CN108247705B

CN108247705B - Full-automatic rice noodle cutting machine

Info

Publication number: CN108247705B
Application number: CN201810271571.7A
Authority: CN
Inventors: 王仁和; 王杰; 陈�田; 朱家诚; 吴焱明; 苗凯; 武林; 魏泽旭; 孟凡喜
Original assignee: Anhui Wangrenhe Vermicelli Food Co ltd
Current assignee: Anhui Wangrenhe Vermicelli Food Co ltd
Priority date: 2018-03-29
Filing date: 2018-03-29
Publication date: 2023-09-15
Anticipated expiration: 2038-03-29
Also published as: CN108247705A

Abstract

The invention relates to a full-automatic rice noodle cutting machine, which comprises a feeding component, a working component positioned beside the feeding component and a cutting component positioned below the working component, wherein the working component is positioned at the side of the feeding component; the invention fills the defect of the traditional manual rice noodle cutting technology, is simple and convenient to operate, folds and hangs the dried rice noodle on the rice noodle rod, conveys the rice noodle rod to the working assembly to be pressed and fixed after being transported and counted by the feeding assembly, and outputs and packages the rice noodle rod after being matched with the cutting assembly to finish cutting; on one hand, the labor intensity of workers can be reduced, the workers do not need to carry out dangerous labor production any more, and the machine replaces manual operation; on the other hand, the labor amount required in the production process can be reduced, the production cost is saved, and the production efficiency is improved.

Description

Full-automatic rice noodle cutting machine

Technical Field

The invention relates to the field of rice noodle processing equipment, in particular to a full-automatic rice noodle cutting machine.

Background

After the rice noodles are produced and dried, rice noodles are required to be cut in order by each rice noodle manufacturer, and then can be packaged, so that the cutting procedure of the rice noodles is an important link of rice noodle industrialized production. In the prior art, the dried rice noodle is usually taken down from the production line manually, and is manually conveyed to a cutting saw blade (strip) for cutting and then is bundled, so that the labor intensity is high; meanwhile, the manual cutting is relatively close to the saw blade, and the risk is relatively high.

Disclosure of Invention

The invention aims to provide a full-automatic rice noodle cutting machine which replaces the traditional manual rice noodle cutting procedure, improves the production efficiency and ensures the operation safety.

In order to achieve the above purpose, the present invention adopts the following technical scheme:

a full-automatic rice noodle cutting machine comprises a feeding component, a working component positioned beside the feeding component and a cutting component positioned below the working component;

the feeding assembly comprises a feeding rack, a first speed reducer and a first bearing seat are oppositely arranged at the top end of the feeding rack, a first motor is installed at the input end of the first speed reducer, and a first transmission shaft is installed at the output end of the first speed reducer; one end of the first transmission shaft is connected with the first bearing seat, a first sprocket is arranged at the end of the first transmission shaft, and the other end of the first transmission shaft extends out of the shell of the first speed reducer and a second sprocket is arranged at the end of the first transmission shaft; a second bearing seat and a third bearing seat are correspondingly arranged below the first sprocket and the second sprocket on the feeding frame respectively; two third chain wheels are arranged on the second bearing through a rotating shaft, one of the third chain wheels is connected with the first chain wheel through a chain, and the other third chain wheel is connected with the fifth chain wheel through a chain; the third bearing seat is provided with two fourth chain wheels through a rotating shaft, one of the fourth chain wheels is connected with the second chain wheel through a chain, and the other fourth chain wheel is connected with the sixth chain wheel through a chain; the fifth chain wheel and the sixth chain wheel are symmetrically arranged on one side of the feeding frame adjacent to the working assembly, a fourth bearing seat is arranged on the feeding frame below the fifth chain wheel and the sixth chain wheel, a turnover plate is arranged on the fourth bearing seat through a rotating shaft, two first cylinders are symmetrically fixed on two sides of the turnover plate, and a piston rod end of any first cylinder is upwards along the side edge of the turnover plate and is connected with a fork plate for taking out a rice noodle rod; two second cylinders are symmetrically arranged on the feeding frame, and piston rod ends of the two second cylinders are movably connected with two sides of the turnover plate;

the working assembly comprises a working machine frame, a third cylinder is arranged at the top end of the working machine frame, and a piston rod end of the third cylinder is vertically downward and is connected with a compression plate; the device comprises a working frame, a first motor, a first speed reducer, a second motor, a second speed reducer, a second transmission shaft, two synchronous pulleys, two driven pulleys, a movable beam, two traction hands, a fork plate and a fork plate, wherein the first speed reducer is driven by the first motor; a plurality of rows of conveyor belts driven by a third motor are arranged below the moving beam on the working frame in parallel, and gaps are reserved on two sides of any conveyor belt;

the cutting assembly comprises a cutting machine frame, two platform sliding rails are symmetrically arranged at the top of the cutting machine frame, a moving platform is movably connected between the two platform sliding rails, a ball screw driven by a fourth motor is arranged below the moving platform, and the moving platform is fixed on a nut of the ball screw; the movable platform is symmetrically provided with two fifth bearing seats, a saw blade shaft is arranged between the two fifth bearing seats, the saw blade shaft is driven by a fifth motor arranged on the movable platform, a plurality of saw blades are arranged on the saw blade shaft side by side, the size of each saw blade is matched with the gaps on two sides of the conveyor belt, and each saw blade stretches out of the upper side of the conveyor belt through the corresponding gap.

Further, two fork plate sliding rails are symmetrically arranged on two sides of the turnover plate, and sliding blocks matched with the fork plate sliding rails are fixed on the fork plates.

Further, a counting detector is arranged above the rear part of the fifth chain wheel and the sixth chain wheel on the feeding frame.

Further, the pressing plate comprises a supporting frame connected with the piston rod end of the third air cylinder and a plurality of pressing plates fixed at the bottom of the supporting frame in parallel, and a space corresponding to the gap is reserved between the pressing plates.

Further, both ends of the conveyor belt are respectively arranged on the working frame through a driving roller and a driven roller, and an output shaft of the third motor is connected with one end of the driving roller.

Further, a waste port is arranged at one end far away from the feeding assembly in the working frame, and a blanking plate is arranged beside the conveyor belt at the end.

Further, a driven wheel is arranged at one end of the saw blade shaft, a driving wheel is arranged on an output shaft of the fifth motor, and the driven wheel is connected with the driving wheel through a V belt in a transmission manner.

Further, the intervals between the saw blades are equal.

The invention has the beneficial effects that: the equipment fills the defect of the traditional rice-flour wire cutting technology, on one hand, the labor intensity of workers can be reduced, the workers do not need dangerous labor production, and the machine replaces manual operation; on the other hand, the labor amount required in the production process can be reduced, the production cost is saved, and the production efficiency is improved.

Drawings

FIG. 1 is a schematic diagram of the structure of the present invention;

FIG. 2 is a schematic diagram of a loading assembly;

FIG. 3 is a schematic diagram of a second loading assembly;

FIG. 4 is a schematic diagram of the combined construction of the working assembly and the cutting assembly;

FIG. 5 is a schematic illustration of a construction of a working assembly;

FIG. 6 is a second schematic structural view of the working assembly;

FIG. 7 is a schematic view of a cutting assembly;

FIG. 8 is a schematic diagram of a second embodiment of a cutting assembly;

wherein: 1-feeding assembly, 100-feeding frame, 101-first speed reducer, 102-first bearing seat, 103-first motor, 104-first transmission shaft, 105-first sprocket, 106-second sprocket, 107-second bearing seat, 108-third bearing seat, 109-third sprocket, 110-fifth sprocket, 111-fourth sprocket, 112-sixth sprocket, 113-fourth bearing seat, 114-turnover plate, 115-first cylinder, 116-fork plate, 117-second cylinder, 118-fork plate slide rail, 119-slide block, 120-count detector, 2-working assembly, 200-working frame, 201-third cylinder, 202-hold-down plate, 203-second motor 204-second speed reducer, 205-second transmission shaft, 206-synchronous pulley, 207-driven pulley, 208-synchronous belt, 209-moving beam, 210-moving slide rail, 211-traction hand, 212-conveyor belt, 213-gap, 214-supporting frame, 215-pressing plate, 216-gap, 217-driving roller, 218-driven roller, 219-blanking plate, 220-auxiliary conveyor belt, 3-cutting assembly, 300-cutting frame, 301-platform slide rail, 302-moving platform, 303-fourth motor, 304-ball screw, 305-fifth bearing seat, 306-saw blade shaft, 307-fifth motor, 308-saw blade, 309-driven wheel, 310-driving wheel, 311-V belt.

Detailed Description

The invention is further described below with reference to the accompanying drawings:

referring to fig. 1, a full-automatic rice noodle cutting machine comprises a feeding assembly 1, a working assembly 2 positioned beside the feeding assembly, and a cutting assembly 3 positioned below the working assembly 2.

Referring to fig. 2 and 3, the feeding assembly 1 includes a feeding frame 100, a first speed reducer 101 and a first bearing seat 102 are disposed on top of the feeding frame 100, an input end of the first speed reducer 101 is provided with a first motor 103, and an output end of the first speed reducer 101 is provided with a first transmission shaft 104.

One end of the first transmission shaft 104 is connected with the first bearing seat 102, and a first sprocket 105 is mounted at the end, and the other end of the first transmission shaft 104 extends out of the housing of the first speed reducer 101, and a second sprocket 106 is mounted at the end.

The feeding frame 100 is provided with a second bearing seat 107 and a third bearing seat 108 respectively corresponding to the lower parts of the first sprocket 105 and the second sprocket 106. The second bearing 107 is provided with two third sprockets 109 via a rotation shaft, one of the third sprockets 109 is connected to the first sprocket 105 via a chain, and the other third sprocket 109 is connected to a fifth sprocket 110 via a chain. The third bearing seat 108 is provided with two fourth chain wheels 111 through a rotating shaft, one fourth chain wheel 111 is connected with the second chain wheel 106 through a chain, and the other fourth chain wheel 111 is connected with the sixth chain wheel 112 through a chain.

The fifth sprocket 110 and the sixth sprocket 112 are symmetrically arranged on one side of the feeding frame 100 adjacent to the working assembly 2, a fourth bearing seat 113 is mounted on the feeding frame 100 below the fifth sprocket 110 and the sixth sprocket 112, a turnover plate 114 is mounted on the fourth bearing seat 113 through a rotating shaft, two first cylinders 115 are symmetrically fixed on two sides of the turnover plate 114, a fork plate 116 for taking out a wire rod is connected with a piston rod end of any of the first cylinders 115 upwards along the side edge of the turnover plate 114, two fork plate sliding rails 118 are symmetrically arranged on two sides of the turnover plate 114, and a sliding block 119 matched with the fork plate sliding rails 118 is fixed on the fork plate 116.

A counting detector 120 is installed on the feeding frame 100 above and behind the fifth sprocket 110 and the sixth sprocket 112 to count the number of rice noodles passing through the fifth sprocket 110 and the sixth sprocket 112.

Two second cylinders 117 are symmetrically arranged on the feeding frame 100, and piston rod ends of the two second cylinders 117 are movably connected with two sides of the turnover plate 114, in this embodiment, through holes are formed in two sides of the turnover plate 114, and the through holes are connected with the piston rod ends of the second cylinders 117 through pin shafts.

Referring to fig. 5 and 6, the working assembly 2 includes a working frame 200, a third cylinder 201 is mounted on the top end of the working frame 200 through a cylinder bracket, and a compression plate 202 is connected to a piston rod end of the third cylinder 201 vertically downward.

As an implementation manner of this embodiment, the pressing plate 202 includes a supporting frame 214 connected to a piston rod end of the third air cylinder 201, and a plurality of pressing plates 215 fixed on the bottom of the supporting frame 214 in parallel, and a space 216 is left between the pressing plates 215.

A second speed reducer 204 driven by a second motor 203 is installed at one end of the working frame 200, the output end of the second speed reducer 204 is connected with a second transmission shaft 205, one end of the second transmission shaft 205 is installed through a bearing on the working frame 200, two synchronous pulleys 206 are installed on the second transmission shaft 205, the two synchronous pulleys 206 are close to the side edge of the working frame 200, two driven pulleys 207 are installed at the other end of the working frame 200 corresponding to the two synchronous pulleys 206 through bolts, and each group of corresponding synchronous pulleys 206 and driven pulleys 207 are connected through a synchronous belt 208.

A moving beam 209 is fixed between the bottoms of the two synchronous belts 208 through bolts, two ends of the moving beam 209 are movably connected with two moving slide rails 210 arranged on two sides of the working frame 200 respectively, and two traction hands 211 matched with the fork plate 116 are arranged on the moving beam 209. Thus, when the fork plate 116 ejects the wire rod to the pulling hand 211, the moving beam 209 can drive the wire rod on the pulling hand 211 to move the dried wire rod to the other end of the working frame 200.

A plurality of rows of conveyor belts 212 driven by a third motor 221 are arranged in parallel on the working frame 200 below the moving beam 209, two ends of the conveyor belts 212 are respectively arranged on the working frame 200 through a driving roller 217 and a driven roller 218, meanwhile, an auxiliary conveyor belt 220 for conveying the cut rice noodles out of the working frame 200 is also connected to the driving roller 217, and the auxiliary conveyor belts 220 and the conveyor belts 212 are alternately arranged. An output shaft of the third motor 221 is connected with one end of the driving roller 217, so as to drive the driving roller 217 to rotate, and further drive the conveyor belt 212 and the auxiliary conveyor belt 220 to work, and a gap 213 is reserved between two sides of any conveyor belt 212. The gap 213 corresponds to a gap 216 between the platens 215, which serves as an extension channel for the cutting blade.

The working frame 200 is provided with a waste port at one end far away from the feeding assembly 1, and a blanking plate 219 is arranged beside the conveyor belt 212 at the end, and the rice noodle rods and the waste are dropped and carried out from the waste port after cutting.

Referring to fig. 7 and 8, the cutting assembly 3 includes a cutting frame 300, two platform sliding rails 301 are symmetrically disposed at the top of the cutting frame 300, a moving platform 302 is movably connected between the two platform sliding rails 301, a ball screw 304 driven by a fourth motor 303 is disposed below the moving platform 302, and the moving platform 302 is fixed on a nut of the ball screw 304.

Two fifth bearing seats 305 are symmetrically arranged on the moving platform 301, a fifth motor 307 is fixed beside one fifth bearing seat 305, a saw blade shaft 306 is installed between the two fifth bearing seats 305, a driven wheel 309 is installed at one end of the saw blade shaft 306, a driving wheel 310 is installed on an output shaft of the fifth motor 307, and the driven wheel 309 and the driving wheel 310 are in transmission connection through a V belt 311.

The saw blade shaft 306 is provided with a plurality of saw blades 308 side by side, the intervals between the saw blades 308 are equal, the size of the saw blade 308 is matched with the gaps 213 on two sides of the conveyor belt 212, the saw blade 308 extends out of the upper side of the conveyor belt 212 through the corresponding gaps 213, and the ball screw 304 drives the saw blade 308 to move back and forth to complete the cutting work of the dried rice noodles on the conveyor belt 212.

The specific working process of the invention is as follows:

the dried rice noodles are folded and hung on a rice noodle rod, then the rice noodle rod is sent to a feeding assembly 1, two ends of the rice noodle rod are respectively arranged on a chain between a third chain wheel 109 and a fifth chain wheel 110 and a chain between a fourth chain wheel 111 and a sixth chain wheel 112, a first motor 103 drives a first speed reducer 101 to act, the rice noodle rod is conveyed to one side of a working assembly 2 and enters a fork plate 116, each time the rice noodle rod is counted by a counting detector 120, when the preset number requirement is met, a turnover plate 114 turns over towards the working assembly 2 under the action of a second cylinder 117, and when the rice noodle rod turns over to a traction hand 211 position, the first cylinder 115 acts to push the fork plate 116 to push the rice noodle rod out to the traction hand 211 along a fork plate sliding rail 118; then the second motor 203 drives the second speed reducer 204 to drive the synchronous belt 208 to act, and then drives the movable beam 209 to move towards the waste port along the movable guide rail 210, the rice noodles to be dried on the rice noodle rod are laid on each conveyor belt 212 below in the moving process, then the third air cylinder 201 acts, the rice noodles are pressed by the pressing plate 202, then the fifth motor 307 on the cutting assembly acts, the saw blade 308 is driven to rotate, meanwhile, the ball screw 304 is also driven by the fourth motor 303 to push towards the cutting direction, and the saw blade moves through the gaps 213 between the conveyor belts 212 to complete the cutting of the dried rice noodles; after the cutting is completed, the third air cylinder 201 acts on the pressing plate 202 to lift up and loosen the rice noodles, and the third motor 221 drives the driving roller 217 to rotate, so that the working frame 200 is conveyed to the packing station through the conveying belt 212 and the auxiliary conveying belt 220, and the rice noodles rods and the waste materials on the rice noodles rods are discharged from the blanking plate 219 at the waste material port.

The above examples are only illustrative of the preferred embodiments of the present invention and are not intended to limit the scope of the present invention, and various modifications and improvements made by those skilled in the art to the technical solution of the present invention should fall within the scope of protection defined by the claims of the present invention without departing from the spirit of the present invention.

Claims

1. A full-automatic rice noodle cutting machine which characterized in that: the cutting device comprises a feeding assembly, a working assembly positioned beside the feeding assembly and a cutting assembly positioned below the working assembly;

2. The fully automatic wire cutting machine according to claim 1, wherein: two fork plate sliding rails are symmetrically arranged on two sides of the turnover plate, and sliding blocks matched with the fork plate sliding rails are fixed on the fork plates.

3. The fully automatic wire cutting machine according to claim 1, wherein: and a counting detector is arranged above the rear part of the fifth chain wheel and the sixth chain wheel on the feeding frame.

4. The fully automatic wire cutting machine according to claim 1, wherein: the pressing plate comprises a supporting frame connected with the end of the piston rod of the third air cylinder and a plurality of pressing plates fixed at the bottom of the supporting frame in parallel, and a space corresponding to the gap is reserved between the pressing plates.

5. The fully automatic wire cutting machine according to claim 1, wherein: the two ends of the conveyor belt are respectively arranged on the working frame through a driving roller and a driven roller, and an output shaft of the third motor is connected with one end of the driving roller.

6. The fully automatic wire cutting machine according to claim 1, wherein: the waste material port is arranged at one end far away from the feeding component in the working frame, and the blanking plate is arranged beside the conveyor belt at the end.

7. The fully automatic wire cutting machine according to claim 1, wherein: the driven wheel is arranged at one end of the saw blade shaft, the driving wheel is arranged on the output shaft of the fifth motor, and the driven wheel is connected with the driving wheel through a V belt in a transmission way.

8. The fully automatic wire cutting machine according to claim 1, wherein: the distance between the saw blades is equal.