CN216814706U - Full-automatic cubic ice cutting machine - Google Patents

Abstract

The utility model discloses a full-automatic cubic ice cutting machine which comprises a rack, a sliding plate and an ice loading tool assembly, wherein the rack is provided with a guide rail; the sliding plate is obliquely arranged on the rack through the translation assembly; the sliding plate horizontally moves on the rack through the translation assembly; a first sawing component is arranged at the right end of the middle part of the back surface of the sliding plate; a second sawing component is arranged at the upper part of the back surface of the sliding plate; a third sawing component is arranged at the left end of the middle part of the back surface of the sliding plate; the third sawing component is connected with a discharging slideway; the lower part of the back of the sliding plate is provided with a waste discharging assembly; the ice loading tool assembly is obliquely arranged on the rack through a lifting assembly; the ice loading tool assembly moves up and down on the rack through the lifting assembly; the working surface of the ice loading tool assembly is parallel to the front surface of the sliding plate; the automatic cubic ice cutting machine has the advantages of automatic cutting of ice blocks, high processing efficiency, no need of manual operation, effective reduction of production cost, satisfaction of mass cubic ice production, good economic benefit and contribution to development of enterprises.

Description

Full-automatic cubic ice cutting machine

Technical Field

The utility model relates to the technical field of cutting equipment, in particular to a full-automatic cubic ice cutting machine.

Background

There is no special ice cutter on the existing market for cutting large ice cubes into smaller cubes. When the large cubic ice needs to be cut, a bone sawing machine is mostly utilized, and the bone sawing machine is a vertical band sawing machine meeting the food-grade requirement and is mostly used for cutting meat with bones. When the bone sawing machine is used for cutting ice blocks, large ice blocks are firstly cut into ice boards, then the ice boards are cut into long ice strips, and finally the strip ice strips are cut into small cubes. This method is time-consuming, labor-consuming and inefficient. Cannot meet the production of cubic ice in large batch.

Among foreign products, there is a hand push ice-cube cutting machine, and a row of interval equals the circular saw blade rotation, and the manual work pushes away the ice-cube and advances the ice-cube, and the circular saw blade cuts the ice-cube into a plurality of ice-cube bundles, and the manual work drags back the ice-cube bundle, changes the ice-cube bundle direction, advances the ice-cube bundle and lets the circular saw blade cut once more, and the ice-cube bundle cuts off into the ice cube piece. This kind of mode needs manual operation, and is more time-consuming and laboursome, and efficiency is lower, has also increased the cost of labor simultaneously, is unfavorable for the development of enterprise.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a full-automatic cubic ice cutting machine which can automatically cut ice blocks, has high processing efficiency and effectively reduces the production cost.

The utility model is realized by the following technical scheme:

a fully automated cubic ice cutter comprising:

a machine frame, a plurality of guide rails and a plurality of guide rails,

the sliding plate is obliquely arranged on the rack through a translation assembly; the sliding plate is horizontally moved on the rack through the translation assembly; a first sawing component is arranged at the right end of the middle part of the back surface of the sliding plate; a second sawing component is arranged at the upper part of the back surface of the sliding plate; a third sawing component is arranged at the left end of the middle part of the back surface of the sliding plate; the third sawing component is connected with a discharging slideway; the lower part of the back of the sliding plate is provided with a waste discharging assembly; and the number of the first and second groups,

the ice loading tool assembly is obliquely arranged on the rack through a lifting assembly; the ice loading tool assembly moves up and down on the rack through the lifting assembly; the working face of the ice loading tool assembly is parallel to the front face of the sliding plate.

Further, the translation assembly comprises a translation guide rail, a translation sliding block, a translation chain set and a translation motor; the translation guide rail is provided with two guide rails which are respectively arranged at the top and the bottom of the rack; the sliding plate is slidably mounted on the translation guide rail through the translation sliding block; the translation motor is in transmission connection with the sliding plate through the translation chain set.

Further, the lifting assembly comprises a lifting guide rail, a lifting slide block, a lifting chain group and a lifting motor; the two lifting guide rails are respectively obliquely arranged on the rack; the ice loading tool assembly is arranged on the lifting guide rail in a lifting way through the lifting slide block; the lifting motor is in transmission connection with the ice loading tool assembly through the lifting chain group.

Further, the first sawing assembly comprises a first saw blade group, a first synchronous belt group and a first driving motor; the first saw blade group is longitudinally arranged on the sliding plate; the sliding plate is longitudinally provided with a grid hole; the first saw blade group penetrates from the back surface of the sliding plate to the front surface of the sliding plate through a grid hole; the first driving motor is arranged on the sliding plate; the first driving motor is in transmission connection with the first saw blade group through the first synchronous belt group.

Further, the second sawing assembly comprises a second saw blade group, a second synchronous belt group and a second driving motor; the second saw blade group is transversely arranged on the sliding plate; grid holes are transversely formed in the sliding plate; the first saw blade group penetrates from the back surface of the sliding plate to the front surface of the sliding plate through a grid hole; the second driving motor is arranged on the sliding plate; and the second driving motor is in transmission connection with the second saw blade group through the second synchronous belt group.

Further, the third sawing assembly comprises a third saw blade group, a third synchronous belt group and a third driving motor; a discharge hole is formed in the sliding plate; the third saw blade group penetrates through the discharge hole from the back surface of the sliding plate to the front surface of the sliding plate; the top surface of the third saw blade group protrudes out of the plane of the sliding plate; the third driving motor is arranged on the sliding plate; and the third driving motor is in transmission connection with the third saw blade group through the third synchronous belt group.

Further, the surplus material discharging assembly comprises a turning plate, a turning assembly and a turning cylinder; the sliding plate is provided with a square hole; the overturning assembly and the overturning air cylinder are respectively arranged on the sliding plate; the turning plate is rotatably arranged on the turning component; the turnover cylinder drives the turnover plate to rotatably cover the square hole through the turnover assembly.

Further, the ice loading tool assembly comprises a clamping table, a clamping table bottom plate, a clamping table bottom cylinder, a clamping plate and a clamping cylinder; the clamping table is provided with two ice inlets; the clamping table bottom plate is rotatably arranged on the clamping table; the clamping table bottom air cylinder is arranged at the bottom of the clamping table; a piston rod of the cylinder at the bottom of the clamping table is connected with the bottom of the bottom plate of the clamping table; the clamping cylinders are symmetrically arranged on the left side and the right side of the clamping table; the clamping plate is connected with a piston rod of the clamping cylinder; and a photoelectric sensor assembly is arranged above the clamping plate.

Furthermore, a plurality of parallel round bars are arranged on the discharging slide way; a first organ cover is arranged on the translation assembly; and a second organ cover is arranged on the lifting component.

Furthermore, an electric box is mounted on the side wall of the rack; and the upper end and the lower end of the rack are respectively provided with a vertical hard limiting component.

The utility model has the beneficial effects that:

according to the ice cube discharging device, the sliding plate and the ice containing tool assembly are obliquely arranged on the rack, so that ice cubes can automatically cling to the sliding plate, and meanwhile, excess materials and finished products can be automatically discharged from the ice cubes; the first saw cutting assembly and the second saw cutting assembly are respectively used for grooving the ice blocks to be processed, and the third saw cutting assembly is arranged to cut the ice blocks to be processed, so that the ice blocks to be processed are automatically cut into cubic ice blocks, the surplus material discharging assembly is arranged to automatically discharge surplus materials of the ice blocks to be processed, and the ice loading tool assembly is arranged to automatically clamp the ice blocks to be processed; the automatic cubic ice cutting machine has the advantages of automatic cutting of ice blocks, high processing efficiency, no need of manual operation, effective reduction of production cost, satisfaction of mass cubic ice production, good economic benefit and contribution to development of enterprises.

Drawings

FIG. 1 is a schematic diagram of the back overall structure of a fully automatic cubic ice cutter according to an embodiment of the present invention;

FIG. 2 is a schematic front view of the full-automatic cubic ice cutter according to the embodiment of the present invention;

FIG. 3 is a schematic side view of the full-automatic cubic ice cutter according to the embodiment of the present invention;

FIG. 4 is a front view of a sled mounted sawing assembly according to an embodiment of the present invention;

FIG. 5 is a schematic view of the rear side of the sawing assembly mounted on the sled according to the embodiment of the present invention;

FIG. 6 is a schematic perspective view of an overall structure of an ice loading fixture assembly according to an embodiment of the present invention;

fig. 7 is a schematic perspective view of the ice loading assembly according to the second embodiment of the present invention.

In the drawings: 1-a frame; 2, sliding plates; 3-a translation assembly; 4-a discharge chute; 5-an ice loading tool assembly; 6-a lifting assembly; 7-an electric box; 8-vertical hard limit component; 21-a first sawing assembly; 22-a second sawing assembly; 23-a third sawing assembly; 24-a residue discharge assembly; 25-a discharge port; 26-square holes; 31-a translation guide; 32-a translation slide; 33-translational chain set; 34-a translation motor; 35-a first organ cover; 41-parallel round bars; 51-a clamping table; 52-clamping table bottom plate; 53-clamping table bottom cylinder; 54-clamping the plate; 55-clamping cylinder; 56-a photosensor assembly; 61-lifting guide rails; 62-lifting slide block; 63-lifting chain group; 64-a lift motor; 65-a second organ cover; 211-a first group of saw blades; 212-a first set of synchronization bands; 213-a first drive motor; 221-a second group of saw blades; 222-a second set of sync strips; 223-a second drive motor; 231-a third group of saw blades; 232-a third set of synchronization bands; 233-a third drive motor; 241-turning plate; 242-flip assembly; 243-overturn cylinder.

Detailed Description

The utility model will be described in detail with reference to the drawings and specific embodiments, which are illustrative of the utility model and are not to be construed as limiting the utility model.

It should be noted that all the directional indications (such as up, down, left, right, front, back, upper end, lower end, top, bottom … …) in the embodiments of the present invention are only used to explain the relative position relationship between the components, the movement situation, etc. in a specific posture (as shown in the drawings), and if the specific posture is changed, the directional indication is changed accordingly.

In the present invention, unless expressly stated or limited otherwise, the term "coupled" is to be interpreted broadly, e.g., "coupled" may be fixedly coupled, detachably coupled, or integrally formed; can be mechanically or electrically connected; they may be directly connected or indirectly connected through intervening media, or they may be connected internally or in any other suitable relationship, unless expressly stated otherwise. The specific meanings of the above terms in the present invention can be understood according to specific situations by those of ordinary skill in the art.

In addition, the descriptions related to "first", "second", etc. in the present invention are only for descriptive purposes and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature; in addition, technical solutions between various embodiments may be combined with each other, but must be realized by a person skilled in the art, and when the technical solutions are contradictory or cannot be realized, such a combination should not be considered to exist, and is not within the protection scope of the present invention.

Referring to fig. 1 to 7, a fully automatic cubic ice cutter includes:

the machine frame (1) is provided with a frame,

the sliding plate 2 is obliquely arranged on the rack 1 through a translation assembly 3; the sliding plate 2 is horizontally moved on the frame 1 through the translation assembly 3; a first sawing component 21 is arranged at the right end of the middle part of the back surface of the sliding plate 2; the upper part of the back surface of the sliding plate 2 is provided with a second sawing assembly 22; a third sawing component 23 is arranged at the left end of the middle part of the back surface of the sliding plate 2; the third sawing component 23 is connected with a discharging slideway 4; the lower part of the back of the sliding plate 2 is provided with a waste discharging assembly 24; the ice loading tooling assembly 5 is obliquely arranged on the rack 1 through a lifting assembly 6; the ice loading tool assembly 5 moves up and down on the rack 1 through the lifting assembly 6; the working face of the ice loading tool assembly 5 is parallel to the front face of the sliding plate 2. It should be noted that, the sliding plate 2 and the ice containing tool assembly 5 are obliquely arranged on the frame 1, so that ice cubes can automatically cling to the sliding plate 2, and meanwhile, the ice cubes can automatically discharge excess materials and finished products; the automatic ice cube cutting machine has the advantages that the automatic ice cube cutting machine is used for automatically cutting ice cubes, the production cost is effectively reduced, the mass production of cubic ice cubes is met, the economic benefit is good, and the development of enterprises is facilitated.

Specifically, in this embodiment, the translation assembly 3 includes a translation guide rail 31, a translation slider 32, a translation chain group 33, and a translation motor 34; the translation guide rail 31 is provided with two rails which are respectively arranged at the top and the bottom of the rack 1; the sliding plate 2 is slidably mounted on the translation guide rail 31 through the translation sliding block 32; the translation motor 34 is in transmission connection with the slide plate 2 through the translation chain set 33. It should be noted that the sliding plate 2 moves left and right on the rack 1 by arranging the translation assembly 3; the translation motor 34 works and pulls the sliding plate 2 to move left and right through the transmission of the translation chain set 33.

Specifically, in this embodiment, the lifting assembly 6 includes a lifting guide rail 61, a lifting slider 62, a lifting chain group 63, and a lifting motor 64; the two lifting guide rails 61 are respectively installed on the rack 1 in an inclined manner; the ice loading tool assembly 5 is arranged on the lifting guide rail 61 in a lifting way through the lifting slide block 62; the lifting motor 64 is in transmission connection with the ice loading tool assembly 5 through the lifting chain group 63. It should be noted that the lifting assembly 6 is arranged to realize the lifting movement of the ice loading tooling assembly 5 on the frame 1; the lifting motor 64 works and pulls the ice loading tooling assembly 5 to move up and down through the transmission of the lifting chain group 63.

It should be noted that the rack 1 provides a mounting base for each component. The installation base surfaces of the translation guide rail 31 and the lifting guide rail 61 provided by the frame 1 form the same angle with the vertical surface, so that the installation base surfaces of the translation guide rail 31 and the lifting guide rail 61 are inclined and kept parallel to each other.

Specifically, in this embodiment, the first sawing assembly 21 includes a first saw blade group 211, a first synchronous belt group 212, and a first driving motor 213; the first saw blade group 211 is longitudinally arranged on the sliding plate 2; the sliding plate 2 is longitudinally provided with a grid hole; the first saw blade group 211 penetrates through the back surface of the sliding plate 2 to the front surface of the sliding plate 2 through the grid holes; the first driving motor 213 is installed on the slide plate 2; the first driving motor 213 is in transmission connection with the first saw blade group 211 through the first synchronous belt group 212. It should be noted that, according to the ice cubes to be processed with different sizes, the cutting distance of the first saw blade group 211 can be adjusted, specifically, the number of the saw blades of the first saw blade group 211 is adjusted, so that the ice cubes to be processed with different sizes can be cut.

Specifically, in this embodiment, the second sawing assembly 22 includes a second saw blade group 221, a second synchronous belt group 222, and a second driving motor 223; the second saw blade group 221 is transversely arranged on the sliding plate 2; grid holes are transversely arranged on the sliding plate 2; the first saw blade group 211 penetrates through the back surface of the sliding plate 2 to the front surface of the sliding plate 2 through the grid holes; the second driving motor 223 is installed on the slide plate 2; the second driving motor 223 is in transmission connection with the second saw blade group 221 through the second synchronous belt group 222. It should be noted that, according to the ice cubes to be processed with different sizes, the cutting distance of the second saw blade group 221 can be adjusted, specifically, the number of the saw blades of the second saw blade group 221 is adjusted, so that the ice cubes to be processed with different sizes can be cut.

Specifically, in this embodiment, the third sawing assembly 23 includes a third blade group 231, a third timing belt group 232, and a third driving motor 233; the sliding plate 2 is provided with a discharge hole 25; the third saw blade group 231 penetrates through the discharge hole 25 from the back of the sliding plate 2 to the front of the sliding plate 2; the top surface of the third saw blade group 231 protrudes out of the plane of the sliding plate 2; the third driving motor 233 is installed on the slide plate 2; the third driving motor 233 is in transmission connection with the third saw blade group 231 through the third synchronous belt group 232. It should be noted that, only one end of the third blade group 231 is provided with a blade, and the third blade group 231 passes through the material outlet 25 of the sliding plate 2, so that the top surface of the blade is higher than the plane of the sliding plate 2, and the gap between the blade and the sliding plate 2 is the maximum thickness of ice cut by the cutting machine.

Specifically, in this embodiment, the surplus material discharging assembly 24 includes a turning plate 241, an overturning assembly 242, and an overturning cylinder 243; a square hole 26 is formed in the sliding plate 2; the overturning assembly 242 and the overturning cylinder 243 are respectively mounted on the sliding plate 2; the turning plate 241 is rotatably mounted on the turning component 242; the overturning air cylinder 243 drives the overturning plate 241 to rotatably cover the square hole 26 through the overturning component 242. It should be noted that, when idle, turn over board 241 and close on square hole 26, mend the slide 2 and tie up, when detecting that the clout ice-cube is not pressed from both sides inadequately on the dress ice frock subassembly 5, upset cylinder 243 work promotes to turn over board 241 and rotates 90, turn over board 241 face and dress ice frock subassembly 5 bottom surface coplanar this moment, this face has inclination with relative horizontal plane, constitute and arrange the clout passageway, dress ice frock subassembly 5 loosens the ice-cube that waits to process that the surplus is not enough, under the effect of gravity, the clout slides out to the clout conveyer line outside the ice-cutting machine from turning over board 241.

Specifically, in the scheme of this embodiment, the ice loading tooling assembly 5 includes a clamping table 51, a clamping table bottom plate 52, a clamping table bottom cylinder 53, a clamping plate 54 and a clamping cylinder 55; the clamping table 51 is provided with two ice inlets; the clamping table bottom plate 52 is rotatably arranged on the clamping table 51; the clamping table bottom air cylinder 53 is arranged at the bottom of the clamping table 51; a piston rod of the clamping table bottom air cylinder 53 is connected with the bottom of the clamping table bottom plate 52; the clamping cylinders 55 are symmetrically arranged at the left side and the right side of the clamping table 51; the clamping plate 54 is connected with a piston rod of the clamping cylinder 55; a photoelectric sensor assembly 56 is arranged above the clamping plate 54. It should be noted that two ice inlets on the clamping table 51 receive ice cubes to be processed which are automatically pushed from the outside of the ice cutting device. After the ice blocks to be processed are pushed into the ice inlet, the cylinder 53 at the bottom of the clamping table props against the bottom plate 52 of the clamping table to rotate upwards, the bottom plate 52 of the clamping table inclines with the horizontal plane, the ice blocks automatically slide to enable the inner ends of the ice blocks to be attached to the sliding plate 2, and the clamping cylinder 55 works to drive the clamping plate 54 to clamp the ice blocks to be processed.

Specifically, in the embodiment, a plurality of parallel round rods 41 are arranged on the discharging chute 4. A first organ cover 35 is arranged on the translation assembly 3; a second organ cover 65 is arranged on the lifting component 6. It should be noted that after the ice to be processed is cut off at the third sawing assembly 23, the small cubic ice slides onto the discharging slideway 4 through the discharging port 25, the discharging slideway 4 is provided with a slideway composed of parallel round rods 41, and crushed ice, small ice blocks and the like are separated through the parallel round rods 41. And qualified finished cubic ice is collected at the tail end of the discharging slideway 4. It should be noted that, by arranging the first organ cover 35 and the second organ cover 65 to isolate the guide rail from the production environment, pollutants generated by long-term abrasion of the guide rail are prevented from floating around.

Specifically, in the present embodiment, an electrical box 7 is installed on a side wall of the rack 1; vertical hard limiting assemblies 8 are respectively arranged at the upper end and the lower end of the rack 1. It should be noted that the electrical box 7 is arranged to ensure power supply of each component on the rack 1, and ensure normal operation of the equipment. The lifting motion of the ice loading tool assembly 5 is limited by arranging the vertical hard limiting assembly 8.

Specifically, the working process of the utility model is as follows: (1) the machine is started, the first saw blade group 211, the second saw blade group 221 and the third saw blade group 231 rotate simultaneously, (2) an external machine pushes ice cubes to be processed to the clamping table 51, after the clamping table 51 detects that the ice cubes to be processed are in place through the photoelectric sensor assembly 56, (3) the cylinder 53 at the bottom of the clamping table props against the bottom plate 52 of the clamping table to rotate upwards, the bottom plate 52 of the clamping table inclines with the horizontal plane, the ice cubes to be processed automatically slide to enable the inner ends of the ice cubes to be attached to the sliding plate 2, the clamping table 51 clamps the ice cubes to be processed, (4) the lifting motor 64 drives the clamping table 51 to move upwards for a certain distance, the inner ends of the ice cubes are cut into cutting grooves in the vertical direction by the first saw blade group 211, (5) the translation motor 34 drives the sliding plate 2 to move leftwards for a certain distance, the inner ends of the ice cubes are cut into cutting grooves in the left and right directions by the second saw blade group 221, (6) the lifting motor 64 drives the clamping table 51 to move downwards for a certain distance, the inner end of the ice block is cut and separated into the cubic ice block, the cubic ice block falls off and slides to the discharging slide way 4 through the discharging port 25, the discharging slide way 4 is provided with a slide way formed by parallel round rods 41, and crushed ice, small ice blocks and the like are separated through the parallel round rods 41. And qualified finished cubic ice is collected at the tail end of the discharging slideway 4. (7) The translation motor 34 drives the sliding plate 2 to move rightwards for a certain distance, the clamping table 51 returns to the initial position, a cycle is completed until the clamping table 51 detects that the ice cake excess material is not clamped stably enough, the turning plate 241 is turned over, the clamping table 51 loosens the rest ice cake to be processed, the excess material is automatically discharged, the cylinder 53 at the bottom of the clamping table retracts, the bottom plate 52 of the clamping table rotates downwards to be horizontal, and the clamping table 51 is in a state of waiting for receiving the ice cake at the moment.

The technical solutions provided by the embodiments of the present invention are described in detail above, and the principles and embodiments of the present invention are explained herein by using specific examples, and the descriptions of the embodiments are only used to help understanding the principles of the embodiments of the present invention; meanwhile, for a person skilled in the art, according to the embodiments of the present invention, there may be variations in the specific implementation manners and application ranges, and in summary, the content of the present description should not be construed as a limitation to the present invention.

Claims (10)

1. A fully automated cubic ice cutter, comprising:

a machine frame, a plurality of guide rails and a plurality of guide rails,

the sliding plate is obliquely arranged on the rack through a translation assembly; the sliding plate is horizontally moved on the rack through the translation assembly; a first sawing component is arranged at the right end of the middle part of the back surface of the sliding plate; a second sawing component is arranged at the upper part of the back surface of the sliding plate; a third sawing component is arranged at the left end of the middle part of the back surface of the sliding plate; the third sawing component is connected with a discharging slideway; the lower part of the back of the sliding plate is provided with a waste discharging assembly; and the number of the first and second groups,

the ice loading tool assembly is obliquely arranged on the rack through a lifting assembly; the ice loading tool assembly moves up and down on the rack through a lifting assembly; the working face of the ice loading tool assembly is parallel to the front face of the sliding plate.

2. A fully automated cubic ice cutter according to claim 1, wherein: the translation assembly comprises a translation guide rail, a translation sliding block, a translation chain set and a translation motor; the translation guide rail is provided with two rails which are respectively arranged at the top and the bottom of the rack; the sliding plate is slidably mounted on the translation guide rail through the translation sliding block; the translation motor is in transmission connection with the sliding plate through the translation chain set.

3. The fully automatic cubic ice cutter according to claim 1, wherein: the lifting assembly comprises a lifting guide rail, a lifting slide block, a lifting chain group and a lifting motor; the two lifting guide rails are respectively obliquely arranged on the rack; the ice loading tool assembly is arranged on the lifting guide rail in a lifting way through the lifting slide block; the lifting motor is in transmission connection with the ice loading tool assembly through the lifting chain group.

4. The fully automatic cubic ice cutter according to claim 1, wherein: the first sawing assembly comprises a first saw blade group, a first synchronous belt group and a first driving motor; the first saw blade group is longitudinally arranged on the sliding plate; the sliding plate is longitudinally provided with a grid hole; the first saw blade group penetrates from the back surface of the sliding plate to the front surface of the sliding plate through a grid hole; the first driving motor is arranged on the sliding plate; the first driving motor is in transmission connection with the first saw blade group through the first synchronous belt group.

5. The fully automatic cubic ice cutter according to claim 4, wherein: the second sawing assembly comprises a second saw blade group, a second synchronous belt group and a second driving motor; the second saw blade group is transversely arranged on the sliding plate; grid holes are transversely formed in the sliding plate; the first saw blade group penetrates from the back surface of the sliding plate to the front surface of the sliding plate through a grid hole; the second driving motor is arranged on the sliding plate; and the second driving motor is in transmission connection with the second saw blade group through the second synchronous belt group.

6. The fully automatic cubic ice cutter according to claim 5, wherein: the third sawing assembly comprises a third saw blade group, a third synchronous belt group and a third driving motor; a discharge hole is formed in the sliding plate; the third saw blade group penetrates through the discharge hole from the back surface of the sliding plate to the front surface of the sliding plate; the top surface of the third saw blade group protrudes out of the plane of the sliding plate; the third driving motor is arranged on the sliding plate; and the third driving motor is in transmission connection with the third saw blade group through the third synchronous belt group.

7. The fully automatic cubic ice cutter according to claim 1, wherein: the excess material discharging assembly comprises a turning plate, a turning assembly and a turning cylinder; the sliding plate is provided with a square hole; the overturning assembly and the overturning air cylinder are respectively arranged on the sliding plate; the turning plate is rotatably arranged on the turning component; the turnover cylinder drives the turnover plate to rotatably cover the square hole through the turnover assembly.

8. The fully automatic cubic ice cutter according to claim 1, wherein: the ice loading tool assembly comprises a clamping table, a clamping table bottom plate, a clamping table bottom cylinder, a clamping plate and a clamping cylinder; the clamping table is provided with two ice inlets; the clamping table bottom plate is rotatably arranged on the clamping table; the clamping table bottom air cylinder is arranged at the bottom of the clamping table; a piston rod of the cylinder at the bottom of the clamping table is connected with the bottom of the bottom plate of the clamping table; the clamping cylinders are symmetrically arranged on the left side and the right side of the clamping table; the clamping plate is connected with a piston rod of the clamping cylinder; and a photoelectric sensor assembly is arranged above the clamping plate.

9. The fully automatic cubic ice cutter according to claim 1, wherein: a plurality of parallel round bars are arranged on the discharging slideway; a first organ cover is arranged on the translation assembly; and a second organ cover is arranged on the lifting component.

10. The fully automatic cubic ice cutter according to claim 1, wherein: an electric box is mounted on the side wall of the rack; and the upper end and the lower end of the rack are respectively provided with a vertical hard limiting component.

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