A meat product material conveying device

Abstract

The utility model relates to meat product material conveying technical field, especially a kind of meat product material conveying device, including shell, shell right end top surface is equipped with feed inlet, shell left end face is equipped with discharge port, two installation shafts are arranged in parallel in shell;Installation shaft is set through shell, and installation shaft is slidably arranged on the side wall of shell;One end of installation shaft is connected with axial drive mechanism;Axial drive mechanism is used to drive two installation shafts to alternate reciprocating translation along the axis;Several groups of pusher mechanism are evenly arranged on installation shaft along the length direction;Each group of pusher mechanism includes limiting component and several push plates evenly arranged along the circumferential direction of installation shaft;Push plate is hinged on installation shaft;Limiting component can limit the included angle α between the plane of push plate and installation shaft axis;When pushing, limiting component limits α equal to 90 °;When returning, limiting component limits α as acute angle.The problem that traditional device cannot consider material quality protection and conveying continuity simultaneously is solved.

Description

Technical Field

[0001] This utility model relates to the field of meat product material conveying technology, and in particular to a meat product material conveying device. Background Technology

[0002] In the meat processing industry, material conveying is a crucial link in the production process, directly affecting production efficiency and product quality. With the development of automation technology, various material conveying devices are widely used in scenarios such as raw material transfer and process connection. Among them, the screw feeder has become one of the mainstream conveying equipment due to its simple structure, continuous conveying, and applicability to various forms of meat products (such as minced meat, meat granules, and ground meat), and occupies an important position in large and medium-sized meat processing plants.

[0003] Existing screw feeders typically consist of a cylindrical shell, a rotating shaft, and helical blades fixed to the rotating shaft. Their working principle involves a motor driving the rotating shaft to rotate the helical blades at high speed. The friction and thrust between the blades and the material push the material axially from the inlet to the outlet along the shell. This structure has demonstrated certain advantages in long-term applications, such as enabling closed-loop conveying to reduce external contamination and adapting to the conveying needs of materials with varying viscosities.

[0004] However, this type of screw feeder has significant technical drawbacks when processing meat products: First, the continuous rotation of the screw blades exerts continuous compression and shearing on the material, causing the meat fibers to break and the particles to crumble, severely damaging the original structure and quality of the material. Second, the continuous friction between the blades and the material, and between the material and the inner wall of the casing, generates a large amount of heat, raising the material temperature. Meat products are more prone to accelerated microbial growth at higher temperatures, increasing food safety risks. These problems have become key bottlenecks restricting the quality of material conveying in meat processing, necessitating a conveying device that can reduce material structure damage, lower the risk of temperature rise, and ensure conveying efficiency. Utility Model Content

[0005] In view of the current problems that meat products are prone to structural damage and temperature rise, which can easily damage the quality of the materials, this utility model provides a meat product material conveying device.

[0006] To solve the above problems, the technical solution adopted by this utility model is as follows:

[0007] A meat product material conveying device includes a housing with an inlet on the top right side and an outlet on the left side. Two mounting shafts are arranged parallel to each other inside the housing. The mounting shafts penetrate the housing and are slidably mounted on the side wall of the housing. One end of each mounting shaft is connected to an axial drive mechanism, which drives the two mounting shafts to alternately reciprocate axially. Several sets of pushing mechanisms are evenly arranged along the length of the mounting shafts. Each set of pushing mechanisms includes a limiting component and several push plates evenly arranged along the circumference of the mounting shaft. The push plates are hinged to the mounting shafts. The limiting component limits the angle α between the plane of the push plate and the axis of the mounting shaft. During pushing, the limiting component limits α to 90°. During return, the limiting component limits α to an acute angle. This meat product material conveying device uses two parallel mounting shafts and an axial drive mechanism to achieve alternating reciprocating translation. During pushing, the push plate is in a 90° vertical position under the action of the limiting component to effectively push the material. During return, the push plate is in an acute angle to reduce the reverse force with the material. This avoids the damage to the material structure caused by continuous squeezing and shearing in traditional screw devices. Furthermore, the reciprocating translation instead of rotation reduces frictional heat generation, lowering the risk of microbial growth caused by material temperature rise. It also allows the meat product material to be pushed forward within the shell. At the same time, the alternating operation of the two mounting shafts ensures conveying efficiency and solves the problem that traditional devices cannot balance material quality protection and continuous conveying.

[0008] Preferably, the overall cross-section of the shell is elliptical, with the axis of each mounting shaft coinciding with the focal point of the ellipse; the outer diameter of the pusher plate is twice the focal length of the ellipse. By setting the shell cross-section to elliptical and coinciding the axis of the mounting shaft with the focal point of the ellipse, combined with the design of the outer diameter of the pusher plate being twice the focal length of the ellipse, the residual dead corners of material within the shell are reduced through the adaptability of the elliptical inner wall to the pusher plate. This also ensures that the pushers on the two mounting shafts do not interfere with each other during alternating reciprocating motion. Furthermore, by utilizing the varying distance from the focal point of the ellipse to the inner wall, the pusher plate generates a more uniform pushing force on the material during the pushing process, avoiding excessive local compression, further reducing the risk of material structural damage, and improving the smoothness of the conveying process and the integrity of the material.

[0009] Preferably, the pusher plate is fan-shaped; the limiting component includes an annular groove formed on the outer wall of the mounting shaft; several pushers are hinged in the annular groove; a slope is provided on the side of the annular groove away from the feed inlet; the angle between the slope and the axis of the mounting shaft is acute. The fan-shaped design of the pusher plate increases the contact area with the material, improves the pushing stability and reduces local compression; the annular groove provides a stable hinged mounting space for the pusher plate, preventing material jamming from affecting the rotation of the pusher plate, and at the same time forming circumferential protection for the pusher plate; the acute-angle slope on the side of the annular groove away from the feed inlet can automatically retract the pusher plate to the acute angle state when the pusher plate returns, thanks to the synergistic effect of material resistance and slope guidance, achieving precise angle switching without additional drive components, which simplifies the limiting component and ensures the reliability of the pusher plate's operation in the pushing and returning states, further reducing material damage and equipment energy consumption.

[0010] Preferably, the angle between the slope and the axis of the mounting shaft is 45°; several baffles are evenly arranged along the circumference inside the annular groove; a hinge shaft is installed between two adjacent baffles; the push plate is hinged to the hinge shaft. The 45° angle between the slope and the axis of the mounting shaft allows the push plate to retract smoothly at a stable angle during the return stroke, minimizing reverse scraping with the material; the baffles in the annular groove separate the push plates into independent spaces, avoiding mutual interference during push plate movement, while the cooperation between the hinge shaft and the push plate ensures the flexibility and stability of the push plate rotation. This ensures that the push plate can accurately maintain a vertical state to provide effective thrust during material pushing, and makes the retraction action during return more reliable, further reducing the risk of material damage and operating noise, and improving the overall service life of the equipment.

[0011] Preferably, the side edge of the pusher plate facing the slope is chamfered. This chamfered edge allows for a smooth transition when the pusher plate rotates around the hinge axis and contacts the slope, preventing interference between adjacent pushers, extending the service life of the components, and making the pusher plate move more smoothly during retraction. This further reduces disturbance and scratching of the meat products, effectively protecting their integrity.

[0012] Preferably, a guide plate is fixedly installed on the inner wall of the shell at the feed inlet; the guide plate is configured in conjunction with the push plate. The guide plate at the feed inlet on the inner wall of the shell, in conjunction with the push plate, can guide the meat products entering from the feed inlet to the pushing area of ​​the push plate, reducing the accumulation of materials below the feed inlet or the scattering into dead corners where the push plate cannot function, thus ensuring the quality of the meat products.

[0013] Preferably, the axial drive mechanism includes a connecting rod connecting two mounting shafts; a connecting shaft is radially fixed at one end of each mounting shaft; an elongated through hole is provided on the connecting rod to mate with the connecting shaft, and a clearance through hole is also provided on the connecting rod to mate with the mounting shaft; a drive assembly is connected to the bottom surface of the middle part of the connecting rod. In the axial drive mechanism, the connecting rod engages with the connecting shaft of the mounting shaft through the elongated through hole, which enables the alternating reciprocating translation of the two mounting shafts and avoids interference during the movement of the mounting shafts through the clearance through hole. Combined with the drive assembly in the middle of the connecting rod, the driving force can be accurately transmitted. This not only simplifies the transmission structure and reduces the failure rate of the equipment, but also ensures the coordination and stability of the movement of the two mounting shafts, thereby improving the continuity and uniformity of material conveying.

[0014] Preferably, the drive assembly includes a rotating platform mounted on the bottom surface of the connecting rod; the rotating platform is mounted on a support. By using a rotating platform mounted on the bottom surface of the connecting rod and fixed to the support, the drive assembly can provide a continuous and uniform driving force to the connecting rod through the stable rotation of the rotating platform, enabling control of the alternating reciprocating translation of the two mounting shafts. Furthermore, the support's fixing effect enhances the overall stability of the drive mechanism, reducing vibration and displacement deviations during operation. This ensures the coordination of the pushing mechanism's actions and the continuity of material conveying, while also simplifying the power transmission path, reducing equipment maintenance difficulty, and improving reliability.

[0015] Preferably, a liquid outlet is provided at the lower part of the right end face of the shell; a liquid inlet is provided at the bottom surface of the left end of the shell. The liquid outlet at the lower part of the right end face of the shell and the liquid inlet at the bottom surface of the left end cooperate with each other, so that cleaning liquid can be introduced through the liquid inlet to rinse the inner cavity of the shell, while the liquid outlet at the lower right end can promptly discharge the wastewater after rinsing, juices seeping from the material, and other liquids, avoiding the accumulation of liquid in the shell that could lead to the growth of microorganisms or interfere with the material conveying. This not only ensures the hygiene and safety of meat product processing, but also facilitates the daily cleaning and maintenance of the equipment, improving the practicality and reliability of the device.

[0016] As can be seen from the above technical solution, the advantages of this utility model include: the meat product material conveying device achieves alternating reciprocating translation by setting two parallel mounting shafts and cooperating with an axial drive mechanism. When pushing material, the push plate is in a 90° vertical state under the action of the limiting component to effectively push the material. When returning, the push plate is in an acute angle state to reduce the reverse force with the material. This not only avoids the damage to the material structure caused by continuous squeezing and shearing in traditional screw devices, but also reduces frictional heat generation by replacing rotational motion with reciprocating translation, reducing the risk of microbial growth caused by material temperature rise. It also enables the meat product material to be pushed forward in the shell. At the same time, the alternating work of the two mounting shafts ensures the conveying efficiency and solves the problem that traditional devices cannot take into account both material quality protection and conveying continuity. Attached Figure Description

[0017] To more clearly illustrate the technical solution of this utility model, the drawings used in the description will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this utility model. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.

[0018] Figure 1 This is a schematic diagram of the structure of this utility model.

[0019] Figure 2 This is a partial cross-sectional structural diagram of the present invention.

[0020] Figure 3 This is a cross-sectional structural diagram of the present invention.

[0021] Figure 4 This is a schematic diagram of the structure at the hinge point between the mounting shaft and the push plate of this utility model.

[0022] Figure 5 This is a schematic diagram of the connecting rod of this utility model.

[0023] Figure 6 This is a schematic diagram of the push plate of this utility model.

[0024] Explanation of reference numerals in the attached drawings: 1-Housing, 2-Mounting shaft, 3-Push plate, 4-Connecting rod, 5-Rotating platform, 6-Support; 101-Inlet, 102-Outlet, 103-Guide plate, 104-Liquid outlet, 105-Inlet; 201-Annular groove, 202-Slope, 203-Partition plate, 204-Hinge shaft, 205-Connecting shaft; 301-Chamfered edge; 401-Long through hole, 402-Leaning through hole. Detailed Implementation

[0025] To make the objectives, features, and advantages of this utility model more apparent and understandable, the technical solutions of this utility model will be clearly and completely described below with reference to the accompanying drawings of the specific embodiments. Obviously, the embodiments described below are only some embodiments of this utility model, and not all embodiments. Based on the embodiments of this patent, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of this patent.

[0026] like Figure 1-3As shown, a meat product material conveying device includes a housing 1. A feed inlet 101 is provided on the top right side of the housing 1, and a discharge outlet 102 is provided on the left side of the housing 1. Two mounting shafts 2 are arranged parallel to each other inside the housing 1. The mounting shafts 2 penetrate the housing 1 and are slidably mounted on the side wall of the housing 1. One end of each mounting shaft 2 is connected to an axial drive mechanism. The axial drive mechanism drives the two mounting shafts 2 to alternately reciprocate axially. Several sets of pushing mechanisms are evenly arranged along the length of the mounting shafts 2. Each set of pushing mechanisms includes a limiting component and several push plates 3 evenly arranged along the circumference of the mounting shaft 2. The push plates 3 are hinged to the mounting shafts 2. The limiting component can limit the angle α between the plane of the push plate 3 and the axis of the mounting shaft 2. During pushing, the limiting component limits α to 90°; during return, the limiting component limits α to an acute angle. A liquid outlet 104 is provided at the lower part of the right side of the housing 1, and a liquid inlet 105 is provided on the bottom left side of the housing 1. A guide plate 103 is fixedly installed on the inner wall of the housing 1 at the feed inlet 101; the guide plate 103 is configured in conjunction with the push plate 3.

[0027] This meat product material conveying device uses two parallel mounting shafts 2 and an axial drive mechanism to achieve alternating reciprocating translation. When pushing material, the push plate 3 is in a 90° vertical state under the action of the limiting component to effectively push the material. When returning, the push plate 3 is in an acute angle state to reduce the reverse force with the material. This not only avoids the damage to the material structure caused by continuous squeezing and shearing in traditional screw devices, but also reduces frictional heat generation by replacing rotational motion with reciprocating translation, thereby reducing the risk of microbial growth caused by material temperature rise. It also allows the meat product material to be pushed forward within the shell 1. At the same time, the alternating work of the two mounting shafts 2 ensures the conveying efficiency and solves the problem that traditional devices cannot take into account both material quality protection and conveying continuity. The liquid outlet at the lower right end face of the shell works in conjunction with the liquid inlet on the bottom left end. The inlet allows cleaning fluid to be introduced to rinse the inner cavity of the shell, while the outlet at the lower right end promptly discharges wastewater and seepage from the material, preventing residual liquid from causing microbial growth or interfering with material transport. This ensures the hygiene and safety of meat processing and facilitates daily cleaning and maintenance, improving the practicality and reliability of the device. The guide plate 103 at the feed inlet 101 on the inner wall of the shell 1 works in conjunction with the push plate 3 to guide the meat material entering through the feed inlet 101 to the pushing area of ​​the push plate 3. This reduces material accumulation below the feed inlet 101 or spillage into dead zones where the push plate 3 cannot function, ensuring the quality of the meat products.

[0028] The axial drive mechanism includes a connecting rod 4 that connects two mounting shafts 2; a connecting shaft 205 is fixedly mounted radially at one end of each mounting shaft 2; for example... Figure 5As shown, a long through hole 401 is provided on the connecting rod 4 to mate with the connecting shaft 205, and a clearance through hole 402 is provided on the connecting rod 4 to mate with the mounting shaft 2; a drive assembly is connected to the bottom surface of the middle part of the connecting rod 4. The drive assembly includes a rotating platform 5 mounted on the bottom surface of the connecting rod 4; the rotating platform 5 is mounted on the support 6. In the axial drive mechanism, the connecting rod 4 mates with the connecting shaft 205 of the mounting shaft 2 through the long through hole 401, which can realize the alternating reciprocating translation of the two mounting shafts 2, and can also avoid interference when the mounting shafts 2 move through the clearance through hole 402. With the drive assembly in the middle of the connecting rod 4, the driving force can be accurately transmitted, which not only simplifies the transmission structure and reduces the failure rate of equipment operation, but also ensures the coordination and stability of the movement of the two mounting shafts 2, thereby improving the continuity and uniformity of material conveying. The drive assembly uses a rotating platform 5 mounted on the bottom surface of the connecting rod 4 and fixed to the support 6. The stable rotation of the rotating platform 5 provides a continuous and uniform driving force to the connecting rod 4, enabling the control of the alternating reciprocating translation of the two mounting shafts 2. The fixing effect of the support 6 enhances the overall stability of the drive mechanism, reduces vibration and displacement deviation during operation, thereby ensuring the coordination of the pushing mechanism's actions and the continuity of material conveying. At the same time, it simplifies the power transmission path, reduces the difficulty of equipment maintenance, and improves reliability.

[0029] In other alternative embodiments, the axial drive mechanism consists of two cylinders, hydraulic cylinders, or electric actuators, with the output ends of the cylinders, hydraulic cylinders, or electric actuators connected to one end of the mounting shaft 2. This embodiment requires a relatively complex control system to control the alternating movements of the two cylinders, hydraulic cylinders, or electric actuators, thereby driving the two mounting shafts 2 to move axially alternately.

[0030] In the above settings, such as Figure 4 As shown, the cross-section of the housing 1 is generally elliptical, and the axis of each mounting shaft 2 coincides with the focal point of the ellipse; the outer diameter of the push plate 3 is twice the focal length of the ellipse of the housing 1. The push plate 3 is generally fan-shaped; the limiting assembly includes an annular groove 201 formed on the outer wall of the mounting shaft 2; several push plates 3 are hinged in the annular groove 201; a slope 202 is provided on the side of the annular groove 201 away from the feed inlet 101; the angle between the slope 202 and the axis of the mounting shaft 2 is an acute angle. The angle between the slope 202 and the axis of the mounting shaft 2 is 45°; several partitions 203 are evenly arranged in the annular groove 201 along the circumferential direction; a hinge shaft 204 is installed between two adjacent partitions 203; the push plate 3 is hinged to the hinge shaft 204.

[0031] By designing the cross-section of the housing 1 as an ellipse and aligning the axis of the mounting shaft 2 with the focal point of the ellipse, and combining this with a design where the outer diameter of the push plate 3 is twice the focal length of the ellipse, the adaptability between the inner wall of the ellipse and the push plate 3 reduces the dead corners of material residue within the housing 1. This also ensures that the push plates 3 on the two mounting shafts 2 do not interfere with each other during their alternating reciprocating motion. Furthermore, by utilizing the change in distance from the focal point of the ellipse to the inner wall, the push plate 3 generates a more uniform pushing force on the material during the pushing process, avoiding excessive local compression, further reducing the risk of material structural damage, and improving the smoothness of the conveying process and the integrity of the material. The push plate 3 is designed in a fan shape to increase the contact area with the material, improve the pushing stability and reduce local squeezing; the annular groove 201 provides a stable hinge installation space for the push plate 3, avoiding material jamming that affects the rotation of the push plate 3, and at the same time forming circumferential protection for the push plate 3; the acute-angle slope 202 on the side of the annular groove 201 away from the feed port 101 can automatically retract the push plate 3 to the acute angle state when the push plate 3 returns, with the help of the material resistance and the guiding effect of the slope 202. The angle can be accurately switched without additional driving components, which simplifies the limiting components and ensures the reliability of the push plate 3 in the pushing and returning states, further reducing material damage and equipment energy consumption. The slope 202 is set at a 45° angle with the axis of the mounting shaft 2, which allows the push plate 3 to retract smoothly at a stable angle during the return stroke, minimizing reverse scraping with the material. The partition 203 in the annular groove 201 separates the push plate 3 into an independent space, avoiding mutual interference when the push plates 3 move. The cooperation between the hinge shaft 204 and the push plate 3 ensures the flexibility and stability of the push plate 3's rotation. This ensures that the push plate 3 can accurately maintain a vertical state to provide effective thrust when pushing material, and makes the retraction action during return more reliable. This further reduces the risk of material damage and operating noise, and improves the overall service life of the equipment.

[0032] like Figure 6 As shown, a chamfered edge 301 is provided on the side edge of the push plate 3 facing the slope 202. The chamfered edge 301 on the side edge of the push plate 3 facing the slope 202 can form a smooth transition when the push plate 3 rotates around the hinge axis 204 and contacts the slope 202, avoiding interference between adjacent push plates 3, extending the service life of the components, and making the push plate 3 move more smoothly during the retraction process, further reducing disturbance and scratching of meat products, and effectively protecting the integrity of meat products.

[0033] After the axial drive mechanism is started, the two mounting shafts 2 are driven to reciprocate and translate alternately along the axial direction of the housing 1 through the cooperation of the connecting rod 4 and the connecting shaft 205. When one of the mounting shafts 2 is driven to translate to the left (towards the discharge port 102), the push plate 3 in its pushing mechanism is kept perpendicular to the axis of the mounting shaft 2 at 90° under the action of the limiting component (the blocking effect of the annular groove 201). The side of the push plate 3 perpendicular to the conveying direction directly contacts and pushes the meat product material in the housing 1 toward the discharge port 102. At the same time, the other mounting shaft 2 translates to the right (towards the inlet 101). The push plate 3 of its pushing mechanism automatically retracts under the reverse resistance of the material and the limiting effect of the slope 202, forming an acute angle of 45° with the axis of the mounting shaft 2. At this time, the push plate 3 smoothly returns along the surface of the material, reducing the reverse drag on the already pushed material. After the two mounting shafts 2 complete one stroke switch, the mounting shaft 2 that was originally pushing to the left turns to return to the right (the push plate 3 retracts to a 45° acute angle), and the mounting shaft 2 that was originally returning to the right turns to push to the left (the push plate 3 unfolds to a 90° angle). Through this alternating and reciprocating coordinated action, the continuous and segmented pushing of meat products is achieved, which not only ensures the continuity of material conveying, but also reduces the squeezing and friction of the material during the pushing process by changing the angle of the push plate 3.

[0034] The above description of the disclosed embodiments enables those skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the general principles defined herein may be implemented in other embodiments without departing from the spirit or scope of the present invention. Therefore, the present invention is not to be limited to the embodiments shown herein, but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims

1. A meat product material conveying device, comprising a housing (1), wherein a feed inlet (101) is provided on the top surface of the right end of the housing (1), and a discharge outlet (102) is provided on the end face of the left end of the housing (1), characterized in that, Two mounting shafts (2) are arranged in parallel inside the housing (1); the mounting shafts (2) are arranged through the housing (1) and are slidably arranged on the side wall of the housing (1); one end of the mounting shaft (2) is connected to an axial drive mechanism; the axial drive mechanism is used to drive the two mounting shafts (2) to move back and forth alternately along the axial direction; several sets of pushing mechanisms are evenly arranged along the length direction on the mounting shaft (2); each set of pushing mechanisms includes a limiting component and several push plates (3) evenly arranged along the circumference of the mounting shaft (2); the push plates (3) are hinged to the mounting shaft (2); the limiting component can limit the angle α between the plane where the push plate (3) is located and the axis of the mounting shaft (2); when pushing, the limiting component limits α to 90°; when returning, the limiting component limits α to an acute angle.

2. The meat product material conveying device according to claim 1, characterized in that, The cross-section of the housing (1) is elliptical in shape, and the axis of each mounting shaft (2) coincides with the focus of the ellipse; the outer diameter of the push plate (3) is twice that of the ellipse of the housing (1).

3. The meat product material conveying device according to claim 2, characterized in that, The push plate (3) is fan-shaped; the limiting component includes an annular groove (201) opened on the outer wall of the mounting shaft (2); several push plates (3) are hinged in the annular groove (201); a slope (202) is provided on the side of the annular groove (201) away from the feed port (101); the angle between the slope (202) and the axis of the mounting shaft (2) is an acute angle.

4. The meat product material conveying device according to claim 3, characterized in that, The angle between the slope (202) and the axis of the mounting shaft (2) is 45°; several partitions (203) are evenly arranged in the circular groove (201) along the circumferential direction; a hinge shaft (204) is installed between two adjacent partitions (203); the push plate (3) is hinged to the hinge shaft (204).

5. The meat product material conveying device according to claim 4, characterized in that, A chamfered edge (301) is provided on the side edge of the push plate (3) facing the slope (202).

6. The meat product material conveying device according to claim 5, characterized in that, A guide plate (103) is fixedly installed on the inner wall of the housing (1) at the feed inlet (101); the guide plate (103) is set in conjunction with the push plate (3).

7. The meat product material conveying device according to claim 1 or 6, characterized in that, The axial drive mechanism includes a connecting rod (4) connecting two mounting shafts (2); a connecting shaft (205) is fixedly installed at one end of the mounting shaft (2) in the radial direction; a long through hole (401) is opened on the connecting rod (4) to cooperate with the connecting shaft (205), and a clearance through hole (402) is opened on the connecting rod (4) to cooperate with the mounting shaft (2); a drive assembly is connected to the bottom surface of the middle part of the connecting rod (4).

8. The meat product material conveying device according to claim 7, characterized in that, The drive assembly includes a rotating platform (5) mounted on the bottom surface of the connecting rod (4); the rotating platform (5) is mounted on the support (6).

9. The meat product material conveying device according to claim 1, characterized in that, The lower part of the right end face of the shell (1) is provided with a liquid outlet (104); the bottom surface of the left end of the shell (1) is provided with a liquid inlet (105).

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