阅读说明：本技术 一种冷冻食品物料破碎的自动化机械设备 (Automatic mechanical equipment for crushing frozen food materials ) 是由 吴敏 于 2021-09-27 设计创作，主要内容包括：本发明公开了一种冷冻食品物料破碎的自动化机械设备,属于食品加工领域,包括：支架立柱、破碎仓板和破碎中轴三部分组成,支架立柱顶端焊接有上横梁,所述支架立柱中部焊接有中横梁,所述上横梁和中横梁内表面焊接有侧挡板,支架立柱用于固定和安装侧挡板和破碎仓板,使得整体结构受力均衡且能够稳定放置在地面上,上横梁用于固定侧挡板的上端,且用于安装两个无杆气缸,中横梁用于安装和固定侧挡板的中部,同时加固整体结构的稳定性,多个破碎仓板焊接在两块侧挡板之间,每两块所述破碎仓板之间安装有刀架圆环,所述刀架圆环与破碎仓板交替排列,刀架圆环可在破碎中轴上在一定角度范围内转动。(The invention discloses automatic mechanical equipment for crushing frozen food materials, which belongs to the field of food processing and comprises the following components: the support stand column, the broken storehouse board and broken axis triplex, the welding of support stand column top has the entablature, the welding of support stand column middle part has the entablature, entablature and the internal surface welding of entablature have the side shield, and the support stand column is used for fixing and installs side shield and broken storehouse board for overall structure atress is balanced and can stably place subaerial, and the entablature is used for fixing the upper end of side shield, and is used for installing two rodless cylinders, and the entablature is used for the middle part of installation and fixed side shield, consolidates overall structure's stability simultaneously, and a plurality of broken storehouse board welding is between two side shields, per two install the knife rest ring between the broken storehouse board, knife rest ring and broken storehouse board alternate arrangement, the knife rest ring can be epaxial rotation in certain angle within range in breakage.)

1. An automated mechanical apparatus for the fragmentation of frozen food material, comprising:

an upper cross beam (101) is welded at the top end of the support upright post (1), a middle cross beam (102) is welded in the middle of the support upright post (1), and side baffles (2) are welded on the inner surfaces of the upper cross beam (101) and the middle cross beam (102);

the crushing bin plates (3) are welded between the two side baffle plates (2), a tool rest circular ring (401) is arranged between every two crushing bin plates (3), and the tool rest circular ring (401) and the crushing bin plates (3) are arranged alternately;

the bottom of the crushing bin plate (3) is sleeved with a crushing center shaft (4), the crushing center shaft (4) penetrates through all the crushing bin plates (3), and a tool rest circular ring (401) is sleeved outside the crushing center shaft (4).

2. An automated mechanical apparatus for the breaking of frozen food pieces, according to claim 1, characterized in that: the welding has cutting tool rail (402) on knife rest ring (401), cutting edge (403) are installed to the embedded cutting tool rail (402), cutting tool rail (402) thickness is less than knife rest ring (401), the length of cutting tool rail (402) is greater than the length of broken storehouse board (3).

3. An automated mechanical apparatus for the breaking of frozen food pieces, according to claim 1, characterized in that: the slag pushing arc (302) is arranged in the middle of the crushing bin plate (3), the bin plate round angle (301) is arranged on the edge of the inner surface of the crushing bin plate (3), and the gap depth between the two crushing bin plates (3) is larger than the width of the cutting tool rail (402).

4. An automated mechanical apparatus for the breaking of frozen food pieces, according to claim 1, characterized in that: the arc surface top welding of cutting tool rail (402) has tool rail push rod (406), tool rail push rod (406) both ends are provided with push rod pivot (407), entablature (101) upper surface passes through bolt fixedly connected with rodless cylinder (5), push rod pivot (407) rotate to be connected on rodless cylinder (5).

5. An automated mechanical apparatus for the breaking of frozen food pieces according to claim 4, characterized in that: rodless cylinder (5) are including cylinder support (501) and cylinder slide rail (502), bolt fixedly connected with cylinder bedplate (507) is passed through to cylinder support (501) bottom, cylinder bedplate (507) passes through bolt fixed mounting at entablature (101) upper surface, sliding connection has cylinder slider (503) on cylinder slide rail (502), cylinder slider (503) side is through bolt fixedly connected with tool rail promotion guide rail (504), sliding connection has tool rail promotion slider (505) on tool rail promotion guide rail (504), slider trompil (506) have been seted up to tool rail promotion slider (505) side, tool rail promotion slider (505) internal rotation is connected with push rod pivot (407).

6. An automated mechanical apparatus for the breaking of frozen food pieces, according to claim 1, characterized in that: side shield (2) below has been seted up and has been pushed away cinder notch (202) it is provided with slag discharging channel (203) to push away outside cinder notch (202), slag discharging channel (203) welding is on side shield (2), it is concentric to push away cinder notch (202), push away sediment circular arc (302), slag discharging channel (203) three, and pushes away cinder notch (202), pushes away sediment circular arc (302), the radius of slag discharging channel (203) equals.

7. An automated mechanical apparatus for the breaking of frozen food pieces, according to claim 1, characterized in that: the welding of the right flank of right side shield (2) has and pushes away sediment piece pipe (6), it has pipe support (601) to push away the welding of sediment piece pipe (6) right-hand member, it has seted up pipe trompil (602) to push away sediment piece pipe (6) left side below, it has and pushes away sediment piece (603) to push away interior sliding fit of sediment piece pipe (6), it has seted up and has pushed away sediment rack (604) to push away sediment piece (603) bottom.

8. An automated mechanical apparatus for the breaking of frozen food pieces, according to claim 1, characterized in that: the utility model discloses a slag pushing device, including support stand column (1), slag pushing motor (607), it has motor mounting panel (608) to push away the welding of slag motor (607) left side, motor mounting panel (608) are installed at support stand column (1) right flank through the bolt, it is provided with and pushes away slag motor output shaft (606) to push away slag motor (607) front end, it is connected with and pushes away slag gear (605) to push away slag motor output shaft (606) top interference fit, it is located and pushes away slag block pipe (6) below to push away slag motor (607), push away slag gear (605) and push away slag rack (604) and mesh mutually.

9. An automated mechanical apparatus for the breaking of frozen food pieces, according to claim 2, characterized in that: a tool path T-shaped groove (405) is formed in the cutting tool path (402), a tool edge T-shaped tail (404) is arranged on the cutting tool edge (403), and the tool edge T-shaped tail (404) is excessively matched and connected in the tool path T-shaped groove (405).

Technical Field

The invention belongs to the technical field of food processing, and particularly relates to automatic mechanical equipment for crushing frozen food materials.

Background

China is one of the countries with the most fresh water aquaculture water surfaces in the world, and the fresh water aquaculture yield is also the top of the world. In the last decade, the fresh water aquaculture industry in China has developed rapidly. In 2010, the total output of freshwater aquaculture in China is about 2600 ten thousand tons, and the output of a large number of freshwater fishes (black carps, grass carps, silver carps, bighead carps, crucian carps and breams) is about 1820 ten thousand tons, accounting for 70% of the total output of freshwater aquaculture in China. However, the proportion of freshwater fish processing in China is quite low, fresh marketing is basically relied on, and in some key fish culture areas, the contradiction between production and marketing is suddenly hit, and the marketing is lost. In order to improve the deep processing strength, representative frozen surimi is selected as a material to prepare the fish ball, and the method has important significance for fully utilizing aquatic resources. When processing frozen food, after quick-freeze tunnel, a plurality of frozen food can the adhesion together, for convenient subsequent measurement, packing, need separate the frozen food that the adhesion is together, and current operation method is that the manual work uses hammer-shaped instrument to beat moderately, extravagant manpower and materials on the one hand, and on the other hand has also increased workman's the amount of labour, influences workman's healthy, consequently, it is necessary to provide a breaker, replaces manual operation.

Disclosure of Invention

The present invention aims to provide an automatic mechanical device for crushing frozen food materials, so as to solve the problems in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme: an automated mechanical apparatus for breaking frozen food pieces, comprising: the support stand column, the crushing bin plate and the crushing middle shaft.

The upper cross beam is used for fixing the upper end of the side baffle and installing two rodless cylinders, and the middle cross beam is used for installing and fixing the middle part of the side baffle and simultaneously reinforcing the stability of the whole structure;

the crushing bin plates are welded between the two side baffle plates, a knife rest ring is arranged between every two crushing bin plates, the knife rest rings and the crushing bin plates are alternately arranged, the knife rest rings can rotate on a crushing center shaft within a certain angle range, and the arrangement mode of the crushing bin plates and the knife rest rings ensures that the thickness of the crushed frozen food material finally cut is equal to that of the crushing bin plates;

the bottom of the crushing bin plate is sleeved with a crushing center shaft, the crushing center shaft penetrates through all the crushing bin plates, a knife rest ring is sleeved outside the crushing center shaft, and the crushing center shaft is used for connecting the crushing bin plates and the knife rest ring, so that the knife rest ring can work normally.

Preferably, the welding has the cutting tool rail on the knife rest ring, the cutting edge is installed to the embedding in the cutting tool rail, cutting tool rail thickness is less than the knife rest ring, the length of cutting tool rail is greater than the length of broken storehouse board, and the knife rest ring makes the cutting tool rail can be around broken axis at certain angular range internal rotation, realizes the broken function of frozen food material, and the cutting tool rail is used for installing the cutting edge, and after equipment use was allowed in the assembled design between cutting edge and the cutting tool rail for a period of time, the staff can change the cutting edge when the cutting edge is no longer sharp, and cutting tool rail thickness is less than the knife rest ring for the clearance between two broken storehouse boards can freely be passed in and out to the cutting tool rail and can not block, and the length of cutting tool rail is greater than the length of broken storehouse board makes the tool rail push rod can normally promote all cutting tool rails.

Preferably, a slag pushing circular arc is arranged in the middle of the crushing bin plate, a bin plate circular corner is arranged at the edge of the inner surface of the crushing bin plate, the gap depth between the crushing bin plates is larger than the width of the cutting tool rail, the slag pushing circular arc is used for leaving a moving space for the work of pushing a slag block, the design of the bin plate circular corner can effectively prevent frozen food material fragments from being cut by the edge of the crushing bin plate when being pushed out, so that the moving track of the cutting tool rail is blocked, the cut frozen food material fragments can be smoothly pushed out, the gap depth between the crushing bin plates is larger than the width of the cutting tool rail, the cutting tool rail can be completely hidden in two blocks after being provided with cutting edges, and the pushing-out of the frozen food material fragments is prevented from being hindered.

Preferably, the top end of the arc surface of each cutting tool rail is welded with a tool rail push rod, two ends of each tool rail push rod are provided with push rod rotating shafts, the upper surface of the upper beam is fixedly connected with a rodless cylinder through bolts, the push rod rotating shafts are rotatably connected to the rodless cylinders, the tool rail push rods can simultaneously push all the cutting tool rails, the tool rail push rods can rotate in the tool rail pushing sliding blocks, and the tool rail push rods can normally work when the cutting tool rails rotate around the crushing center shafts.

Preferably, rodless cylinder includes cylinder support and cylinder slide rail, there is cylinder bedplate cylinder support bottom through bolt fixedly connected with, the cylinder bedplate passes through bolt fixed mounting at the entablature upper surface, sliding connection has the cylinder slider on the cylinder slide rail, there is tool rail promotion guide rail cylinder slider side through bolt fixedly connected with, sliding connection has tool rail promotion slider on the tool rail promotion guide rail, the slider trompil has been seted up to tool rail promotion slider side, tool rail promotion slider internal rotation is connected with the push rod pivot, and rodless cylinder is used for promoting the tool rail push rod, and two rodless cylinders work in step, and rail promotion slider sliding connection is on tool rail promotion guide rail for rodless cylinder can not block when promoting the promotion tool rail push rod.

Preferably, the side shield below has been seted up and has been pushed away the cinder notch push away the cinder notch and be provided with the scum way outward, the scum way welds on the side shield, push away the cinder notch, push away the cinder arc, arrange the cinder notch three concentric, and push away the cinder notch, push away the cinder arc, arrange the radius of cinder notch and equal, arrange the cinder notch and can prolong the distance that pushes away the sediment action for collect the frozen food material that the transportation breakage was accomplished convenient and fast more.

Preferably, the right flank welding of right side shield has and pushes away the sediment piece pipe, it has the pipe support to push away sediment piece pipe right-hand member welding, it has seted up the pipe trompil to push away sediment piece pipe left side below, it has and pushes away the sediment piece to push away the interior sliding fit of sediment piece pipe and be connected with, it has seted up and has pushed away the sediment rack to push away sediment piece bottom, pushes away the sediment piece pipe and is used for the restraint to push away the sediment piece, and the messenger pushes away the sediment piece and can the horizontal slip, and the pipe trompil is used for will pushing away the sediment rack that pushes away on the sediment piece and expose to the messenger pushes away the sediment gear can with push away the sediment rack and mesh mutually.

Preferably, support stand right side is installed and is pushed away the sediment motor, it has the motor mounting panel to push away the welding of sediment motor left side, the motor mounting panel passes through the bolt and installs at support stand right flank, it is provided with and pushes away sediment motor output shaft to push away sediment motor front end, it is connected with and pushes away the sediment gear to push away sediment motor output shaft interference fit, it is located and pushes away sediment piece pipe below to push away the sediment motor, push away the sediment gear and push away the meshing of sediment rack mutually, push away the sediment motor and be used for releasing the action and provide power for the frozen food piece that releases broken completion, the motor mounting panel is used for will pushing away sediment motor fixed mounting on support stand, pushes away the sediment gear and is used for transmitting the moment of torsion that pushes away the sediment motor and produce to pushing away the sediment piece, makes the rotary motion who pushes away sediment motor output shaft convert the linear motion that pushes away the sediment piece.

Preferably, a tool path T-shaped groove is formed in the cutting tool path, a cutting edge T-shaped tail is arranged on the cutting blade, the cutting edge T-shaped tail is excessively matched and connected in the tool path T-shaped groove, the tool path T-shaped groove is matched with the cutting edge T-shaped tail to enable the cutting blade to be firmly installed in the cutting tool path, and the cutting blade can be detached from the cutting tool path and replaced when necessary.

The invention has the beneficial effects that:

1. a plurality of cutting blades work jointly, and once the cutting can be shredded frozen food material, and crushing efficiency is high, pushes away the lower extreme of sediment circular arc design at broken storehouse board for it is closer apart from broken axis to push away the sediment circular arc, because lever principle, effectively strengthens the cutting dynamics of cutting blade, improves cutting efficiency.

2. The design of the T-shaped groove of the tool path and the T-shaped tail of the cutting edge can enable the cutting blade to normally work when the frozen food material is cut, and after the cutting blade is used for a long time and is worn, the cutting blade can be detached from the cutting tool path for replacement, so that the maintenance cost is low.

Drawings

FIG. 1 is a schematic view of an axial structure of the present invention;

FIG. 2 is an enlarged view of the structure of FIG. 1 at F according to the present invention;

FIG. 3 is a schematic perspective view of the present invention with some parts hidden, showing a schematic perspective view of FIG. 1;

FIG. 4 is an enlarged view of the structure of FIG. 3 at G in accordance with the present invention;

FIG. 5 is a schematic perspective view of the present invention with some parts hidden therein, shown in FIG. 2;

FIG. 6 is an enlarged schematic view of the present invention at H in FIG. 5;

FIG. 7 is an enlarged view of the structure of FIG. 5 at J in accordance with the present invention;

FIG. 8 is a schematic top view of the present invention;

fig. 9 is a schematic front view of the present invention.

In the figure: 1. a bracket upright post; 101. an upper cross beam; 102. a middle cross beam; 2. a side dam; 201. an end face baffle; 202. a slag pushing port; 203. a slag discharge channel; 3. crushing a bin plate; 301. the bin plate is provided with round corners; 302. pushing slag arcs; 4. crushing the middle shaft; 401. a tool holder ring; 402. cutting the tool path; 403. a cutting blade; 404. a blade T-shaped tail; 405. a tool path T-shaped groove; 406. a tool path push rod; 407. a push rod rotating shaft; 5. a rodless cylinder; 501. a cylinder support; 502. a cylinder slide rail; 503. a cylinder slider; 504. the tool path pushes the guide rail; 505. the tool path pushes the slide block; 506. opening a hole in the sliding block; 507. a cylinder seat plate; 6. a slag block pushing conduit; 601. a catheter mount; 602. opening a hole in the conduit; 603. pushing the slag block; 604. a slag pushing rack; 605. a slag pushing gear; 606. an output shaft of a slag pushing motor; 607. a slag pushing motor; 608. motor mounting panel.

Detailed Description

In the description of the present invention, it should be noted that the terms "upper", "lower", "inner", "outer", "top/bottom", and the like indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and thus should not be construed as limiting the present invention. Furthermore, the terms "first" and "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "disposed," "sleeved/connected," "connected," and the like are to be construed broadly, e.g., "connected," which may be fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Examples

Referring to fig. 1-9, an automated mechanical apparatus for breaking frozen food product comprises: the support upright post 1, the crushing bin plate 3 and the crushing middle shaft 4.

The top end of the support upright post 1 is welded with an upper cross beam 101, the middle part of the support upright post 1 is welded with a middle cross beam 102, and the inner surfaces of the upper cross beam 101 and the middle cross beam 102 are welded with side baffles 2;

a plurality of crushing bin plates 3 are welded between the two side baffle plates 2, a tool rest ring 401 is arranged between every two crushing bin plates 3, and the tool rest ring 401 and the crushing bin plates 3 are alternately arranged;

the bottom of the crushing bin plate 3 is sleeved with a crushing middle shaft 4, the crushing middle shaft 4 penetrates through all the crushing bin plates 3, and a tool rest circular ring 401 is sleeved outside the crushing middle shaft 4.

In a further embodiment, the support upright post 1 is used for fixing and installing the side baffle 2 and the crushing bin plate 3, so that the integral structure is stressed uniformly and can be stably placed on the ground, the upper cross beam 101 is used for fixing the upper end of the side baffle 2 and is used for installing the two rodless cylinders 5, the middle cross beam 102 is used for installing and fixing the middle part of the side baffle 2, meanwhile, the stability of the integral structure is strengthened, the knife rest ring 401 can rotate on the crushing middle shaft 4 within a certain angle range, the arrangement mode of the crushing bin plate 3 and the knife rest ring 401 enables the thickness of the frozen food material to be finally cut into pieces to be equal to the thickness of the crushing bin plate 3, the crushing middle shaft 4 is used for connecting the crushing bin plates 3 and the knife rest ring 401, and the knife rest ring 401 can work normally.

Specifically, referring to fig. 6, a cutting tool track 402 is welded on a tool rest circular ring 401, a cutting tool edge 403 is embedded in the cutting tool track 402, the thickness of the cutting tool track 402 is smaller than that of the tool rest circular ring 401, and the length of the cutting tool track 402 is larger than that of the crushing bin plate 3.

In a further embodiment, the knife rest ring 401 enables the cutting knife track 402 to rotate around the crushing central shaft 4 within a certain angle range, so as to realize the function of crushing frozen food materials, the cutting knife track 402 is used for installing the cutting knife edge 403, after the assembled design between the cutting knife edge 403 and the cutting knife track 402 allows the device to be used for a period of time, a worker can replace the cutting knife edge 403 when the cutting knife edge 403 is no longer sharp, the thickness of the cutting knife track 402 is smaller than that of the knife rest ring 401, so that the cutting knife track 402 can freely enter and exit a gap between two crushing bin plates 3 without being clamped, and the length of the cutting knife track 402 is larger than that of the crushing bin plates 3, so that the knife track push rod 406 can normally push all the cutting knife track 402.

Specifically, referring to fig. 5, a slag pushing arc 302 is disposed in the middle of the crushing bin plate 3, a bin plate fillet 301 is disposed on the edge of the inner surface of the crushing bin plate 3, and the depth of the gap between the two crushing bin plates 3 is greater than the width of the cutting blade track 402.

In a further embodiment, the slag pushing arc 302 is used for leaving an active space for the operation of the slag pushing block 603, the design of the bin plate fillet 301 can effectively prevent frozen food material fragments from being cut by the edge of the crushing bin plate 3 when being pushed out, so as to block the active track of the cutting tool track 402, and also enable the cut frozen food material fragments to be smoothly pushed out, the depth of the gap between the two crushing bin plates 3 is greater than the width of the cutting tool track 402, so that the cutting tool track 402 can be completely hidden in the gap between the two crushing bin plates 3 after being provided with the cutting tool 403, and the pushing out of the frozen food material fragments is prevented from being hindered.

Specifically, referring to fig. 1 and 2, a tool path push rod 406 is welded to the top end of the arc surface of the cutting tool path 402, push rod rotating shafts 407 are disposed at two ends of the tool path push rod 406, the upper surface of the upper cross beam 101 is fixedly connected to a rodless cylinder 5 through bolts, and the push rod rotating shafts 407 are rotatably connected to the rodless cylinder 5.

In a further embodiment, the tool path pushing rod 406 can push all the cutting tool paths 402 at the same time, and the tool path pushing rod 406 can rotate in the tool path pushing slider 505, so that the tool path pushing rod 406 can work normally when the cutting tool paths 402 rotate around the crushing central shaft 4.

Specifically, referring to fig. 1 and 2, the rodless cylinder 5 includes a cylinder support 501 and a cylinder slide rail 502, the bottom of the cylinder support 501 is fixedly connected with a cylinder seat plate 507 through a bolt, the cylinder seat plate 507 is fixedly mounted on the upper surface of the upper beam 101 through a bolt, the cylinder slide rail 502 is slidably connected with a cylinder slide block 503, the side surface of the cylinder slide block 503 is fixedly connected with a tool rail pushing guide rail 504 through a bolt, the tool rail pushing guide rail 504 is slidably connected with a tool rail pushing slide block 505, the side surface of the tool rail pushing slide block 505 is provided with a slide block opening 506, and the tool rail pushing slide block 505 is rotatably connected with a push rod rotating shaft 407.

In a further embodiment, a rodless cylinder 5 is used to push the tool rail push rod 406, and the two rodless cylinders 5 operate synchronously, and a rail push slider 505 is slidably connected to the tool rail push rail 504, so that the rodless cylinder 5 does not get stuck when pushing the tool rail push rod 406.

Specifically, referring to fig. 1, a slag pushing port 202 is formed below the side baffle 2, a slag discharging channel 203 is arranged outside the slag pushing port 202, the slag discharging channel 203 is welded on the side baffle 2, the slag pushing port 202, the slag pushing arc 302 and the slag discharging channel 203 are concentric, and the radii of the slag pushing port 202, the slag pushing arc 302 and the slag discharging channel 203 are equal.

In a further embodiment, the slag discharge channel 203 can extend the distance of slag pushing action, so that the collection and transportation of the crushed frozen food materials are more convenient and faster.

Specifically, referring to fig. 3 and 4, the slag pushing block guide pipe 6 is welded on the right side surface of the right side baffle 2, the guide pipe support 601 is welded at the right end of the slag pushing block guide pipe 6, the guide pipe opening 602 is formed below the left side of the slag pushing block guide pipe 6, the slag pushing block 603 is connected in the slag pushing block guide pipe 6 in a sliding fit manner, and the slag pushing rack 604 is formed at the bottom of the slag pushing block 603.

In a further embodiment, the slag pushing block conduit 6 is used for restraining the slag pushing block 603 so that the slag pushing block 603 can slide left and right, and the conduit opening 602 is used for exposing the slag pushing rack 604 on the slag pushing block 603 so that the slag pushing gear 605 can be meshed with the slag pushing rack 604.

Specifically, referring to fig. 9, a slag pushing motor 607 is installed on the right side of the support upright post 1, a motor mounting plate 608 is welded on the left side of the slag pushing motor 607, the motor mounting plate 608 is installed on the right side of the support upright post 1 through bolts, a slag pushing motor output shaft 606 is installed at the front end of the slag pushing motor 607, a slag pushing gear 605 is connected to the top end of the slag pushing motor output shaft 606 in an interference fit manner, the slag pushing motor 607 is located below the slag block pushing guide pipe 6, and the slag pushing gear 605 is engaged with the slag pushing rack 604.

In a further embodiment, the slag pushing motor 607 is used for providing power for pushing out the crushed frozen food fragments, the motor mounting plate 608 is used for fixedly mounting the slag pushing motor 607 on the bracket upright post 1, and the slag pushing gear 605 is used for transmitting the torque generated by the slag pushing motor 607 to the slag pushing block 603, so that the rotary motion of the slag pushing motor output shaft 606 is converted into the linear motion of the slag pushing block 603.

Specifically, referring to fig. 2, a cutting track T-shaped groove 405 is formed in the cutting track 402, a cutting edge T-shaped tail 404 is arranged on the cutting edge 403, and the cutting edge T-shaped tail 404 is excessively connected in the cutting track T-shaped groove 405 in a matching manner.

In a further embodiment, the T-shaped channel 405 of the blade track cooperates with the T-shaped tail 404 of the blade to allow the cutting blade 403 to be securely mounted in the cutting blade track 402 and to allow the cutting blade 403 to be removed from the cutting blade track 402 for replacement when necessary.

The working principle of the invention is as follows:

frozen food materials are poured into the crushing bin plates 3, then the rodless cylinder 5 starts to work, the cylinder slide block 503 moves forwards to drive the tool path pushing guide rail 504 and the tool path pushing slide block 505 to move forwards, then the tool path pushing guide rail 504 and the tool path pushing slide block 505 are driven by the tool path push rod 406 to drive the cutting blade 403 on the cutting tool path 402 to cut the frozen food materials, after the cutting tool path 402 rotates into gaps in a plurality of crushing bin plates 3, the rodless cylinder 5 stops working, the slag pushing motor 607 starts to work, the slag pushing block 603 is pushed into the slag pushing arc 302 through the slag pushing rack 604 and the slag pushing gear 605, and the crushed frozen food material is pushed out from the slag pushing port 202, then the slag pushing motor 607 is reversed to reset the slag pushing block 603, the rodless cylinder 5 is reversely operated to reset the knife rail push rod 406, and the steps are repeated to carry out automatic frozen food material crushing work.

Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments or portions thereof without departing from the spirit and scope of the invention.