetic through cavity is communicated with a magnetic sliding plate cavity, the right side of the magnetic sliding plate cavity is communicated with a pressing block sliding cavity, the right end of the driving transmission shaft is fixedly connected with a rotating block, the rotating block is connected with a driven gear in a rotating matching manner, an annular rack cavity which is arranged by taking the driving transmission shaft as a central ring and has an inward opening is arranged in the driven gear, and the upper side of the annular rack cavity is communicated with a transmission pinion cavity in an initial state, the transmission pinion chamber right side is equipped with the slip nut chamber, slip nut chamber right side intercommunication be equipped with the chamber is led to annular magnetism leads to the magnetism that the chamber corresponds, the outer disc fixedly connected with of turning block with the initiative transmission shaft sets up and is located as central annular the annular rack of annular rack intracavity.

On the basis of the technical scheme, the right end wall of the transmission pinion cavity is connected with a transmission pinion shaft which extends rightwards into the sliding nut cavity and extends leftwards into the transmission pinion cavity in a matched manner, the left end of the transmission pinion shaft is fixedly connected with a transmission pinion which is meshed with the annular rack, the transmission pinion shaft is connected with a sliding nut which is connected with the sliding nut cavity in a matched manner in a threaded manner, the magnetic sliding plate cavity is connected with a magnetic sliding plate which corresponds to the sliding nut in a matched manner in a sliding manner, the upper end wall of the magnetic sliding plate cavity is fixedly connected with a contact switch, the right end wall of the pressing block sliding cavity is connected with a knob which extends rightwards to the outside and extends inwards into the pressing block sliding cavity in a matched manner in a rotating manner, the right end of the knob is fixedly connected with a lead screw, and the knob is connected with a spring pressing block which is connected with the pressing block sliding cavity in a matched manner in a threaded manner, and a sliding plate spring is fixedly connected between the left end surface of the spring pressing block and the right end surface of the magnetic sliding plate.

On the basis of the technical scheme, slip nut chamber downside is equipped with opening decurrent damping pearl chamber, be equipped with the opening in the turning block and upwards just with the damping pearl chamber that corresponds damping pearl sliding chamber, damping pearl sliding chamber sliding fit is connected with the damping pearl, damping pearl downside with fixedly connected with damping pearl spring between the lower end wall of damping pearl sliding chamber, be equipped with the inside arc chamber of opening in the driven gear, fixedly connected with on the outer disc of turning block with the slider that arc chamber sliding fit connects, terminal surface before the slider with fixedly connected with arc spring between the arc chamber upper end wall.

The invention has the beneficial effects that: slowly add water when flour stirs for flour and water mix more thoroughly, can be faster rub the shaping with the dough, improved noodless production efficiency, can automatic stop supply water to kneading the face intracavity during the dough shaping simultaneously, make the dough can not be because of the too much unable shaping of moisture, guaranteed noodless shaping quality, can be according to the required taste of different noodless moreover, water content when adjusting the dough shaping has improved the suitability of device greatly.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the invention, and it is obvious for those skilled in the art that other drawings can be obtained based on these drawings without creative efforts.

The invention is further illustrated with reference to the following figures and examples.

Fig. 1 is a schematic view showing the overall construction of a noodle extruding apparatus capable of adjusting the water content of noodles according to the present invention.

Fig. 2 is an enlarged schematic view of a in fig. 1.

Fig. 3 is an enlarged schematic view of B in fig. 1.

Fig. 4 is a schematic diagram of the structure C-C in fig. 2.

Detailed Description

The invention will now be described in detail with reference to fig. 1-4, wherein for ease of description the orientations described hereinafter are now defined as follows: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

The noodle extruding device capable of adjusting the water content of noodles, which is described in conjunction with the attached drawings 1-4, comprises a main box body 10, a noodle kneading cavity 11 with an upward opening is arranged in the main box body 10, a noodle extruding cavity 23 with a rightward opening is communicated with the lower side of the noodle kneading cavity 11, a water discharging cavity 35 is communicated with the left side of the noodle kneading cavity 11, a water pump 34 fixedly connected with the main box body 10 is communicated with the left side of the water discharging cavity 35, an external water pipe 33 is fixedly connected with the left end surface of the main box body 10, a water inlet cavity 32 extending leftwards into the external water pipe 33 is communicated with the left side of the water pump 34, a power transmission belt cavity 30 positioned at the lower side of the water pump 34 is arranged at the left side of the noodle kneading cavity 11, a driven gear cavity 45 is arranged at the right side of the noodle kneading cavity 11, a driving transmission shaft 31 extending leftwards into the power transmission belt cavity 30 is connected with the right end wall of the driven gear cavity 45 in a rotating and matching manner, the stirring screw rod 12 positioned in the dough kneading cavity 11 is fixedly connected to the driving transmission shaft 31, the right side of the power transmission belt cavity 30 is provided with an end face tooth transmission cavity 57, the right end wall of the power transmission belt cavity 30 is in rotating fit connection with a driven transmission shaft 29 which extends to the right side of the end face tooth transmission cavity 57 to the left side and extends to the inside of the power transmission belt cavity 30, the left end of the driven transmission shaft 29 and the left end of the driving transmission shaft 31 are in power fit connection with a power transmission belt 28, the driven transmission shaft 29 is in spline fit connection with an end face tooth shaft sleeve 60 positioned in the end face tooth transmission cavity 57, the right end of the end face tooth shaft sleeve 60 is in rotating fit connection with a magnetic connecting rod 54, the left end of the end face tooth shaft sleeve 60 is fixedly connected with a sliding end face tooth 59, and the right side of the end face tooth transmission cavity 57 is provided with a synchronous transmission belt cavity 26, the left end wall of the synchronous transmission belt cavity 26 is connected with a spiral vane shaft 24 which extends leftwards to the end face tooth transmission cavity 57 and rightwards to penetrate through the synchronous transmission belt cavity 26 to the noodle extrusion cavity 23 in a rotating and matching mode.

In addition, in one embodiment, a driving end face tooth 58 capable of meshing with the sliding end face tooth 59 is fixedly connected to the left end wall of the driven transmission shaft 29, a synchronous transmission shaft 53 extending through the end face tooth transmission chamber 57 to the synchronous transmission belt chamber 26 to the right is connected to the left end wall of the end face tooth transmission chamber 57 in a rotationally engaged manner, a sliding gear sleeve 55 in a spline engaged connection with the synchronous transmission shaft 53 is connected to the magnetic connecting rod 54 in a rotationally engaged manner, a sliding gear 56 capable of meshing with the driving end face tooth 58 is fixedly connected to the left end wall of the sliding gear sleeve 55, a synchronous transmission belt 27 located in the synchronous transmission belt chamber 26 is connected between the helical blade shaft 24 and the synchronous transmission shaft 53 in a rotationally engaged manner, a helical blade 25 located in the noodle extrusion chamber 23 is fixedly connected to the helical blade shaft 24, and a noodle forming die 21 is fixedly connected to the inner wall of the noodle extrusion chamber 23, be equipped with a plurality of noodless that link up about in the noodless forming die 21 and extrude hole 22, fixedly connected with connecting rod electro-magnet 62 in the end face tooth transmission chamber 57 right-hand member wall, magnetism connecting rod 54 right-hand member face with fixedly connected with end face tooth spring 61 between the end face tooth transmission chamber 57 right-hand member wall, driven gear chamber 45 upside intercommunication is equipped with straight gear drive chamber 13.

In addition, in an embodiment, the right side of the straight gear transmission cavity 13 is provided with a motor 16 fixedly connected with the main box body 10, the left end face of the motor 16 is fixedly connected with a motor shaft 15 extending leftwards into the straight gear transmission cavity 13, the left end of the motor shaft 15 is fixedly connected with a driving straight gear 14, the left side of the driven gear cavity 45 is communicated with an annular magnetic through cavity 43 which is annularly arranged by taking the driving transmission shaft 31 as the center, the right side of the annular magnetic through cavity 43 is communicated with a magnetic sliding plate cavity 39, the right side of the magnetic sliding plate cavity 39 is communicated with a pressing block sliding cavity 20, the right end of the driving transmission shaft 31 is fixedly connected with a rotating block 64, the rotating block 64 is rotatably and cooperatively connected with a driven gear 46, an annular rack cavity 47 which is annularly arranged by taking the driving transmission shaft 31 as the center and has an inward opening is arranged in the driven gear 46, under the initial condition, annular rack chamber 47 upside intercommunication is equipped with transmission pinion chamber 51, transmission pinion chamber 51 right side is equipped with slip nut chamber 49, slip nut chamber 49 right side intercommunication be equipped with the magnetism that the chamber 43 corresponds is led to annular magnetism leads to the chamber 37, the outer disc fixedly connected with of turning block 64 uses initiative transmission shaft 31 sets up and is located as central annular rack 48 in the annular rack chamber 47.

In addition, in one embodiment, the right end wall of the transmission pinion cavity 51 is connected with a transmission pinion shaft 50 which extends to the left in the sliding nut cavity 49 and extends to the left in the transmission pinion cavity 51 in a rotating fit manner, the left end of the transmission pinion shaft 50 is fixedly connected with a transmission pinion 52 which is meshed with the annular rack 48, the transmission pinion shaft 50 is connected with a sliding nut 36 which is connected with the sliding nut cavity 49 in a sliding fit manner in a threaded fit manner, the magnetic sliding plate cavity 39 is connected with a magnetic sliding plate 42 which corresponds to the sliding nut 36 in a sliding fit manner, the upper end wall of the magnetic sliding plate cavity 39 is fixedly connected with a contact switch 38, the right end wall of the pressing block sliding cavity 20 is connected with a knob 19 which extends to the outside in a rotating fit manner and extends to the inside of the pressing block sliding cavity 20, and the right end of the knob 19 is fixedly connected with a lead screw 18, the knob 19 is connected with a spring pressing block 17 in a threaded fit manner, the spring pressing block is connected with the pressing block sliding cavity 20 in a sliding fit manner, and a sliding plate spring 40 is fixedly connected between the left end face of the spring pressing block 17 and the right end face of the magnetic sliding plate 42.

In addition, in an embodiment, the sliding nut chamber 49 downside is equipped with the downward damping pearl chamber 63 of opening, be equipped with the upward damping pearl sliding chamber 68 that corresponds with damping pearl chamber 63 of opening in the turning block 64, sliding fit is connected with damping pearl 70 in the damping pearl sliding chamber 68, damping pearl 70 downside with fixedly connected with damping pearl spring 69 between the terminal wall of damping pearl sliding chamber 68 lower extreme, be equipped with the inward arc chamber 66 of opening in the driven gear 46, fixedly connected with on the outer disc of turning block 64 with slider 44 that arc chamber 66 sliding fit is connected, slider 44 preceding terminal surface with fixedly connected with arc spring 65 between the upper end wall of arc chamber 66.

The fixing and connecting method in this embodiment includes, but is not limited to, bolting, welding, and the like.

As shown in fig. 1-4, when the device of the present invention is in an initial state, the rear end surface of the slider 44 is attached to the rear end wall of the arc-shaped cavity 66, the arc-shaped spring 65 is in a relaxed state, the damping bead spring 69 is in a relaxed state, the upper side surface of the damping bead 70 is located in the damping bead cavity 63, the connecting rod electromagnet 62 is de-energized, the end surface tooth spring 61 is in a relaxed state, the sliding end surface tooth 59 is engaged with the driving end surface tooth 58, the sliding gear 56 is not engaged with the driving end surface tooth 58, the right end surface of the spring pressing block 17 is attached to the right end wall of the pressing block sliding cavity 20, the left end surface of the magnetic sliding plate 42 is attached to the left end wall of the magnetic sliding plate cavity 39, the sliding plate spring 40 is in a relaxed state, and the left end surface of the sliding nut 36 is attached to the left end wall of the sliding nut cavity 49;

sequence of mechanical actions of the whole device:

when the flour kneading machine starts to work, flour is poured into the dough kneading cavity 11, the water pump 34 is started, the water pump 34 absorbs water from the outside through the water inlet cavity 32, water is injected into the dough kneading cavity 11 through the water outlet cavity 35, the motor 16 is started at the same time, the motor shaft 15 is driven to rotate, the driving spur gear 14 is driven to rotate, the driven gear 46 is driven to rotate, the damping balls 70 are clamped into the damping ball cavities 63, the driven gear 46 is driven to rotate to drive the rotating block 64 to rotate, the driving transmission shaft 31 is driven to rotate, the stirring screw rod 12 is driven to rotate, flour in the dough kneading cavity 11 is stirred, the driving transmission shaft 31 rotates to drive the driven transmission shaft 29 to rotate through the power transmission belt 28, the driving end face teeth 58 are driven to rotate, the sliding end face teeth 59 are driven to rotate, the end face teeth shaft sleeve 60 is driven to rotate, the spiral blade shaft 24 is driven to rotate, and the spiral blades 25 are driven to rotate, so that the dough moves leftwards, and the dough is kneaded more thoroughly under the rotation of the stirring screw rod 12;

when kneading of dough is completed, the resistance to rotation of the stirring screw rod 12 is increased with respect to the previous mixture of flour and water, so that the resistance to rotation of the rotary block 64 is increased, the torque to rotation of the driven gear 46 is not changed, so that the tangential force to the damping beads 70 is increased to be greater than the elastic force of the damping bead springs 69, so that the damping beads 70 are moved down into the damping bead sliding chambers 68, so that the rotary block 64 and the driven gear 46 are relatively rotated, so that the arc springs 65 are compressed, and at the same time, the ring-shaped rack 48 is rotated to drive the driving pinion 52 to rotate, so that the driving pinion shaft 50 is rotated to drive the sliding nuts 36 to move rightward to repel the magnetic slide plates 42, and when the repulsive force is greater than the elastic force of the slide springs 40, the magnetic slide plates 42 are moved rightward to touch the contact switches 38 to stop the water pump 34, thereby stopping the water injection into the kneading chamber 11 from the water discharge chamber 35, and simultaneously triggering the contact switch 38 to always start the link electromagnet 62, so as to electrify the link electromagnet 62, attract the magnetic link 54, so as to make the magnetic link 54 move rightwards against the elastic force of the end face tooth spring 61, thereby driving the end face tooth shaft sleeve 60 to move rightwards, thereby making the sliding end face tooth 59 move rightwards to be disengaged from the driving end face tooth 58, and simultaneously the magnetic link 54 drives the sliding gear shaft sleeve 55 to move rightwards, thereby making the sliding gear 56 move rightwards to be engaged with the driving end face tooth 58, thereby making the driving end face tooth 58 rotate to drive the sliding gear 56 to rotate backwards, thereby making the sliding gear shaft sleeve 55 rotate backwards, thereby driving the synchronous transmission shaft 53 to rotate backwards, and driving the helical blade shaft 24 to rotate backwards through the synchronous transmission belt 27, thereby making the helical blade 25 rotate backwards, thereby rolling the dough in the kneading chamber 11 into the noodle extrusion chamber 23, the dough is extruded rightward through the noodle extruding hole 22 by the reverse rotation of the spiral blade 25, so that the dough is extruded into noodles;

if the water content when needs to increase the dough shaping, then rotate lead screw 18, make knob 19 rotate, thereby drive spring briquetting 17 and move left, thereby make slide spring 40 compress, thereby make slide spring 40 to the elasticity grow of magnetic slide 42, thereby make magnetic slide 42 overcome the repulsion force of slide spring 40's elasticity motion right and increase, then the distance that sliding nut 36 moved right needs to increase, thereby make 36 thereby start moving right to repulsion 42's time increase, and then make dough shaping when 42 begin to move right and touch 38's time increase, thereby make the dough shaping after continue to add moisture, thereby make the dough water content increase, make the noodless taste softer a bit, thereby realized the purpose that changes the dough water content through rotatory lead screw 18.

The invention has the beneficial effects that: slowly add water when flour stirs for flour and water mix more thoroughly, can be faster rub the shaping with the dough, improved noodless production efficiency, can automatic stop supply water to kneading the face intracavity during the dough shaping simultaneously, make the dough can not be because of the too much unable shaping of moisture, guaranteed noodless shaping quality, can be according to the required taste of different noodless moreover, water content when adjusting the dough shaping has improved the suitability of device greatly.

The above embodiments are merely illustrative of the technical ideas and features of the present invention, and the purpose thereof is to enable those skilled in the art to understand the contents of the present invention and implement the present invention, and not to limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered within the protection scope of the present invention.

Claims (5)

1. The utility model provides a noodless extrusion device of adjustable noodless water content, includes the main tank body, its characterized in that: a dough kneading cavity with an upward opening is arranged in the main box body, a noodle extruding cavity with a rightward opening is communicated with the lower side of the dough kneading cavity, a water discharging cavity is communicated with the left side of the dough kneading cavity, a water pump fixedly connected with the main box body is communicated with the left side of the water discharging cavity, an external water pipe is fixedly connected with the left end face of the main box body, a water inlet cavity extending to the left side in the external water pipe is communicated with the left side of the water pump, a power transmission belt cavity positioned on the lower side of the water pump is arranged on the left side of the dough kneading cavity, a driven gear cavity is arranged on the right side of the dough kneading cavity, a driving transmission shaft extending through the dough kneading cavity to the power transmission belt cavity is connected in a rotating fit manner in the right end wall of the driven gear cavity, a stirring screw rod positioned in the dough kneading cavity is fixedly connected on the driving transmission shaft, and an end face tooth transmission cavity is arranged on the right side of the power transmission belt cavity, power transmission area chamber right side end wall normal running fit is connected with and extends to right extend to left in the end face tooth transmission intracavity extend to driven transmission shaft in the power transmission area intracavity, driven transmission shaft left side end with power fit is connected with power transmission belt between the end in the driving transmission shaft left side, spline fit is connected with and is located on the driven transmission shaft the end face tooth axle sleeve in the end face tooth transmission intracavity, the terminal normal running fit in end face tooth axle sleeve right side is connected with the magnetism connecting rod, the terminal fixedly connected with slip end face tooth in end face tooth axle sleeve left side, end face tooth transmission chamber right side is equipped with synchronous drive area chamber, synchronous drive area chamber left end wall internal running fit is connected with and extends to left in the end face tooth transmission intracavity extend to run through right synchronous drive area chamber extremely the helical blade axle in the noodless extrusion intracavity.

2. A noodle extruding apparatus capable of adjusting a water content of noodles according to claim 1, wherein: the end of the left side of the driven transmission shaft is fixedly connected with a driving end face tooth which can be meshed with the sliding end face tooth, the end face tooth transmission cavity left end wall is connected with a synchronous transmission shaft which extends through the end face tooth transmission cavity to the synchronous transmission belt cavity in a rotating fit manner, the magnetic connecting rod is connected with a sliding gear shaft sleeve which is connected with the synchronous transmission shaft in a spline fit manner in a rotating fit manner, the end of the left side of the sliding gear shaft sleeve is fixedly connected with a sliding gear which can be meshed with the driving end face tooth, a synchronous transmission belt which is positioned in the synchronous transmission belt cavity is connected between a helical blade shaft and the synchronous transmission shaft in a power fit manner, a helical blade which is positioned in the noodle extrusion cavity is fixedly connected on the helical blade shaft, a noodle forming die is fixedly connected on the inner wall of the noodle extrusion cavity, and a plurality of noodle extrusion holes which are communicated from left to right are arranged in the noodle forming die, fixedly connected with connecting rod electro-magnet in the terminal surface tooth transmission chamber right-hand member wall, magnetism connecting rod right-hand member face with fixedly connected with terminal surface tooth spring between the terminal surface tooth transmission chamber right-hand member wall, driven gear chamber upside intercommunication is equipped with straight-teeth gear drive chamber.

3. A noodle extruding apparatus capable of adjusting a water content of noodles according to claim 2, wherein: the right side of the straight gear transmission cavity is provided with a motor fixedly connected with the main box body, the left end face of the motor is fixedly connected with a motor shaft which extends to the inside of the straight gear transmission cavity leftwards, the left end of the motor shaft is fixedly connected with a driving straight gear, the left side of a driven gear cavity is communicated with an annular magnetic through cavity which is annularly arranged by taking the driving transmission shaft as the center, the right side of the annular magnetic through cavity is communicated with a magnetic sliding plate cavity, the right side of the magnetic sliding plate cavity is communicated with a pressing block sliding cavity, the right end of the driving transmission shaft is fixedly connected with a rotating block, the rotating block is connected with a driven gear in a rotating and matching manner, an annular rack cavity which is annularly arranged by taking the driving transmission shaft as the center and has an inward opening is arranged in the driven gear, a transmission small gear cavity is communicated with the upper side of the annular rack cavity in an initial state, and a sliding nut cavity is arranged on the right side of the transmission small gear cavity, the right side of the sliding nut cavity is communicated with a magnetic through cavity corresponding to the annular magnetic through cavity, and the outer circular surface of the rotating block is fixedly connected with an annular rack which is arranged in an annular mode by taking the driving transmission shaft as a center and is located in the annular rack cavity.

4. A noodle extruding apparatus capable of adjusting a water content of noodles according to claim 3, wherein: the right end wall of the transmission pinion cavity is connected with a transmission pinion shaft which extends rightwards into the sliding nut cavity and leftwards into the transmission pinion cavity in a rotating fit manner, the left end of the transmission pinion shaft is fixedly connected with a transmission pinion which is meshed with the annular rack, the transmission pinion shaft is connected with a sliding nut which is connected with the sliding nut cavity in a sliding fit manner in a threaded fit manner, the magnetic sliding plate cavity is connected with a magnetic sliding plate which corresponds to the sliding nut in a sliding fit manner, the upper end wall of the magnetic sliding plate cavity is fixedly connected with a contact switch, the right end wall of the pressing block sliding cavity is connected with a knob which extends rightwards to the outside and inwards into the pressing block sliding cavity in a rotating fit manner, the right end of the knob is fixedly connected with a lead screw, and the knob is connected with a spring pressing block which is connected with the pressing block sliding cavity in a sliding fit manner in a threaded fit manner, and a sliding plate spring is fixedly connected between the left end surface of the spring pressing block and the right end surface of the magnetic sliding plate.

5. A noodle extruding apparatus capable of adjusting a water content of noodles according to claim 4, wherein: slip nut chamber downside is equipped with the decurrent damping pearl chamber of opening, be equipped with the opening in the turning block and upwards just with the damping pearl chamber of sliding of the damping pearl that corresponds, damping pearl sliding chamber sliding fit is connected with the damping pearl, damping pearl downside with fixedly connected with damping pearl spring between the terminal wall under the damping pearl sliding chamber, be equipped with the inside arc chamber of opening in the driven gear, fixedly connected with on the disc outside the turning block with the slider that arc chamber sliding fit connects, terminal surface before the slider with fixedly connected with arc spring between the arc chamber upper end wall.

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