CN117941546B - A cutting and kneading machine for TMR complete mixed ration production - Google Patents

Abstract

The invention discloses a cutting and kneading integrated machine for producing a TMR complete mixed diet, and relates to the technical field related to cutting and kneading machinery, comprising an integrated frame, a feeding transmission mechanism, a pressure roller assembly, a cutting drum, a kneading drum and an integrated operating mechanism, wherein the pressure roller assembly and the kneading drum are both installed inside the integrated frame and located on the side of the feeding transmission mechanism, a pressure roller assembly is arranged on the top of the feeding transmission mechanism, the cutting drum is located above the kneading drum, and the two are connected through a feeding pipe, the feeding transmission mechanism transmits and moves the raw materials, and the integrated operating mechanism is driven by a motor, and the motor is installed inside the integrated frame; in the present invention, the cutting and kneading operations of the coarse grain raw materials can be carried out simultaneously, and while reducing the cost of mechanical equipment, the vibration force during the operation of the machinery can be reduced, the noise of the mechanical equipment can be reduced, and the stability of the mechanical equipment during operation can be improved.

Description

A cutting and kneading machine for TMR complete mixed ration production

Technical Field

The invention relates to the technical field related to cutting and kneading machinery, and in particular to a cutting and kneading integrated machine for producing TMR complete mixed rations.

Background technique

TMR total mixed ration production is a production technology that fully mixes roughage, concentrate, minerals, vitamins and other additives to provide sufficient nutrition to meet the needs of dairy cows. The roughage part is generally straw, etc. When processing the above coarse grains, it needs to go through production steps such as cutting and kneading, for which corresponding production and processing machinery is required.

The existing Chinese patent application with publication number CN116349509A discloses a straw cutting and shredding machine, comprising: a frame; a picking and conveying platform, the upper end of which is hinged to one side of the frame; a picking roller, installed at the bottom end of the picking and conveying platform and connected to a shredding motor, which is installed on the frame; a feeding conveying platform, which is installed at the front end of the frame corresponding to the picking and conveying platform; a feeding conveying roller, which is arranged corresponding to the intersection of the picking and conveying platform and the feeding conveying platform, and is connected to the cutting motor, which is installed on the frame; the cutting roller, which is arranged behind the feeding conveying platform and is connected to the cutting motor; the shredding roller, which is arranged behind the cutting roller and is connected to the shredding motor; a discharging conveying roller, which is installed on the frame and arranged below the shredding roller; and a discharging port, which is arranged correspondingly behind the discharging conveying roller; the invention can realize the picking up of straws stacked at different heights, and after secondary combing, the straws are transported to the cutting roller and the shredding roller to complete the cutting and shredding operations, thereby effectively reducing the workload.

However, the cutting and kneading machine has the following defects when used specifically:

When processing coarse grains (such as straw), the existing cutting and shredding machines generally need to go through cutting and shredding operations to facilitate subsequent reprocessing. However, in the actual production and processing, the cutting motor and shredding motor need to be used separately to complete the corresponding cutting and shredding operations, resulting in a high overall cost of the machine. At the same time, the vibration force generated by different motors during transportation will further increase the noise and stability of the machine operation, affecting the normal processing of the raw materials;

When existing cutting and shredding machines process coarse grains (straw, etc.), in order to facilitate the cutting and shredding operations, a feeding structure is generally provided to improve the processing efficiency. However, when the general feeding structure is transporting the coarse grains for feeding and moving, part of the coarse grains (such as leaves, etc.) will fall into the inside of the machine due to its small volume. At this time, when the above-mentioned fallen parts accumulate to a certain extent, it will affect the normal operation of the machine, and will also cause this part of the coarse grains to be wasted, further increasing the cost of raw materials.

Summary of the invention

The object of the present invention is to provide a cutting and kneading machine for producing TMR complete mixed ration to solve the problems raised in the above-mentioned background technology.

In order to achieve the above-mentioned invention object, the present invention adopts the following technical scheme:

The present invention provides a cutting and kneading integrated machine for TMR complete mixed diet production, comprising an integrated frame, a feeding transmission mechanism, a pressure roller assembly, a cutting drum, a kneading drum and an integrated operating mechanism, wherein the pressure roller assembly and the kneading drum are both installed inside the integrated frame and located on the side of the feeding transmission mechanism, a pressure roller assembly is provided on the top of the feeding transmission mechanism, the cutting drum is located above the kneading drum, and the two are connected through a feeding pipe, the feeding transmission mechanism transmits and moves the raw materials, the integrated operating mechanism is driven by a motor, and the motor is installed inside the integrated frame, and the integrated frame also includes:

A belt transmission assembly, the belt transmission assembly is connected to the output end of the motor and synchronously drives the feeding transmission mechanism and the pressure roller assembly to operate, and the belt transmission assembly is located on one side of the integrated frame;

A circulating cutting assembly, which is arranged inside the cutting drum and connected to the belt transmission assembly, and which cuts the raw materials moved into the cutting drum;

The gear kneading assembly is arranged inside the kneading drum and connected to the belt transmission assembly. The gear kneading assembly kneads the raw materials moved into the kneading drum.

As a preferred embodiment of the present invention, the feeding transmission mechanism is composed of an oblique feeding component, a storage frame, a transmission belt and a feeding conveyor belt. The oblique feeding component is installed on one side of the integrated frame and is arranged obliquely. A storage frame is provided at the bottom of the central part of the oblique feeding component. The side of the port part of the oblique feeding component is connected to the feeding conveyor belt through a transmission belt. The feeding conveyor belt is installed on the top of the integrated frame and is located on one side of the cutting drum feed port. A pressure roller assembly is provided on the top of the feeding conveyor belt.

As a preferred embodiment of the present invention, the oblique feeding assembly includes an external frame, which is installed on the top of the integrated frame through an external mounting seat and is arranged obliquely, and the internal part of the external frame is movably connected with a first rotating shaft that passes through the mounting seat; a first belt, which is connected to the outer side of the first rotating shaft through a pulley and is located on the outer side of the mounting seat, and the inner side of the first belt is also connected to a first feeding roller through a pulley, and the first feeding roller is movably connected to the inside of the external frame; a first transmission gear, which is installed on the outer side of the first feeding roller and is rotatably connected to the outside of the external frame, and the side of the first transmission gear is meshed and connected with a second transmission gear, and the internal part of the second transmission gear is rotatably connected with a second feeding roller, and the second feeding roller is rotatably connected to the inside of the external frame; a second belt, which is respectively connected to the outer sides of the second feeding roller and the first feeding roller through pulleys, and is located on the sides of the first transmission gear and the second transmission gear.

As a preferred solution of the present invention, the first feeding roller, the first transmission gear, the second transmission gear, the second feeding roller and the second belt are all provided in plurality, and the outer side of the first rotating shaft is also connected to the feeding transmission belt through the transmission belt;

Wherein, the first rotating shaft is connected to the belt transmission assembly.

As a preferred embodiment of the present invention, the pressure roller assembly includes a pressure roller support seat, which is installed on the side of the integrated frame by screws, and two groups are provided. The inner side of the pressure roller support seat is movably connected with a pressure roller shaft, and the outside of the pressure roller shaft is installed with a pressure roller cylinder; wherein the pressure roller shaft is connected to a belt drive assembly.

As a preferred embodiment of the present invention, the belt transmission assembly comprises:

A first transmission belt, the first transmission belt is connected to the output end of the motor through a pulley, the outer side of the first transmission belt is also connected to a first connecting shaft through a pulley, and the first connecting shaft is rotatably connected to the outer side of the pressure roller support seat;

Wherein, a pressure roller shaft is installed at the bottom of the first connecting shaft;

A second transmission belt, wherein the second transmission belt is connected to the outer side of the pressure roller shaft through a pulley, and the inner side of the second transmission belt is also connected to the first rotating shaft through a pulley, and the first rotating shaft is arranged away from the pressure roller shaft;

A third transmission belt, the third transmission belt is connected to the outer side of the pressure roller shaft through a pulley and is located on the side of the second transmission belt, and the inner side of the third transmission belt is also connected to the second connecting shaft through a pulley;

Wherein, the second connecting shaft is installed on the outside of the connecting seat, and the connecting seat is installed on the top of the integrated frame by screws;

The fourth transmission belt is connected to the outer side of the second connecting shaft through a pulley, and the inner side of the fourth transmission belt is also connected to the third connecting shaft through a pulley, and the third connecting shaft is installed at the center of the side of the silk kneading drum.

As a preferred solution of the present invention, a circulating cutting assembly is installed at the bottom of the second connecting shaft, and a gear kneading assembly is connected to the bottom of the third connecting shaft.

As a preferred embodiment of the present invention, the cyclic cutting assembly comprises:

A connecting plate, the connecting plate is rotatably connected to the outer side of the cutting drum, a cutting tool is installed at the center of the side of the connecting plate, and the cutting tool is movably connected to the inner side of the cutting drum;

An annular groove, the annular groove is opened on one side of the cutting drum and is located on the side of the connecting disk, the interior of the annular groove is movably connected with a wedge-shaped push plate, the wedge-shaped push plate is installed on the side of the connecting disk and is located at the eccentric position of the connecting disk;

The guide part is installed inside the cutting drum and is arranged far away from the annular groove. A wedge-shaped push plate is movably connected inside the guide part.

As a preferred solution of the present invention, the annular groove and the guide portion are both located outside the cutting tool blade portion, and the wedge-shaped push plate is located outside the cutting tool blade portion and pushes the raw material inside the cutting drum to move.

As a preferred embodiment of the present invention, the gear kneading assembly comprises:

A third belt, the third belt is connected to the outer side of the third connecting shaft through a pulley, the inner side of the third belt is also connected to a silk kneading shaft through a pulley, the silk kneading shaft is arranged away from the third connecting shaft, and is rotatably connected to the inside of the silk kneading drum;

Wherein, the kneading shafts are provided in two groups and are symmetrically arranged relative to the third connecting shaft;

A rotating gear, which is installed on the outer side of the kneading shaft and is rotatably connected to the inner wall of the kneading cylinder. Two groups of rotating gears are provided, and the two groups of rotating gears are meshed and connected;

The kneading rollers are installed on the outside of the kneading shaft and are provided in two groups.

Compared with the prior art, one or more of the above technical solutions have the following beneficial effects:

1. The cutting and kneading integrated machine for producing TMR fully mixed rations can drive the first transmission belt, the first connecting shaft, the third transmission belt and the second connecting shaft at the output end to rotate through a group of motors when producing and processing the coarse grain raw materials for synthesizing TMR fully mixed rations, thereby driving the connecting plate and the cutting tool connected to the second connecting shaft to rotate, thereby realizing the automatic cutting operation of the coarse grain raw materials. At the same time, when the second connecting shaft rotates, it will drive the fourth transmission belt, the third connecting shaft, the third belt, the kneading shaft, the rotating gear and the kneading roller connected to the outer side through the pulley to operate, thereby automatically realizing the kneading operation of the coarse grain raw materials after cutting, which is convenient for subsequent reprocessing. At this time, the cutting and kneading operations of the coarse grain raw materials are carried out simultaneously, which can reduce the vibration force during the operation of the machinery and equipment while reducing the cost of the machinery and equipment, reduce the noise of the machinery and equipment, and improve the stability of the machinery and equipment during operation;

2. The cutting and kneading integrated machine for TMR full mixed diet production, when the motor drives the first transmission belt and the first connecting shaft at its output end to rotate, can synchronously drive the pressure roller shaft and the pressure roller barrel connected to the first connecting shaft to rotate, and perform a pressure roller operation on the coarse grain raw materials transmitted on the top of the feeding conveyor belt, so as to ensure that the coarse grain raw materials are located below the pressure roller barrel, and reduce the probability of the coarse grain raw materials being stuck outside the cutting drum, and when the first connecting shaft is rotating, it can drive the second transmission belt, the first rotating shaft, the first belt, the first feeding roller, the first transmission gear, the second transmission gear, the second feeding roller and the second belt connected to the outside through the pulley to automatically transmit and feed the coarse grain raw materials on the top of the external frame, wherein the feeding of the above raw materials and the cutting and kneading of the raw materials can be carried out synchronously, so as to realize the integrated feeding, cutting and kneading of the raw materials, and improve the efficiency of the production and processing of the raw materials;

3. In the TMR fully mixed diet production cutting and kneading integrated machine, when the first rotating shaft drives the first belt, the first feeding roller, the first transmission gear, the second transmission gear, the second feeding roller and the second belt connected at its output end through the pulley to operate, two sets of adjacent first feeding rollers and second feeding rollers are connected through the second belt to ensure that the rotation of the first feeding roller and the second feeding roller can be synchronized and carried out in the same direction, and the two sets of first feeding rollers located on both sides of the second feeding roller can be driven by the meshing of the two sets of first transmission gears and the one set of second transmission gears to ensure that the rotation of the two sets of first feeding rollers is transmitted. The first rotating shaft can be operated synchronously and in the same direction. At this time, the uniform feeding operation of the raw materials can be realized through the above operation. Moreover, when the first rotating shaft is rotating, the transmission belt and the feeding conveyor belt connected by the pulley on the outside thereof will be driven to operate, and the subsequent automatic feeding operation of the transmitted raw materials will be performed more intelligently. Among them, when the first feeding roller and the second feeding roller feed the raw materials, the storage frame arranged at the bottom can be used to automatically complete the collection operation of the dropped raw materials, thereby reducing the cost of coarse grains and avoiding the problem of raw materials accumulating inside the mechanical equipment, thereby ensuring the normal processing of the raw materials.

4. The cutting and kneading machine for TMR fully mixed ration production, when the connecting disc and the cutting tool are rotating, will synchronously drive the wedge-shaped pusher plate installed at the eccentric part of the side of the connecting disc to rotate, and the coarse grain raw materials cut inside the cutting drum are fed in a circular manner to ensure that the size of the coarse grain raw materials after cutting can enter the kneading drum through the discharge pipe, meet the subsequent raw material kneading operation, and ensure the quality of the raw materials after processing.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings in the specification, which constitute a part of the present invention, are used to provide a further understanding of the present invention. The exemplary embodiments of the present invention and their descriptions are used to explain the present invention and do not constitute improper limitations on the present invention.

In addition, the terms "installed", "set", "provided with", "connected", "connected", and "socketed" should be understood in a broad sense. For example, it can be a fixed connection, a detachable connection, or an integral structure; it can be a mechanical connection, or an electrical connection; it can be a direct connection, or an indirect connection through an intermediate medium, or it can be an internal connection between two devices, elements, or components. For those of ordinary skill in the art, the specific meanings of the above terms in this application can be understood according to specific circumstances.

FIG1 is a schematic diagram of the overall structure of the present invention;

FIG2 is a schematic diagram of the overall structure of the present invention from a side view;

FIG3 is a schematic diagram of the structure of point A in FIG2 of the present invention;

FIG4 is a schematic structural diagram of the present invention as a whole viewed from the front;

FIG5 is a schematic diagram of the overall structure of the present invention from a top view;

6 is a schematic structural diagram of the feeding transmission mechanism of the present invention;

7 is a schematic structural diagram of the oblique feeding assembly of the present invention;

8 is a schematic structural diagram of the connection between the first rotating shaft and the second belt of the present invention;

9 is a schematic structural diagram of the connection between the integrated operating mechanism and the pressure roller assembly of the present invention;

10 is a schematic structural diagram of the connection between the motor and the pressure roller of the present invention;

11 is a schematic structural diagram of a cross-sectional view of the connection between the feeding conveyor belt and the cutting drum of the present invention;

12 is a schematic structural diagram of the connection between the cyclic cutting assembly and the gear kneading assembly of the present invention;

13 is a schematic structural diagram of the third connecting shaft and gear kneading assembly of the present invention;

In the figure:

10. Integrated rack;

20. feeding transmission mechanism; 201. oblique feeding assembly; 2011. peripheral frame; 2012. mounting seat; 2013. first rotating shaft; 2014. first belt; 2015. first feeding roller; 2016. first transmission gear; 2017. second transmission gear; 2018. second feeding roller; 2019. second belt;

202, storage frame; 203, transmission belt; 204, feeding transmission belt;

30. Pressing roller assembly; 301. Pressing roller support seat; 302. Pressing roller shaft; 303. Pressing roller cylinder;

40. Cutting drum;

50. Silk kneading roller;

60. Feeding pipe;

70, belt drive assembly; 701, first drive belt; 702, first connecting shaft; 703, second drive belt; 704, third drive belt; 705, second connecting shaft; 706, fourth drive belt; 706i, connecting seat; 707, third connecting shaft;

80. Circular cutting assembly; 801. Connecting plate; 802. Cutting tool; 803. Annular groove; 804. Wedge-shaped push plate; 805. Guide portion;

90, gear kneading assembly; 901, third belt; 902, kneading shaft; 903, rotating gear; 904, kneading roller;

100, integrated operating mechanism; 100i, motor.

Detailed ways

In order to enable those skilled in the art to better understand the present application, the technical solutions in the embodiments of the present application will be clearly and completely described below in conjunction with the drawings in the embodiments of the present application. Obviously, the described embodiments are only part of the embodiments of the present application, not all of the embodiments. Based on the embodiments in the present application, all other embodiments obtained by ordinary technicians in this field without creative work should fall within the scope of protection of this application.

Please refer to Figures 1 to 13, a cutting and kneading integrated machine for TMR complete mixed diet production includes an integrated frame 10, a feeding transmission mechanism 20, a pressure roller assembly 30, a cutting drum 40, a kneading drum 50 and an integrated operating mechanism 100, the pressure roller assembly 30 and the kneading drum 50 are both installed inside the integrated frame 10 and are located on the side of the feeding transmission mechanism 20, the pressure roller assembly 30 is arranged on the top of the feeding transmission mechanism 20, the cutting drum 40 is located above the kneading drum 50, and the two are connected through a feeding pipe 60, the feeding transmission mechanism 20 transmits and moves the raw materials, and the integrated operating mechanism 100 is driven by a motor 100i, which is installed on the integrated frame. 10, the integrated frame 10 also includes a belt drive assembly 70, the belt drive assembly 70 is connected to the output end of the motor 100i, and synchronously drives the feeding transmission mechanism 20 and the pressure roller assembly 30 to operate, and the belt drive assembly 70 is located on one side of the integrated frame 10; a circulating cutting assembly 80, the circulating cutting assembly 80 is arranged inside the cutting drum 40, and is connected to the belt drive assembly 70, and the circulating cutting assembly 80 cuts the raw materials moved to the inside of the cutting drum 40; a gear kneading assembly 90, the gear kneading assembly 90 is arranged inside the kneading drum 50, and is connected to the belt drive assembly 70, and the gear kneading assembly 90 kneads the raw materials moved to the inside of the kneading drum 50.

The above working principle: when the coarse grain part of the TMR total mixed diet is produced and processed, the corresponding coarse grain raw materials are first placed on the top of the feeding transmission mechanism 20. At this time, the feeding transmission mechanism 20 can complete the automatic feeding operation of the raw materials and automatically move them to the inside of the cutting drum 40. At the same time, while the raw materials are being fed, the operation of the belt transmission component 70 will synchronously drive the circulation cutting component 80 to operate, automatically circulate and cut the raw materials entering the inside of the cutting drum 40, and complete the cutting operation of the raw materials. The cut raw materials will fall into the inside of the kneading drum 50 through the discharge pipe 60, and the gear kneading component 90 will be started by the belt transmission component 70 to operate, and the raw materials on the inside of the gear kneading component 90 will be kneaded. Among them, the above-mentioned feeding transmission mechanism 20, the gear kneading component 90 and the circulation cutting component 80 can complete the integrated feeding, cutting and kneading operations through the operation of a group of motors 100i. The mechanical cost is low, and the noise generated during operation is small, ensuring the normal production and processing of coarse grains.

6, 7 and 8, the loading transmission mechanism 20 is composed of an oblique feeding component 201, a storage frame 202, a transmission belt 203 and a loading transmission belt 204. The oblique feeding component 201 is installed on one side of the integrated frame 10 and is arranged obliquely. The storage frame 202 is provided at the bottom of the central part of the oblique feeding component 201, and the side of the port part of the oblique feeding component 201 is connected to the loading transmission belt 204 through the transmission belt 203. The loading transmission belt 204 is installed on the top of the integrated frame 10 and is located on one side of the feed port of the cutting drum 40.

In this embodiment, a pressure roller assembly 30 is disposed on the top of the feeding conveyor belt 204, and the pressure roller assembly 30 can be used to complete the pressing process of the conveyed raw materials, so that the coarse grains are more evenly conveyed.

In the cutting and kneading machine for producing TMR complete mixed ration of the present invention, the oblique feeding component 201 can move the coarse grains for feeding and move them to the top of the feeding conveyor belt 204. Thereafter, the coarse grain raw materials are moved to the inside of the cutting drum 40 through the transmission movement of the feeding conveyor belt 204. When the oblique feeding component 201 feeds the raw materials, smaller raw materials will fall into the inside of the storage frame 202 for collection, which is convenient for subsequent reuse and can reduce the probability of raw materials accumulating inside the machine.

In the above solution, the feeding conveyor belt 204 is driven by the inner gear and toothed conveyor belt, and the power for driving the gear and toothed conveyor belt to operate is provided by the torque force transmitted by the transmission belt 203 .

6, 7 and 8, the oblique feeding assembly 201 includes an external frame 2011, which is mounted on the top of the integrated frame 10 through an external mounting seat 2012 and is arranged obliquely, and the internal part of the external frame 2011 is movably connected with a first rotating shaft 2013 that passes through the mounting seat 2012; a first belt 2014, which is connected to the outside of the first rotating shaft 2013 through a pulley and is located on the outside of the mounting seat 2012, and the inner side of the first belt 2014 is also connected to a first feeding roller 2015 through a pulley, and the first feeding roller 2015 is movably connected to the inside of the external frame 2011; A transmission gear 2016, the first transmission gear 2016 is installed on the outside of the first feeding roller 2015 and is rotatably connected to the outside of the external frame 2011, the side of the first transmission gear 2016 is meshedly connected with the second transmission gear 2017, the inside of the second transmission gear 2017 is rotatably connected with the second feeding roller 2018, and the second feeding roller 2018 is rotatably connected to the inside of the external frame 2011; a second belt 2019, the second belt 2019 is respectively connected to the outside of the second feeding roller 2018 and the first feeding roller 2015 through pulleys, and is located on the sides of the first transmission gear 2016 and the second transmission gear 2017.

In the present embodiment, a plurality of first feed rollers 2015, first transmission gears 2016, second transmission gears 2017, second feed rollers 2018 and second belts 2019 are provided, and the transmission and feeding of the coarse grain raw materials can be completed by designing a plurality of groups of first feed rollers 2015 and second feed rollers 2018. The design of the first transmission gear 2016, second transmission gear 2017 and second belt 2019 can ensure that a plurality of groups of first feed rollers 2015 and second feed rollers 2018 can rotate synchronously and in the same direction, thereby completing the automated feeding operation of the raw materials.

At the same time, in this embodiment, the outer side of the first rotating shaft 2013 is also connected to the loading conveyor belt 204 through the transmission belt 203. Through the design of the transmission belt 203, the operation of the first feeding roller 2015, the second feeding roller 2018 and the loading conveyor belt 204 can be carried out synchronously, thereby automatically transmitting the raw materials to the interior of the cutting drum 40.

In addition, in this embodiment, the first rotating shaft 2013 is connected to the belt transmission assembly 70 , and the first rotating shaft 2013 can be driven to rotate through the operation of the belt transmission assembly 70 .

In the integrated cutting and kneading machine for producing TMR complete mixed diet of the present invention, when the belt transmission assembly 70 is in operation, it drives the first rotating shaft 2013 connected to the inside through the pulley to rotate, and then drives the first belt 2014 connected to the bottom of the first rotating shaft 2013 through the pulley to transmit, and the transmission of the first belt 2014 drives the first feeding roller 2015 connected to the inside through the pulley to rotate, and then drives the first transmission gear 2016 installed on the side of the first feeding roller 2015 to rotate. At this time, the rotation of the first transmission gear 2016 The rotation of the second transmission gear 2017 on its side will drive the rotation of the other group of first transmission gears 2016 meshed with the other side of the second transmission gear 2017, thereby ensuring that several groups of first feeding rollers 2015 can rotate synchronously in the same direction. Among them, the second feeding roller 2018 arranged between the two groups of first feeding rollers 2015 can be designed with a second belt 2019 so that the rotation of the first feeding roller 2015 can drive several groups of second feeding rollers 2018 to rotate synchronously in the same direction, thereby realizing the automated feeding operation of coarse grain raw materials.

10 , the pressure roller assembly 30 includes a pressure roller support seat 301 , which is mounted on the side of the integrated frame 10 by screws, and is provided with two groups. The inner side of the pressure roller support seat 301 is movably connected with a pressure roller shaft 302 , and the outer side of the pressure roller shaft 302 is installed with a pressure roller cylinder 303 .

In this embodiment, the pressure roller shaft 302 is connected to the belt transmission assembly 70 , and the pressure roller shaft 302 can be driven to rotate through the operation of the belt transmission assembly 70 .

The cutting and kneading machine for producing TMR complete mixed diet of the present invention, when the belt drive assembly 70 is in operation, will drive the pressure roller shaft 302 connected to its bottom to rotate, and then drive the pressure roller cylinder 303 installed on the side of the pressure roller shaft 302 to rotate, and perform a pressure roller operation on the raw materials transported on the top of the feeding conveyor belt 204, so that the transported material is located below the pressure roller cylinder 303, so that the raw materials can automatically enter the interior of the cutting drum 40.

9, the belt drive assembly 70 includes a first transmission belt 701, the first transmission belt 701 is connected to the output end of the motor 100i through a pulley, the outer side of the first transmission belt 701 is also connected to the first connecting shaft 702 through a pulley, and the rotation of the first connecting shaft 702 is connected to the outer side of the pressure roller support seat 301; a second transmission belt 703, the second transmission belt 703 is connected to the outer side of the pressure roller shaft 302 through a pulley, and the inner side of the second transmission belt 703 is also connected to the first rotating shaft 2013 through a pulley, and the first rotating shaft 201 3 is arranged away from the pressure roller shaft 302; a third transmission belt 704, which is connected to the outer side of the pressure roller shaft 302 through a pulley and is located on the side of the second transmission belt 703, and the inner side of the third transmission belt 704 is also connected to the second connecting shaft 705 through a pulley; a fourth transmission belt 706, which is connected to the outer side of the second connecting shaft 705 through a pulley, and the inner side of the fourth transmission belt 706 is also connected to the third connecting shaft 707 through a pulley, and the third connecting shaft 707 is installed at the center of the side of the silk kneading drum 50.

In this embodiment, a pressure roller shaft 302 is installed at the bottom of the first connecting shaft 702 , and the pressure roller shaft 302 can be driven to rotate by the rotation of the first connecting shaft 702 .

Meanwhile, in the present embodiment, the second connecting shaft 705 is installed on the outside of the connecting seat 706i, and the connecting seat 706i is installed on the top of the integrated frame 10 by screws. The design of the connecting seat 706i can ensure the stability of the second connecting shaft 705 during rotation.

Moreover, in this embodiment, a circulating cutting assembly 80 is installed at the bottom of the second connecting shaft 705, and a gear kneading assembly 90 is connected to the bottom of the third connecting shaft 707. The circulating cutting assembly 80 can be driven to operate synchronously by the rotation of the second connecting shaft 705, and the gear kneading assembly 90 can be driven to operate synchronously by the rotation of the third connecting shaft 707.

The cutting and kneading integrated machine for producing TMR complete mixed ration of the present invention can drive the first transmission belt 701 connected to its output end through the pulley to rotate through the operation of the motor 100i when realizing the feeding, cutting and kneading operations of coarse grains, thereby driving the first connecting shaft 702 connected to the inner side of the first transmission belt 701 through the pulley to rotate. At this time, the rotation of the first connecting shaft 702 will drive the pressure roller shaft 302 installed at the bottom to operate, thereby realizing the rotation of the pressure roller 303. When the first connecting shaft 702 rotates, it will drive the second transmission belt 703 connected to its outer side through the pulley to rotate, thereby driving the first rotating shaft 2013 connected to the inner side of the second transmission belt 703 through the pulley to rotate. , driving the feeding transmission mechanism 20 to operate, realizing the automatic feeding operation of raw materials, and when the first connecting shaft 702 rotates, it will drive the third transmission belt 704 connected to its outer side through the pulley to transmit, and then drive the second connecting shaft 705 connected to the inner side of the third transmission belt 704 through the pulley to rotate, so that the circulating cutting assembly 80 installed at the bottom of the second connecting shaft 705 operates, wherein, when the second connecting shaft 705 rotates, it will drive the fourth transmission belt 706 connected to its outer side through the pulley to operate, and then drive the third connecting shaft 707 connected to the inner side of the fourth transmission belt 706 through the pulley to rotate, so that the gear kneading assembly 90 installed at the bottom of the third connecting shaft 707 operates.

With specific reference to Figures 9, 11 and 12, the circulating cutting assembly 80 includes a connecting disk 801, which is rotatably connected to the outer side of the cutting drum 40, and a cutting tool 802 is installed at the center of the side of the connecting disk 801, and the cutting tool 802 is movably connected to the inner side of the cutting drum 40; an annular groove 803, which is opened on one side of the cutting drum 40 and is located on the side of the connecting disk 801, and a wedge-shaped push plate 804 is movably connected inside the annular groove 803, and the wedge-shaped push plate 804 is installed on the side of the connecting disk 801 and is located at the eccentric position of the connecting disk 801; a guide portion 805, which is installed inside the cutting drum 40 and is arranged away from the annular groove 803, and the wedge-shaped push plate 804 is movably connected inside the guide portion 805.

In this embodiment, the annular groove 803 and the guide portion 805 are both located on the outside of the blade portion of the cutting tool 802, and the wedge-shaped push plate 804 is located on the outside of the blade portion of the cutting tool 802, and pushes the raw material inside the cutting drum 40 to move. The positions of the wedge-shaped push plate 804, the annular groove 803 and the guide portion 805 can be designed so that the rotation of the cutting tool 802 will not affect the rotational movement of the wedge-shaped push plate 804, thereby ensuring that the two can proceed synchronously.

The cutting and kneading integrated machine for producing TMR complete mixed diet of the present invention, when the second connecting shaft 705 rotates, will drive the connecting disk 801 installed at its bottom to rotate, and then drive the cutting tool 802 installed at the center of the side of the connecting disk 801 to rotate. At this time, the coarse grain raw materials are automatically cut and processed by the rotation of the cutting tool 802, and the coarse grain raw materials after cutting, and the raw materials that meet the cutting quality standards will pass through the unloading pipe 60 and enter the interior of the kneading drum 50, which is convenient for subsequent kneading operations. When the connecting disk 801 rotates, it will drive the wedge-shaped pusher plate 804 installed at its eccentric part to rotate, and push the larger raw materials to move in a circular motion, thereby realizing the secondary cutting operation of the raw materials. The rotation of the wedge-shaped pusher plate 804 is carried out inside the annular groove 803 and the guide part 805, so as to ensure the stability of the wedge-shaped pusher plate 804 when it moves in a circular motion.

12 and 13, the gear kneading assembly 90 includes a third belt 901, which is connected to the outer side of the third connecting shaft 707 through a pulley, and the inner side of the third belt 901 is also connected to a kneading shaft 902 through a pulley, and the kneading shaft 902 is arranged away from the third connecting shaft 707 and is rotatably connected to the inside of the kneading drum 50; a rotating gear 903, which is installed on the outer side of the kneading shaft 902 and is rotatably connected to the inner wall of the kneading drum 50, and two groups of rotating gears 903 are provided, and the two groups of rotating gears 903 are meshed and connected; a kneading roller 904, which is installed on the outer side of the kneading shaft 902 and is provided with two groups.

In this embodiment, two groups of kneading shafts 902 are provided, and are symmetrically arranged relative to the third connecting shaft 707. The kneading rollers 904 can be rotated synchronously by rotating the kneading shafts 902 to knead the raw materials.

In the cutting and kneading integrated machine for producing TMR complete mixed diet of the present invention, when the third connecting shaft 707 is rotating, it will drive the third belt 901 connected to its outer side through a pulley for transmission, and then drive the kneading shaft 902 connected to the inner side of the third belt 901 through a pulley to rotate. At this time, the rotation of the kneading shaft 902 will drive the kneading roller 904 installed on its outer side to rotate, and the other group of kneading shafts 902 inside the kneading drum 50 can be connected by the meshing of two groups of rotating gears 903, so that the rotation directions of the two groups of kneading rollers 904 are opposite, thereby realizing the automated raw material kneading operation.

The above are only preferred specific implementation modes of the present invention, but the protection scope of the present invention is not limited thereto. Any technician familiar with the technical field can make equivalent replacements or changes according to the technical solutions and inventive concepts of the present invention within the technical scope disclosed by the present invention, which should be covered by the protection scope of the present invention.

Claims (3)

1. TMR mixes ration production with cutting and rub silk all-in-one entirely, its characterized in that: including integral type frame (10), material loading transport mechanism (20), compression roller subassembly (30), cutting cylinder (40), rub silk cylinder (50) and integration operation mechanism (100), compression roller subassembly (30) and rub the inside of silk cylinder (50) all install in integral type frame (10), and be located the side of material loading transport mechanism (20), the top of material loading transport mechanism (20) is provided with compression roller subassembly (30), cutting cylinder (40) are located the top of rubbing silk cylinder (50), and are linked together through unloading pipeline (60) between the two, material loading transport mechanism (20) are carried out the transmission and are removed to the raw materials, integration operation mechanism (100) are driven by motor (100 i), the inside at integral type frame (10) is installed to motor (100 i), integral type frame (10) still include:

The belt transmission assembly (70) is connected with the output end of the motor (100 i) and synchronously drives the feeding transmission mechanism (20) and the compression roller assembly (30) to operate, and the belt transmission assembly (70) is positioned on one side of the integrated frame (10);

A circulation cutting assembly (80), wherein the circulation cutting assembly (80) is arranged inside the cutting drum (40) and is connected with the belt transmission assembly (70), and the circulation cutting assembly (80) cuts raw materials moving into the cutting drum (40);

The gear wire kneading assembly (90), the gear wire kneading assembly (90) is arranged in the wire kneading roller (50) and is connected with the belt transmission assembly (70), and the gear wire kneading assembly (90) kneads raw materials moving into the wire kneading roller (50);

the feeding transmission mechanism (20) is composed of an oblique feeding assembly (201), a storage frame (202), a transmission belt (203) and a feeding transmission belt (204), wherein the oblique feeding assembly (201) is installed on one side of the integrated frame (10) and is obliquely arranged, the storage frame (202) is arranged at the bottom of the central part of the oblique feeding assembly (201), the side face of the port part of the oblique feeding assembly (201) is connected with the feeding transmission belt (204) through the transmission belt (203), the feeding transmission belt (204) is installed on the top of the integrated frame (10) and is located on one side of a feeding port of the cutting drum (40), and a compression roller assembly (30) is arranged on the top of the feeding transmission belt (204);

The oblique feeding assembly (201) comprises an outer frame (2011), the outer frame (2011) is installed at the top of the integrated rack (10) through an external installation seat (2012) and is obliquely arranged, and a first rotating shaft (2013) penetrating through the installation seat (2012) is movably connected inside the outer frame (2011); the first belt (2014) is connected to the outer side of the first rotating shaft (2013) through a belt pulley and is positioned on the outer side of the mounting seat (2012), a first feeding roller (2015) is connected to the inner side of the first belt (2014) through the belt pulley, and the first feeding roller (2015) is movably connected to the inner side of the peripheral frame (2011); the first transmission gear (2016) is arranged on the outer side of the first feeding roller (2015) and is rotationally connected to the outer part of the outer frame (2011), a second transmission gear (2017) is connected to the side face of the first transmission gear (2016) in a meshed mode, a second feeding roller (2018) is rotationally connected to the inner part of the second transmission gear (2017), and the second feeding roller (2018) is rotationally connected to the inner part of the outer frame (2011); a second belt (2019), wherein the second belt (2019) is respectively connected to the outer sides of the second feeding roller (2018) and the first feeding roller (2015) through pulleys and is positioned on the side surfaces of the first transmission gear (2016) and the second transmission gear (2017);

The press roller assembly (30) comprises a press roller supporting seat (301), the press roller supporting seat (301) is arranged on the side face of the integrated frame (10) through screws, two groups of press roller supporting seats are arranged, a press roller shaft (302) is movably connected to the inner side of the press roller supporting seat (301), and a press roller (303) is arranged outside the press roller shaft (302); wherein the press roll shaft (302) is connected with the belt transmission assembly (70);

The belt drive assembly (70) includes: the first transmission belt (701), the first transmission belt (701) is connected with the output end of the motor (100 i) through a belt pulley, the outer side of the first transmission belt (701) is also connected with a first connecting shaft (702) through the belt pulley, and the rotation of the first connecting shaft (702) is connected with the outer side of the compression roller supporting seat (301);

wherein, the bottom of the first connecting shaft (702) is provided with a roller shaft (302);

The second transmission belt (703), the second transmission belt (703) is connected to the outer side of the roller shaft (302) through a belt pulley, the inner side of the second transmission belt (703) is also connected with a first rotating shaft (2013) through a belt pulley, and the first rotating shaft (2013) is far away from the roller shaft (302);

the third transmission belt (704), the third transmission belt (704) is connected to the outer side of the roller shaft (302) through a belt pulley and is positioned on the side surface of the second transmission belt (703), and the inner side of the third transmission belt (704) is also connected with a second connecting shaft (705) through a belt pulley;

the second connecting shaft (705) is arranged on the outer side of the connecting seat (706 i), and the connecting seat (706 i) is arranged on the top of the integrated frame (10) through screws;

The fourth transmission belt (706), the fourth transmission belt (706) is connected to the outer side of the second connecting shaft (705) through a belt pulley, the inner side of the fourth transmission belt (706) is also connected with a third connecting shaft (707) through a belt pulley, and the third connecting shaft (707) is arranged at the center of the side face of the wire kneading roller (50);

the bottom of the second connecting shaft (705) is provided with a circular cutting assembly (80), and the bottom of the third connecting shaft (707) is connected with a gear wire kneading assembly (90);

the circular cutting assembly (80) comprises:

The connecting disc (801), the connecting disc (801) is rotatably connected to the outer side of the cutting drum (40), a cutting tool (802) is arranged at the center of the side face of the connecting disc (801), and the cutting tool (802) is movably connected to the inner side of the cutting drum (40);

The annular groove (803) is formed in one side of the cutting roller (40) and is positioned on the side face of the connecting disc (801), a wedge-shaped pushing plate (804) is movably connected inside the annular groove (803), and the wedge-shaped pushing plate (804) is mounted on the side face of the connecting disc (801) and is positioned at the eccentric position of the connecting disc (801);

the guide part (805), the guide part (805) is installed inside the cutting drum (40) and is far away from the annular groove (803), and a wedge-shaped pushing plate (804) is movably connected inside the guide part (805);

the gear wire kneading assembly (90) comprises:

The third belt (901) is connected to the outer side of the third connecting shaft (707) through a belt pulley, the inner side of the third belt (901) is also connected with a yarn kneading shaft (902) through a belt pulley, and the yarn kneading shaft (902) is far away from the third connecting shaft (707) and is rotatably connected to the inside of the yarn kneading roller (50);

wherein, the yarn kneading shafts (902) are provided with two groups and are symmetrically arranged relative to the third connecting shaft (707);

the rotary gears (903) are arranged on the outer sides of the yarn kneading shafts (902) and are rotatably connected to the inner wall of the yarn kneading roller (50), two groups of the rotary gears (903) are arranged, and the two groups of the rotary gears (903) are in meshed connection;

And the yarn kneading rollers (904) are arranged on the outer sides of the yarn kneading shafts (902), and two groups of yarn kneading rollers are arranged.

2. The cutting and kneading integrated machine for producing TMR total mixed ration according to claim 1, wherein: the first feeding roller (2015), the first transmission gear (2016), the second transmission gear (2017), the second feeding roller (2018) and the second belt (2019) are all provided with a plurality of rollers, and the outer side of the first rotating shaft (2013) is connected with the feeding transmission belt (204) through the transmission belt (203);

wherein the first rotating shaft (2013) is connected with the belt transmission assembly (70).

3. The cutting and kneading integrated machine for producing TMR total mixed ration according to claim 2, characterized in that: the annular groove (803) and the guide part (805) are both positioned on the outer side of the blade part of the cutting tool (802), and the wedge-shaped pushing plate (804) is positioned on the outer side of the blade part of the cutting tool (802) and pushes the raw material in the cutting drum (40) to move.