CN219305874U - Energy-saving automatic noodle press - Google Patents

Abstract

The utility model discloses an energy-saving automatic noodle press, which relates to the technical field of noodle production and comprises a plurality of noodle pressing roller assemblies and a plurality of shrinkage type conveyor belts; a contraction type conveyor belt is arranged between the two dough pressing roller assemblies; the dough piece sequentially passes through a dough pressing roller assembly, a retractable conveyor belt and a dough pressing roller assembly; the end of the dough block passing through the previous dough pressing roller assembly falls onto the contraction type conveyor belt; the retractable conveyor can convey the end of the dough piece falling onto the retractable conveyor to the dough piece inlet of the next dough pressing roller assembly; the supporting plane height of the conveyor belt can be adjusted in the vertical direction. The utility model provides an energy-saving automatic noodle press, which solves the problems that in the prior art, in order to prevent friction between noodle blocks and a conveyor belt, the conveyor belt needs to rotate continuously, so that the problem of high energy consumption of the conveyor belt is caused; the equipment provided by the utility model can drive one end of the dough block to be conveyed to the inlet of the dough pressing roller by the conveyor belt, the conveyor belt integrally moves downwards, the conveyor belt stops working, and the energy consumption is reduced.

Description

Energy-saving automatic noodle press

Technical Field

The utility model relates to the technical field of noodle production, in particular to an energy-saving automatic noodle press.

Background

During the production process of the noodles, the dough needs to be cut into strips after being flattened. In the prior art, the dough is generally passed through two cylindrical pressing wheels which rotate continuously, the dough is pressed into dough blocks with the same thickness as the gap after passing through the gap between the pressing wheels, and the dough blocks continuously pass through the gap between the two pressing wheels with smaller spacing, so that the thickness of the dough blocks can be reduced; to ensure a uniform final thickness of the dough, multiple sets of pinch rollers are typically provided.

The manual operation of putting the dough piece between two pinch rollers is troublesome to the staff is pressed to hurt the finger by pivoted pinch roller in the operation in-process easily, among the prior art, like a three short cakes with sesame dough cover line that chinese patent application number 201610954325.2 discloses, holds the dough piece through setting up the conveyer belt between the roll of pressing the dough, holds the dough piece and removes, can make the dough piece can be carried by the conveyer belt between two pinch rollers, realizes the automation.

However, when the dough is fed between the two pressing wheels, in order to prevent the dough from generating sliding friction with the conveyor belt in the process of being driven by the rotation of the pressing wheels, the dough at the relative sliding position is broken, the conveyor belt needs to keep working at all times, so that the conveyor belt and the dough are kept relatively static, and the sliding friction between the dough and the conveyor belt is reduced; the continuous operation of the conveyor belt increases the energy consumption.

Disclosure of Invention

According to the energy-saving automatic noodle press, one end of the noodle block is driven by the conveyor belt to be conveyed to the inlet of the noodle pressing roller, and then the conveyor belt is integrally moved downwards to stop working of the conveyor belt, so that energy consumption is reduced.

In order to achieve the above purpose, the technical scheme adopted by the utility model is as follows:

the utility model provides an energy-saving automatic noodle press, which comprises a plurality of noodle pressing roller assemblies for thinning noodle blocks and a plurality of shrinkage type conveyor belts for moving the noodle blocks; one contraction type conveyor belt is arranged between the two dough pressing roller assemblies; the dough blocks sequentially pass through the dough pressing roller assembly, the shrinkage conveyor belt and the dough pressing roller assembly; the end of the dough block passing through the previous dough pressing roller assembly falls onto the contraction type conveyor belt; the retractable conveyor can convey the end of the dough falling onto the retractable conveyor to the dough inlet of the next dough pressing roller assembly; the retractable conveyor can adjust the planar height of the retractable conveyor pulling-up block in the vertical direction.

The energy-saving automatic noodle press provided by the utility model is characterized in that preferably, the face of the contraction type conveyor belt for bearing the noodle cake is obliquely arranged; the end part of the dough falls into the vertical position of the contraction type conveyor belt and is lower than the vertical position of the end part of the dough, which leaves the contraction type conveyor belt; the dough piece outlet of the dough pressing roller assembly is flush with the dough piece inlet of the dough pressing roller assembly.

The energy-saving automatic noodle press provided by the utility model is characterized in that preferably, the retractable conveyor belt comprises a retractable cylinder, a linkage rod and a conveyor belt body; the telescopic cylinder is rotatably fixed on the external structure; the telescopic end of the telescopic cylinder can be rotationally fixed on the linkage rod; one end of the linkage rod is rotatably fixed on the external structure; the other end of the linkage rod is rotatably fixed on the conveyor belt body; the conveyor belt body is slidably arranged on the external structure; the outlet of the conveyor belt is opposite to the inlet of the dough pressing roller assembly when the telescopic end of the telescopic cylinder is in an extension state; and the outlet of the conveying belt is lower than the inlet of the surface pressing roller assembly in the retraction state of the telescopic end of the telescopic cylinder.

The energy-saving automatic noodle press provided by the utility model is characterized in that preferably, the noodle pressing roller assembly comprises two rotatable noodle pressing wheels; the edge linear speeds of the two dough pressing wheels are equal when the two dough pressing wheels rotate; one of the dough pressing wheels is fixedly arranged above the other dough pressing wheel vertically; the radius of the dough pressing wheel positioned below is R; the movement route of the surface opening of the contraction type conveyor belt is an arc track taking a rotating shaft of a surface pressing wheel positioned below as an axis and taking a line segment larger than R as a radius.

The technical scheme has the following advantages or beneficial effects:

the utility model discloses an energy-saving automatic noodle press, which relates to the technical field of noodle production and comprises a plurality of noodle pressing roller assemblies for thinning noodle blocks and a plurality of shrinkage type conveyor belts for moving the noodle blocks; one contraction type conveyor belt is arranged between the two dough pressing roller assemblies; the dough blocks sequentially pass through the dough pressing roller assembly, the shrinkage conveyor belt and the dough pressing roller assembly; the end of the dough block passing through the previous dough pressing roller assembly falls onto the contraction type conveyor belt; the retractable conveyor can convey the end of the dough falling onto the retractable conveyor to the dough inlet of the next dough pressing roller assembly; the retractable conveyor can adjust the planar height of the retractable conveyor pulling-up block in the vertical direction. The energy-saving automatic noodle press provided by the utility model solves the problems that in the prior art, one end of a noodle block can be guided to the next noodle pressing roller by a conveyor belt to save labor, but in order to prevent friction between the noodle block and the conveyor belt, the conveyor belt needs to continuously rotate, so that the energy consumption of the conveyor belt is high; the equipment provided by the utility model can drive one end of the dough block to be conveyed to the inlet of the dough pressing roller by the conveyor belt, the conveyor belt integrally moves downwards, the conveyor belt stops working, and the energy consumption is reduced.

Drawings

The utility model and its features, aspects and advantages will become more apparent from the detailed description of non-limiting embodiments with reference to the following drawings. Like numbers refer to like parts throughout. The drawings are not intended to be drawn to scale, emphasis instead being placed upon illustrating the principles of the utility model.

Fig. 1 is a schematic diagram of the overall structure of an energy-saving automatic noodle press according to embodiment 1 of the present utility model.

Fig. 2 is an overall structure diagram of the retractable conveyor belt of the energy-saving automatic noodle press provided in embodiment 1 of the present utility model when it is put down.

Detailed Description

It should be noted that, in the case of no conflict, the embodiments and features in the embodiments may be combined with each other. It is noted that the terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of exemplary embodiments in accordance with the present application.

It will be understood that the terms "comprises" and/or "comprising," when used in this specification, specify the presence of stated features, steps, operations, devices, components, and/or groups thereof.

The terms "center," "upper," "lower," "left," "right," "vertical," "horizontal," "inner," "outer," and the like, as used herein, refer to an orientation or positional relationship based on that shown in the drawings, merely for convenience of description and to simplify the description, and do not denote or imply that the devices or elements referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus are not to be construed as limiting the utility model.

The terms "first," "second," "third," and the like, as used herein, are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

Unless specifically stated or limited otherwise, the terms "mounted," "connected," and "coupled" should be construed broadly, as if they were fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present utility model will be understood in specific cases by those of ordinary skill in the art.

The following description of the technical solutions according to the embodiments of the present utility model refers to the accompanying drawings, which are included to illustrate only some embodiments of the utility model, and not all embodiments. Accordingly, the following detailed description of the embodiments of the utility model, as presented in the figures, is not intended to limit the scope of the utility model, as claimed, but is merely representative of selected embodiments of the utility model. All other embodiments, which can be made by a person skilled in the art without making any inventive effort, are intended to fall within the scope of the present utility model.

Example 1:

the noodle is firstly pressed into noodle blocks with low thickness in the production process, and the noodle blocks cannot be directly pressed to the thickness of the cut noodle by one-time noodle pressing because the dough is thicker at first, and the noodle blocks are usually pressed to be thinner step by step through multiple noodle pressing processes; when a dough is pressed, the end of the dough needs to be guided to the inlet of each dough pressing roller in sequence, a conveyor belt is adopted in the prior art to complete the step, after the end of the dough is completely guided, the conveyor belt does not need to continuously guide the end of the dough, but in order to prevent the problem that the conveyor belt continuously rubs with the dough to cause breakage of the dough and continuous operation of the conveyor belt is required to cause large energy consumption of the conveyor belt, the energy-saving automatic dough pressing machine provided by the embodiment 1 of the utility model comprises a plurality of dough pressing roller assemblies 1 for thinning the dough and a plurality of shrinkage conveyor belts 2 for moving the dough, as shown in fig. 1 to 2; a retractable conveyor belt 2 is arranged between the two dough pressing roller assemblies 1; the dough piece sequentially passes through a dough pressing roller assembly 1, a retractable conveyor belt 2 and the dough pressing roller assembly 1; the end of the dough passing through the previous dough pressing roller assembly 1 falls onto the contraction type conveyor belt 2; the contraction type conveyor belt 2 can convey the end part of the dough falling onto the contraction type conveyor belt 2 to the dough inlet of the next dough pressing roller assembly 1; the retractable conveyor 2 can adjust the planar height of the retractable conveyor 2 pulling up the dough piece in the vertical direction.

When the energy-saving automatic noodle press provided by the embodiment 1 of the utility model works, initial dough is manually guided to the inlet of the noodle block of the first noodle pressing roller assembly 1, the noodle pressing roller assembly 1 works to extrude the dough so that the thickness of the dough is reduced, (the noodle pressing roller assembly 1 is the prior art, the extruded thickness of the noodle block can be changed by adjusting and changing the distance between two noodle pressing wheels of the noodle pressing roller assembly 1), the foremost end of the noodle block extruded by the first noodle pressing roller assembly 1 falls onto the contraction type conveyor belt 2, the foremost end of the noodle block is driven by the contraction type conveyor belt 2 to move to the inlet of the second noodle pressing roller assembly 1, the noodle block is extruded for the second time, and the thickness of the noodle block is further reduced; at this time, a part of the dough has not passed through the first dough roller assembly 1, a part is pressed into dough pieces by the first dough roller assembly 1, and a part passes through the second dough roller assembly 1; the shrink-type conveyor belt 2 between the first and second dough roller assemblies 1, 1 has completed its work (guiding the end of the dough piece to the entrance of the next dough roller assembly 1) at which time the dough piece is moved by the dough roller assembly 1 even if the shrink-type conveyor belt 2 does not rotate; the whole shrinkage type conveyor belt 2 is controlled to move downwards, so that the shrinkage type conveyor belt 2 does not drag up the dough, the shrinkage type conveyor belt 2 is directly separated from the dough and does not contact with the dough, the rotation of the shrinkage type conveyor belt 2 is closed, and energy is saved; the non-contact prevents the stop-rotation shrink-wrapped conveyor belt 2 from constantly rubbing against the dough pieces so that the dough pieces break due to friction.

The energy-saving automatic noodle press provided by the embodiment 1 of the utility model solves the problems that in the prior art, a conveyor belt can guide one end of a noodle block to the next noodle pressing roller to save labor, but in order to prevent friction between the noodle block and the conveyor belt, the conveyor belt needs to continuously rotate, so that the energy consumption of the conveyor belt is high; the equipment provided by the embodiment of the utility model can be used for driving one end of the dough block to be conveyed to the inlet of the dough pressing roller by the conveyor belt, then the conveyor belt moves down integrally, the conveyor belt stops working, and the energy consumption is reduced.

In order that the instant noodle blocks fall onto the contraction type conveyor belt 2 from the noodle roller assembly 1 and can fall to the inlet of the next noodle roller assembly 1 after passing through the contraction type conveyor belt 2, as a preferable scheme, in the embodiment, the noodle for bearing the noodle cake of the contraction type conveyor belt 2 is obliquely arranged; the end of the dough falls into the vertical position of the retractable conveyor belt 2 and is lower than the vertical position of the end of the dough leaving the retractable conveyor belt 2; the dough outlet of the dough pressing roller assembly 1 is flush with the dough inlet of the dough pressing roller assembly 1. When the dough piece is separated from the last dough pressing roller assembly 1, the dough piece moves downwards due to the gravity of the dough piece, the dough piece just falls on the shrinkage conveyor belt 2, the dough piece is lifted to be close to the position above the inlet of the last dough pressing roller assembly 1 by the guidance of the shrinkage conveyor belt 2, and the end of the dough piece falls to the inlet of the second dough pressing roller assembly 1 due to the weight of the dough piece. After the inclined shrinkage type conveyor belt 2 stops rotating, the dough blocks can be driven to move by the next dough pressing roller assembly 1, the rotation speed of the second dough pressing roller assembly 1 is controlled to be faster than that of the shrinkage type conveyor belt 2, the dough block part between the first dough pressing roller assembly 1 and the second dough pressing roller assembly 1 is straightened, the dough block part close to the first dough pressing roller assembly 1 can be separated from the shrinkage type conveyor belt 2, the contact position of the dough blocks and the shrinkage type conveyor belt 2 is reduced, the downward movement of the shrinkage type conveyor belt 2 is facilitated (the contact area between the dough blocks and the shrinkage type conveyor belt 2 is overlarge, adhesion is caused, and the separation of the shrinkage type conveyor belt 2 and the dough blocks is affected).

In order to specifically realize up-and-down movement of the telescopic conveyor belt 2 in the vertical direction, in the present embodiment, the telescopic conveyor belt 2 includes a telescopic cylinder 21, a link lever 22, and a conveyor belt body 23; the telescopic cylinder 21 is rotatably fixed on an external structure; the telescopic end of the telescopic cylinder 21 is rotatably fixed on the linkage rod 22; one end of the linkage rod 22 is rotatably fixed on the external structure; the other end of the linkage rod 22 is rotatably fixed on the conveyor belt body 23; the conveyor body 23 is slidably disposed on the outer structure; the outlet of the conveyor belt body 23 is opposite to the inlet of the surface pressing roller assembly 1 when the telescopic end of the telescopic cylinder 21 is in an extension state; the telescopic end of the telescopic cylinder 21 is in a retracted state, the outlet of the conveyor body 23 is lower than the inlet of the nip roller assembly 1. The telescopic cylinder 21 is in an extended state in a default state, at this time, the end part of the retractable conveyor belt 2 can guide the surface block to move to the inlet of the next surface pressing roller assembly 1, when the retractable conveyor belt 2 and the surface block are required to be separated, the telescopic cylinder 21 is controlled to be in a retracted state, so that the linkage rod 22 can rotate relative to the position of the linkage rod 22 rotatably connected with the outside due to the movement of the telescopic end of the telescopic cylinder 21, the conveyor belt body 23 fixed at the other end of the linkage rod 22 can bear force to move along with the movement of the conveyor belt body 23, and the movement of the conveyor belt body 23 can be limited on the sliding of the conveyor belt body relative to the external part; after the conveyer belt body 23 is stressed, the conveyer belt body 23 can only slide relative to an external structure, and the sliding of the conveyer belt body 23 can enable the shrinkage conveyer belt 2 to move downwards, so that the separation of the dough blocks and the shrinkage conveyer belt 2 is realized; in order to prevent the telescopic direction of the telescopic cylinder 21 from affecting the sliding of the conveyor belt body 23, the telescopic cylinder 21 rotates in comparison with the external structure during the sliding process of the conveyor belt body 23, which is beneficial to the forced movement of the conveyor belt body 23.

For a specific implementation of the feeding of the dough ends to the inlet of the dough roller assembly 1, as a preferred solution, the dough roller assembly 1 comprises in this embodiment two rotatable dough rollers 11; the edge linear speeds of the two dough pressing wheels 11 are equal when the two dough pressing wheels rotate; one of the dough pressing wheels 11 is fixedly arranged vertically above the other dough pressing wheel 11; the radius of the surface pressing wheel 11 positioned below is R; the movement route of the exit of the contraction type conveyor belt 2 is a circular arc track taking the rotating shaft of the pressing surface wheel 11 positioned below as an axis and taking a line segment larger than R as a radius. After one end of the dough piece falls onto the conveyor belt body 23 from between the two dough pressing wheels 11 of the previous dough pressing roller assembly 1, the end of the dough piece can be driven by the conveyor belt body 23 to between the two dough pressing wheels 11 of the next dough pressing roller assembly 1, the dough outlet of the shrinkage conveyor belt 2 is larger than the radius of the dough pressing wheels below, collision between the shrinkage conveyor belt 2 and the dough pressing wheels 11 can be prevented, and normal operation of equipment is facilitated.

In summary, the utility model discloses an energy-saving automatic noodle press, which relates to the technical field of noodle production and comprises a plurality of noodle pressing roller assemblies for thinning noodle blocks and a plurality of shrinkage conveyor belts for moving the noodle blocks; one contraction type conveyor belt is arranged between the two dough pressing roller assemblies; the dough blocks sequentially pass through the dough pressing roller assembly, the shrinkage conveyor belt and the dough pressing roller assembly; the end of the dough block passing through the previous dough pressing roller assembly falls onto the contraction type conveyor belt; the retractable conveyor can convey the end of the dough falling onto the retractable conveyor to the dough inlet of the next dough pressing roller assembly; the retractable conveyor can adjust the planar height of the retractable conveyor pulling-up block in the vertical direction. The energy-saving automatic noodle press provided by the utility model solves the problems that in the prior art, one end of a noodle block can be guided to the next noodle pressing roller by a conveyor belt to save labor, but in order to prevent friction between the noodle block and the conveyor belt, the conveyor belt needs to continuously rotate, so that the energy consumption of the conveyor belt is high; the equipment provided by the utility model can drive one end of the dough block to be conveyed to the inlet of the dough pressing roller by the conveyor belt, the conveyor belt integrally moves downwards, the conveyor belt stops working, and the energy consumption is reduced.

The foregoing description is only of the preferred embodiments of the present utility model and is not intended to limit the scope of the utility model, and all equivalent structural changes made by the present utility model and the accompanying drawings, or direct or indirect application in other related technical fields, are included in the scope of the present utility model.

Claims (4)

1. An energy-saving automatic noodle press is characterized by comprising a plurality of noodle pressing roller assemblies for thinning noodle blocks and a plurality of shrinkage type conveyor belts for moving the noodle blocks;

one contraction type conveyor belt is arranged between the two dough pressing roller assemblies;

the dough blocks sequentially pass through the dough pressing roller assembly, the shrinkage conveyor belt and the dough pressing roller assembly;

the end of the dough block passing through the previous dough pressing roller assembly falls onto the contraction type conveyor belt; the retractable conveyor can convey the end of the dough falling onto the retractable conveyor to the dough inlet of the next dough pressing roller assembly;

the retractable conveyor can adjust the planar height of the retractable conveyor pulling-up block in the vertical direction.

2. The energy efficient automatic dough sheeter of claim 1, wherein the face of the retractable conveyor for carrying dough cake is inclined; the end part of the dough falls into the vertical position of the contraction type conveyor belt and is lower than the vertical position of the end part of the dough, which leaves the contraction type conveyor belt;

the dough piece outlet of the dough pressing roller assembly is flush with the dough piece inlet of the dough pressing roller assembly.

3. The energy efficient automatic noodle press of claim 2, wherein the retractable conveyor comprises a telescoping cylinder, a linkage, and a conveyor body;

the telescopic cylinder is rotatably fixed on the external structure; the telescopic end of the telescopic cylinder can be rotationally fixed on the linkage rod;

one end of the linkage rod is rotatably fixed on the external structure; the other end of the linkage rod is rotatably fixed on the conveyor belt body;

the conveyor belt body is slidably arranged on the external structure;

the outlet of the conveyor belt body is opposite to the inlet of the dough pressing roller assembly when the telescopic end of the telescopic cylinder is in an extension state; and the outlet of the conveyor belt body is lower than the inlet of the dough pressing roller assembly when the telescopic end of the telescopic cylinder is in a retracted state.

4. The energy efficient automatic noodle press as defined in claim 3, wherein said noodle roller assembly comprises two rotatable noodle rollers; the edge linear speeds of the two dough pressing wheels are equal when the two dough pressing wheels rotate; one of the dough pressing wheels is fixedly arranged above the other dough pressing wheel vertically; the radius of the dough pressing wheel positioned below is R;

the movement route of the surface opening of the contraction type conveyor belt is an arc track taking a rotating shaft of the surface pressing wheel positioned below as an axis and taking a line segment larger than R as a radius.

Images