CN218172747U - Automatic material stacking mechanism for rice noodle production - Google Patents

Abstract

The utility model relates to a rice noodle production is with automatic material mechanism of folding, its characterized in that: the device comprises a rack, a telescopic feeding platform and a stacking platform, wherein the telescopic feeding platform and the stacking platform are arranged on the rack; a proximity switch is arranged at one end of the rack close to the material stacking platform; the telescopic feeding platform comprises a feeding conveyer belt, a first driving motor for driving the feeding conveyer belt to run and a drawing mechanism for driving the feeding conveyer belt to stretch; the stacking platform comprises a stacking conveying belt, a transverse moving mechanism for driving the stacking conveying belt to transversely move and a lifting mechanism for driving the stacking conveying belt to lift. The utility model discloses a telescopic feeding platform carries the ground rice of cut to the liftable fold the material platform on, fold one deck back on folding the material platform, carry to packagine machine to construct by folding the material platform again and pack.

Description

Automatic material stacking mechanism for rice noodle production

Technical Field

The utility model relates to a rice noodle production is with automatic material mechanism that folds belongs to food processing equipment technical field.

Background

The rice noodles are also called as the Sha river noodles, are a common snack main material in Guangdong and southeast Asia in China, the rice is used as the raw material of the rice noodles, the manufacture of the rice noodles is slightly complicated, and the traditional manual manufacture of the rice noodles is low in efficiency and cannot meet the market demand. The existing rice noodle making machine is capable of quickly making rice noodle, and the rice noodle is cut, weighed, manually stacked and finally sent to packaging equipment for packaging after the rice noodle is made. The manual stacking means that the cut rice noodles are stacked into one layer, and then packaged after reaching a certain number of layers, so that the manual stacking has low working efficiency and high labor cost, and can not meet the requirements of modern automatic production.

Therefore, how to provide an automatic material stacking mechanism for producing rice noodles is the research object of the utility model.

SUMMERY OF THE UTILITY MODEL

Not enough to the above-mentioned technique, the utility model provides a ground rice production is with automatic material mechanism of folding carries the ground rice that cuts to the liftable through telescopic feeding platform and folds into the one deck on folding the material platform on, packs to packagine machine structure by folding the material platform again.

For solving the prior art problem, the utility model discloses the technical scheme who adopts is:

the utility model provides a rice noodles production is with automatic material mechanism of folding which characterized in that: the device comprises a rack, a telescopic feeding platform and a stacking platform, wherein the telescopic feeding platform and the stacking platform are arranged on the rack; a proximity switch is arranged at one end of the rack close to the material stacking platform; the telescopic feeding platform comprises a feeding conveyer belt, a first driving motor for driving the feeding conveyer belt to operate and a drawing mechanism for driving the feeding conveyer belt to stretch; the feeding conveyer belt comprises a main transmission shaft in transmission connection with the first driving motor, a tensioning roller for adjusting the tightness of the feeding conveyer belt and a driven roller for driving the feeding conveyer belt to stretch; the drawing mechanism comprises a drawing plate, a sliding rod and a transmission belt; the sliding rod is arranged at the top of the rack; the drawing plate is slidably arranged on the sliding rod through a linear bearing; two sides of the drawing plate are fixedly connected with the driven roller; two ends of the transmission belt are arranged below the sliding rod through synchronous wheels and are connected with the bottom of the pull plate through belt clamps; one end of the transmission belt is connected with a first servo motor for driving the transmission belt to run; the stacking platform comprises a stacking conveying belt, a transverse moving mechanism and a lifting mechanism; the lifting mechanism comprises a bottom plate, a lifting plate arranged above the bottom plate in a lifting manner and a second servo motor fixedly arranged on the bottom plate; an output shaft of the second servo motor is provided with a swing arm; the top end of the swing arm is connected with the bottom end of the lifting plate; the transverse moving mechanism comprises a base, an installation plate which is slidably installed above the base and a cylinder which is fixedly installed on the base; the tail end of a piston rod of the air cylinder is connected with the mounting plate through a connecting plate; two sides of the stacked material conveying belt are arranged on the mounting plate through vertical plates; one side of the stacking conveying belt is connected with a second driving motor for driving the stacking conveying belt to operate.

Further, the height of the feeding conveyer belt is always higher than that of the stacking conveyer belt.

Furthermore, a slag receiving disc is arranged at one end, close to the stacking platform, of the rack; the slag receiving disc is arranged below the discharge end of the stacking conveying belt; a slag scraping plate is arranged below the discharge end of the stacking conveyor belt; the slag scraping plate is positioned above the slag receiving disc.

Furthermore, the pull plate is arranged on the inner side of the feeding conveyer belt in a crossing mode and drives the feeding conveyer belt to stretch and retract through the driven roller.

The utility model has the advantages that: 1. the cut river powder is conveyed to the liftable material stacking platform through the telescopic feeding platform, and is stacked into a layer on the material stacking platform, and then conveyed to the packaging mechanism by the material stacking platform for packaging, so that manual material stacking is replaced, and the working efficiency is high; 2. the stacking platform can be lifted, the height of the stacking platform can be adjusted according to the height of stacked materials, and the situation that the river powder is placed unevenly due to large fall when falling is avoided; 3. but fold material platform sideslip, but horizontal hunting during the blanking avoids the river powder too to pile up in the middle, causes the high both sides in excessive middle low.

Drawings

Fig. 1 is a schematic structural diagram of the present invention.

Fig. 2 is a schematic structural view of the telescopic feeding platform of the present invention.

Fig. 3 is a schematic structural view of the feeding and conveying belt of the present invention.

Fig. 4 is a schematic structural view of the drawing mechanism of the present invention.

Fig. 5 is a schematic structural view of the stacking platform of the present invention.

Fig. 6 is a right side view of the stacking platform of the present invention.

Fig. 7 is a schematic structural view of the material stacking and conveying belt of the present invention.

Fig. 8 is a schematic structural view of the traverse mechanism of the present invention.

Fig. 9 is a schematic structural view of the lifting mechanism of the present invention.

Wherein: the device comprises a rack 10, a telescopic feeding platform 20, a stacking platform 30, a proximity switch 40, a slag receiving disc 50, a feeding conveyer belt 201, a drawing mechanism 202, a first driving motor 2011, a main transmission shaft 2012, a tensioning roller 2013, a driven roller 2014, a drawing plate 2021, a sliding rod 2022, a transmission belt 2023, a first servo motor 2024, a stacking conveyer belt 301, a transverse moving mechanism 302, a lifting mechanism 303, a second driving motor 3011, a slag scraping plate 3012, a base 3021, a mounting plate 3022, an air cylinder 3023, a bottom plate 3031, a lifting plate 3032, a second servo motor 3033 and a swing arm 3034.

Detailed Description

In order to make the technical solution of the present invention more understandable to those skilled in the art, the present invention is further analyzed with reference to fig. 1 to 9.

As shown in fig. 1-9, an automatic material stacking mechanism for rice noodle production is characterized in that: the device comprises a frame 10, a telescopic feeding platform 20 and a stacking platform 30, wherein the telescopic feeding platform 20 and the stacking platform 30 are installed on the frame 10; a proximity switch 40 is arranged at one end of the frame 10 close to the material stacking platform 30; the telescopic feeding platform 20 comprises a feeding conveyer belt 201, a first driving motor 2011 for driving the feeding conveyer belt 201 to run, and a drawing mechanism 202 for driving the feeding conveyer belt 201 to stretch and retract; the feeding conveyer belt 201 comprises a main transmission shaft 2012 in transmission connection with the first driving motor 2011, a tension roller 2013 for adjusting the tightness of the feeding conveyer belt 201 and a driven roller 2014 for driving the feeding conveyer belt 201 to stretch and retract; the drawing mechanism 202 comprises a drawing plate 2021, a sliding rod 2022 and a driving belt 2023; the slide bar 2022 is mounted on the top of the frame 10; the drawing plate 2021 is slidably mounted on the slide bar 2022 through a linear bearing; the two sides of the drawing plate 2021 are fixedly connected with the driven rollers 2014; two ends of the transmission belt 2023 are installed below the sliding bar 2022 through synchronizing wheels and are connected with the bottom of the drawing plate 2021 through belt clamps; one end of the transmission belt 2023 is connected with a first servo motor 2024 for driving the transmission belt 2023 to operate, and the transmission belt 2023 is driven to operate by the first servo motor 2024, so that the drawing plate 2021 slides along the slide bar 2022, and the driven roller 2014 fixedly connected with the drawing plate 2021 correspondingly moves to realize the extension and retraction of the feeding and conveying belt 201; the stacking platform 30 comprises a stacking conveying belt 301, a transverse moving mechanism 302 and a lifting mechanism 303; the lifting mechanism 303 comprises a bottom plate 3031, a lifting plate 3032 arranged above the bottom plate 3031 in a lifting way, and a second servo motor 3033 fixedly arranged on the bottom plate 3031; an output shaft of the second servo motor 3033 is provided with a swing arm 3034; the top end of the swing arm 3034 is connected with the bottom end of the lifting plate 3032, and the swing arm 3034 is driven to lift through a second servo motor 3033, so that the lifting plate 3032 is driven to lift, and the height position of the stacking conveying belt 301 is adjusted; the traversing mechanism 302 comprises a base 3021, a mounting plate 3022 slidably mounted above the base 3021, and a cylinder 3023 fixedly mounted on the base 3021; the tail end of a piston rod of the air cylinder 3023 is connected with the mounting plate 3022 through a connecting plate, and the mounting plate 3022 is driven to slide left and right through the air cylinder 3023, so that the stacking conveyor belt 301 can swing left and right properly during material receiving; the two sides of the stacking conveying belt 301 are mounted on the mounting plate 3022 through vertical plates; one side of the stacking conveying belt 301 is connected with a second driving motor 3011 for driving the stacking conveying belt to operate.

In this embodiment, preferably, the height of the feeding conveyor belt 201 is always higher than the height of the stacking conveyor belt 301.

In this embodiment, preferably, a slag receiving pan 50 is disposed at one end of the frame 10 close to the stacking platform 30; the slag receiving disc 50 is arranged below the discharge end of the stacking conveyor belt 301; a slag scraping plate 3012 is arranged below the discharge end of the stacking conveyor belt 301, and a proper gap exists between the top end of the slag scraping plate 3012 and the bottom end of the stacking conveyor belt 301 for scraping off the river powder slag materials remained on the stacking conveyor belt 301; the slag scraping plate 3012 is located above the slag receiving disc 50, and residual river powder slag on the stacking conveyor belt 301 is blocked by the slag scraping plate 3012 and falls onto the slag receiving disc 50, so that the slag is prevented from being accumulated on the stacking conveyor belt 301.

In this embodiment, preferably, the pulling plate 2021 is disposed on the inner side of the feeding conveyor belt 201 in a crossing manner, the feeding conveyor belt 201 is driven to stretch by the driven rollers 2014, and the driving belt 2023 is driven to run by the first servo motor 2024, so that the pulling plate 2021 slides along the sliding rod 2022, and the driven rollers 2014 fixedly connected to the pulling plate 2021 correspondingly move to stretch the feeding conveyor belt 201.

The utility model discloses during the use: according to the number of layers and the height of stacked materials, the height of the stacked material conveying belt 301 is properly adjusted through the lifting mechanism 303; butt-jointing the feeding end of a feeding belt 201 of the telescopic feeding platform 20 with the discharging end of a river powder cutting machine at the front end to receive river powder materials, wherein the feeding belt 201 is in an extension state, when the approach switch 40 detects that the river powder materials are conveyed to the upper part of a stacking belt 301 of the stacking platform 30, a first servo motor 2024 of a drawing mechanism 202 drives a transmission belt 2023 to operate to drive a drawing plate 2021 to slide along a slide bar 2022, so that the feeding belt 201 retracts towards the feeding end direction, the river powder materials fall onto the stacking conveying belt 301 due to the action of gravity, and the stacking conveying belt 301 properly swings left and right through a transverse moving mechanism 302 during material receiving, so that the falling river powder is prevented from being excessively concentrated in the middle for stacking; after the river powder of the previous feeding belt 201 falls onto the stacking conveyor belt 301, the feeding belt 201 is driven by the drawing plate 2021 of the drawing mechanism 202 to extend towards the discharging end, and the above actions are repeated to start conveying the next river powder material until the river powder material is stacked on the stacking conveyor belt 301 to the set number of layers, and then conveyed to the feeding end of the rear-end packaging equipment by the stacking conveyor belt 301.

The technical solutions provided by the present application are introduced in detail above, and the principles and embodiments of the present application are explained in this document by applying embodiments, and the descriptions of the above embodiments are only used to help understand the method and its core ideas of the present application; meanwhile, for a person skilled in the art, according to the idea of the present application, there may be variations in the specific embodiments and the application scope, and in summary, the content of the present specification should not be construed as a limitation to the present application.

Claims (4)

1. The utility model provides a rice noodle production is with automatic material mechanism that folds which characterized in that: the device comprises a rack, a telescopic feeding platform and a stacking platform, wherein the telescopic feeding platform and the stacking platform are arranged on the rack; a proximity switch is arranged at one end of the rack close to the material stacking platform; the telescopic feeding platform comprises a feeding conveyer belt, a first driving motor for driving the feeding conveyer belt to run and a drawing mechanism for driving the feeding conveyer belt to stretch; the feeding conveyer belt comprises a main transmission shaft in transmission connection with the first driving motor, a tensioning roller for adjusting the tightness of the feeding conveyer belt and a driven roller for driving the feeding conveyer belt to stretch; the drawing mechanism comprises a drawing plate, a sliding rod and a transmission belt; the sliding rod is arranged at the top of the rack; the drawing plate is slidably arranged on the sliding rod through a linear bearing; two sides of the drawing plate are fixedly connected with the driven roller; two ends of the transmission belt are arranged below the sliding rod through synchronous wheels and are connected with the bottom of the pull plate through belt clamps; one end of the transmission belt is connected with a first servo motor for driving the transmission belt to run; the stacking platform comprises a stacking conveying belt, a transverse moving mechanism and a lifting mechanism; the lifting mechanism comprises a bottom plate, a lifting plate arranged above the bottom plate in a lifting way and a second servo motor fixedly arranged on the bottom plate; an output shaft of the second servo motor is provided with a swing arm; the top end of the swing arm is connected with the bottom end of the lifting plate; the transverse moving mechanism comprises a base, an installation plate which is slidably installed above the base and a cylinder which is fixedly installed on the base; the tail end of a piston rod of the air cylinder is connected with the mounting plate through a connecting plate; two sides of the stacked material conveying belt are arranged on the mounting plate through vertical plates; one side of the stacking conveying belt is connected with a second driving motor for driving the stacking conveying belt to operate.

2. The automatic material stacking mechanism for rice noodle production according to claim 1, wherein: the height of the feeding conveyer belt is always higher than that of the stacking conveyer belt.

3. The automatic material stacking mechanism for rice noodle production according to claim 1, wherein: a slag receiving disc is arranged at one end of the frame close to the stacking platform; the slag receiving disc is arranged below the discharge end of the stacking conveying belt; a slag scraping plate is arranged below the discharge end of the stacking conveyor belt; the slag scraping plate is positioned above the slag receiving disc.

4. The automatic material stacking mechanism for rice noodle production according to claim 1, wherein: the drawing plate is arranged on the inner side of the feeding conveyer belt in a crossing mode and drives the feeding conveyer belt to stretch and retract through the driven roller.

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