A slicing machine for food production and processing

By introducing spacing and angle adjustment components into the food slicing equipment, the problems of cumbersome and inaccurate blade thickness and angle adjustment in traditional equipment are solved, enabling fast and precise adjustment of slicing thickness and angle, and improving slicing efficiency and consistency of finished product specifications.

CN224407840UActive Publication Date: 2026-06-26WEIHAI MINGHUI AQUATIC FOOD CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
WEIHAI MINGHUI AQUATIC FOOD CO LTD
Filing Date
2025-08-11
Publication Date
2026-06-26

AI Technical Summary

Technical Problem

Existing food slicing equipment mostly adopts a fixed blade structure. The slicing thickness adjustment requires manual replacement of shims or adjustment of mechanical limits, which is cumbersome and has limited precision. For food raw materials of different materials, traditional equipment cannot simultaneously meet the dual adjustment requirements of slicing thickness and angle, resulting in low slicing efficiency and inconsistent finished product specifications. The angle adjustment mechanism mostly adopts bolt locking method, which is time-consuming and labor-intensive to operate.

Method used

It employs a spacing adjustment component and an angle adjustment component. The spacing adjustment component achieves rapid and precise adjustment of the blade spacing through a first lead screw and gear, while the angle adjustment component achieves rapid locking of the blade angle through the cooperation structure of the annular plug and slot. Combined with a scale and dial, it provides intuitive display and precise adjustment.

Benefits of technology

It enables rapid and precise adjustment of blade spacing and angle, improves the efficiency and accuracy of slicing thickness and angle adjustment, ensures the consistency of slicing specifications, makes operation more convenient and reliable, and improves the production efficiency and product quality of food processing.

✦ Generated by Eureka AI based on patent content.

Smart Images

  • Figure CN224407840U_ABST
    Figure CN224407840U_ABST
Patent Text Reader

Abstract

The utility model relates to food production and processing technical field, and disclose a food production and processing is with slicing machine, including operation platform, a plurality of blade and moving frame, and fixedly connected with the box body between moving frame, and the spacing adjustment subassembly is connected with the blade in the box body, the utility model discloses the quick accurate adjustment of blade spacing is realized through spacing adjustment subassembly, just need to drive the exposed gear to can drive the synchronous movement of blade, and the intuitive display adjustment amount of cooperation scale table, simple operation has improved the regulation efficiency and precision of the slice thickness, angle adjustment subassembly adopts the cooperation structure of annular plug-in rod and slot, just need to rotate ring body to can realize the quick locking of blade angle, compared with the operation of traditional bolt locking mode is more convenient and reliable, can satisfy the slicing demand of different hardness food material, can also realize the quick regulation of slicing angle, guarantees the consistency of slicing specification, and time -saving and labour -saving operation, food processing production efficiency and product quality have been improved greatly.
Need to check novelty before this filing date? Find Prior Art

Description

Technical Field

[0001] This utility model relates to the field of food production and processing technology, specifically to a food slicing machine. Background Technology

[0002] Food slicing machines are key pieces of equipment in modern food processing, widely used for the standardized cutting of products such as meat, vegetables, fruits, and bread. Through precision blades or high-speed rotating devices, they achieve efficient and uniform slicing, improving production efficiency and product consistency.

[0003] Currently, most commonly used food slicing equipment adopts a fixed blade structure. The slicing thickness adjustment requires manual replacement of shims or adjustment of mechanical limits, which is cumbersome and has limited precision. For food raw materials of different materials (such as frozen meat, soft fruits and vegetables, etc.), traditional equipment often cannot meet the dual adjustment requirements of slicing thickness and angle at the same time, resulting in low slicing efficiency and inconsistent finished product specifications. The angle adjustment mechanism mostly adopts the bolt locking method, which requires repeated tightening and loosening of bolts during adjustment, which is time-consuming and labor-intensive. Therefore, a slicing machine for food production and processing is proposed. Utility Model Content

[0004] The purpose of this utility model is to provide a food slicing machine to solve the problems mentioned in the background art. Currently, most commonly used food slicing equipment adopts a fixed blade structure, and the slicing thickness adjustment requires manual replacement of shims or adjustment of mechanical limits, which is cumbersome and has limited precision. For food raw materials of different materials (such as frozen meat, soft fruits and vegetables, etc.), traditional equipment often cannot simultaneously meet the dual adjustment requirements of slicing thickness and angle, resulting in low slicing efficiency and inconsistent finished product specifications. The angle adjustment mechanism mostly adopts a bolt locking method, which requires repeated tightening and loosening of bolts during adjustment, which is time-consuming and labor-intensive.

[0005] To achieve the above objectives, this utility model provides the following technical solution: a food processing slicer, comprising an operating table, several blades and a movable frame, wherein a housing is fixedly connected between the movable frames, and the housing is connected to the blades through a spacing adjustment component, and an angle adjustment component is provided on the top of the blades;

[0006] The spacing adjustment assembly includes a first lead screw and a gear. The two sides of the gear are fixedly connected to a connecting frame via bearings. The connecting frame is slidably connected inside the housing. A rubber block is fixedly connected to the bottom of the connecting frame.

[0007] The angle adjustment assembly includes a cylindrical body, inside which a rotating block is movably inserted. The bottom of the rotating block is fixedly connected to a blade by bolts. A ring body is sleeved on the outside of the cylindrical body. The bottom of the ring body is provided with an annular insert rod. The annular insert rod slides radially along the cylindrical body via a slide rail. Several insert rods are evenly fixedly connected to the bottom of the annular insert rod. The top of the rotating block is evenly provided with matching slots.

[0008] Preferably, a first through groove is provided on one side of the box body, and a second through groove adapted to the rubber block is provided at the bottom of the box body.

[0009] Preferably, an annular slider is fixedly connected to the inner wall of the cylinder, and an annular groove adapted to the annular slider is provided on the outer side of the rotating block.

[0010] Preferably, a scale is provided on one side of the aforementioned housing, and the cross-section of the annular slider is T-shaped.

[0011] Preferably, the surface of the cylinder is provided with a scale, and the top of the cylinder is fixedly connected to the bottom of the rubber block.

[0012] Preferably, the outer side of the cylinder is provided with an external thread, the inside of the ring is provided with a matching internal thread, and the ring is rotatably connected to the top of the annular insert rod via an annular guide rail.

[0013] Preferably, a three-phase asynchronous geared motor is installed on one side of the aforementioned operating table, and a second lead screw is fixedly connected to the output end of the three-phase asynchronous geared motor. The bottom of the movable frame is provided with a threaded hole that matches the second lead screw, and the movable frame is slidably connected to the top of the operating table.

[0014] Preferably, the bottom of the aforementioned operating table is fixedly connected to two guide rods, and two guide holes adapted to the guide rods are opened on one side of the movable frame.

[0015] Compared with the prior art, the present invention, by adopting the above technical solution, has the following technical effects:

[0016] This invention achieves rapid and precise adjustment of blade spacing through a spacing adjustment component. Simply pushing the exposed gear moves the blades synchronously, and the adjustment amount is displayed intuitively on the scale. The operation is simple, improving the efficiency and accuracy of slicing thickness adjustment. The angle adjustment component adopts a matching structure of a ring rod and a slot. Simply rotating the ring body can quickly lock the blade angle. Compared with the traditional bolt locking method, the operation is more convenient and reliable. It can meet the slicing needs of ingredients with different hardness and achieve rapid adjustment of slicing angle, ensuring the consistency of slicing specifications. The operation is time-saving and labor-saving, greatly improving the production efficiency and product quality of food processing. Attached Figure Description

[0017] To more clearly illustrate the technical solutions in the embodiments of this application or the prior art, the drawings used in the description of the embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this application. 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 connecting frame structure in an exploded state according to this utility model;

[0019] Figure 2 This is a schematic diagram of the cross-sectional structure of the box body of this utility model;

[0020] Figure 3 for Figure 2 A magnified structural diagram of area A;

[0021] Figure 4 This is a schematic diagram of the connecting frame structure of this utility model;

[0022] Figure 5 This is a schematic diagram of the operating table structure of this utility model;

[0023] Figure 6 This is a schematic diagram of the operating console of this utility model from another perspective.

[0024] Explanation of reference numerals in the attached drawings: 1. Operating table; 2. Moving frame; 3. Box body; 4. Blade; 5. Spacing adjustment assembly; 51. First lead screw; 52. Gear; 53. Scale; 54. First through slot; 55. Second through slot; 56. Connecting frame; 57. Rubber block; 6. Angle adjustment assembly; 61. Cylinder; 62. Rotating block; 63. Annular slider; 64. Annular groove; 65. Ring body; 66. Annular insert rod; 67. Slot; 68. External thread; 69. Scale; 7. Three-phase asynchronous geared motor; 8. Second lead screw; 9. Guide rod; 10. Guide hole. Detailed Implementation

[0025] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.

[0026] It should be noted that the structures, proportions, sizes, etc., shown in the accompanying drawings of this specification are only for the purpose of assisting those skilled in the art in understanding and reading the content disclosed in the specification, and are not intended to limit the conditions under which this application can be implemented. Therefore, they have no substantial technical significance. Any modifications to the structure, changes in the proportions, or adjustments to the size should still fall within the scope of the technical content disclosed in this application, provided that they do not affect the effects and purposes that this application can produce.

[0027] Example 1

[0028] In the current technology, most commonly used food slicing equipment adopts a fixed blade structure. The slicing thickness adjustment requires manual replacement of shims or adjustment of mechanical limits, which is cumbersome and has limited precision. For food raw materials of different materials (such as frozen meat, soft fruits and vegetables, etc.), traditional equipment often cannot meet the dual adjustment requirements of slicing thickness and angle at the same time, resulting in low slicing efficiency and inconsistent finished product specifications. The angle adjustment mechanism mostly adopts the bolt locking method, which requires repeated tightening and loosening of bolts during adjustment, which is time-consuming and labor-intensive.

[0029] Please see Figure 1-6 This utility model provides a technical solution: a slicing machine for food production and processing, including an operating table 1, several blades 4, and a movable frame 2. The blades 4 are made of 420J2 stainless steel with a hardness of HRC52-55. A housing 3 is fixedly connected between the movable frames 2. The housing 3 is connected to the blades 4 through a spacing adjustment component 5. A scale 53 is provided on one side of the housing 3, which allows for precise adjustment of the spacing between the blades 4. An angle adjustment component 6 is provided on the top of the blades 4. A three-phase asynchronous geared motor 7 is installed on one side of the operating table 1. The output end is fixedly connected to the second lead screw 8. The bottom of the movable frame 2 is provided with a threaded hole that matches the second lead screw 8. The movable frame 2 is slidably connected to the top of the operating table 1. When the three-phase asynchronous geared motor 7 drives the second lead screw 8 to rotate, the movable frame 2 moves back and forth relative to the operating table 1. The blade 4 slices the food placed on the surface of the operating table 1. The bottom of the operating table 1 is fixedly connected to two guide rods 9. Two guide holes 10 that match the guide rods 9 are opened on one side of the movable frame 2. When the movable frame 2 moves relative to the operating table 1, the guide rods 9 guide the movable frame 2.

[0030] The spacing adjustment component 5 includes a first lead screw 51 and a gear 52. A connecting frame 56 is fixedly connected to both sides of the gear 52 via bearings. The connecting frame 56 is slidably connected inside the housing 3. A rubber block 57 is fixedly connected to the bottom of the connecting frame 56. A first through groove 54 is provided on one side of the housing 3. A second through groove 55 adapted to the rubber block 57 is provided on the bottom of the housing 3. The rubber block 57 slides in the second through groove 55. The width of the second through groove 55 is 0.1-0.3 mm larger than that of the rubber block 57. The scale 53 is marked in millimeters, and the minimum graduation value is 0.5 mm.

[0031] The working principle or structural principle is as follows: During operation, the precise spacing of the blades 4 is adjusted via the spacing adjustment component 5. A portion of the gear 52 is exposed through the first through slot 54. When the gear 52 is manually pushed up and down, it is linked to the first lead screw 51 via a coupling. The connecting frame 56 slides within the housing 3, moving the blades 4 laterally along with the gear 52. The scale 53 makes the distance of the blades 4's displacement more precise and intuitive. After adjustment, the three-phase asynchronous geared motor 7 is started to drive the second lead screw 8 to rotate, causing the moving frame 2 to move horizontally along the guide rod 9. The blades 4 then slice the food evenly. The spur gear push-pull adjustment structure of the gear 52 simplifies traditional knob operation and, combined with the scale 53, achieves rapid and precise positioning. The three-phase asynchronous geared motor 7 is a model CLJSJ-CH02 manufactured by Kunshan Taiya Electromechanical Technology Co., Ltd. Since the structure and operating principle of this model are existing technologies, their details will not be elaborated here. Telescopic dust covers are installed on the outside of both the first lead screw 51 and the second lead screw 8, with both ends sealed and fixed. Lubrication interfaces are also provided for regular replenishment of grease.

[0032] Example 2

[0033] The angle adjustment assembly 6 includes a cylinder 61, inside which a rotating block 62 is movably inserted. The bottom of the rotating block 62 is fixedly connected to the blade 4 by bolts. A ring 65 is sleeved on the outside of the cylinder 61. The bottom of the ring 65 is provided with an annular insert rod 66, which slides axially along the cylinder 61 via a slide rail. The ring 65 is rotatably connected to the top of the annular insert rod 66 via an axially limiting annular guide rail. Several insert rods are evenly fixedly connected to the bottom of the annular insert rod 66. The top of the rotating block 62 is evenly provided with matching slots 67. Inside the cylinder 61... An annular slider 63 is fixedly connected to the side wall. An annular groove 64 adapted to the annular slider 63 is opened on the outer side of the rotating block 62. The rotating block 62 rotates inside the cylinder 61. The cross-section of the annular slider 63 is T-shaped. The T-shaped slider-groove cooperation forms an axial bidirectional mechanical limit, so that the rotating block 62 can only rotate inside the cylinder 61 and cannot be axially dislodged. A scale 69 is provided on the surface of the cylinder 61. The top of the cylinder 61 is fixedly connected to the bottom of the rubber block 57. The scale 69 makes the rotation of the rotating block 62 inside the cylinder 61 more accurate and intuitive. The outer side of the cylinder 61 is provided with an external thread 68, and the inner side of the ring 65 is provided with a matching internal thread. The ring 65 is rotatably connected to the top of the annular insert rod 66 through an annular guide rail. When the ring 65 rotates on the outside of the cylinder 61, the ring 65 drives the annular insert rod 66 to move up and down relative to the cylinder 61, inserting the insert rod 66 into the slot 67, thereby fixing the rotation position of the rotating block 62. There are twelve insert rods and twelve slots 67. Each rotation is offset by one insert tooth, and the rotating block 62 rotates 30 degrees, which is more precise.

[0034] The working principle or structural principle is as follows: Hold the rotating block 62 above the blade 4 and rotate it through the annular groove 64 and the T-shaped annular slider 63 inside the cylinder 61. Rotate the ring body 65 counterclockwise to raise the insertion rod. Rotate the rotating block 62 to the target angle, and rotate the ring body 65 clockwise to lock it. Rotate it to the required angle according to the scale 69. Then rotate the ring body 65 (moving along the axis of the cylinder 61 through the external thread 68) to drive the annular insertion rod 66 to press down along the slide rail, so that the insertion rod of the annular insertion rod 66 is accurately inserted into the twelve equally divided slots 67 at the top of the rotating block 62 (each misalignment corresponds to 30° adjustment). The rotating block 62 is locked, and the angle of the blade 4 is fixed. The threaded drive insertion structure of the ring body 65 can complete the angle adjustment and mechanical locking with a single rotation. With the help of the scale 69, ±30° indexing positioning is achieved to ensure the accuracy and efficiency of the oblique cutting operation. The power supply of the three-phase asynchronous geared motor must be disconnected before the adjustment operation.

[0035] In summary, the spacing adjustment component 5 enables precise lateral adjustment of the blade 4: manually pushing the exposed gear 52 drives the connecting bracket 56 to slide, and the scale 53 displays the spacing intuitively; when adjusting the angle, rotating the rotating block 62 (which cooperates with the T-shaped annular slider 63 through the annular groove 64) to the specified angle on the scale 69, and rotating the ring body 65 causes the annular insert 66 to press down and insert into the twelve equally divided slots 67 (30° per tooth) of the rotating block 62 to achieve quick locking. The gear 52's direct-push spacing adjustment and the ring body 65's threaded angle locking structure take into account both ease of operation and indexing accuracy, ensuring slice uniformity and oblique cutting efficiency.

[0036] Those skilled in the art will understand that the features described in the various embodiments and / or claims of this utility model can be combined or combined in various ways, even if such combinations or combinations are not explicitly described in this utility model. In particular, the features described in the various embodiments and / or claims of this utility model can be combined or combined in various ways without departing from the spirit and teachings of this utility model. All such combinations and / or combinations fall within the scope of this utility model.

Claims

1. A food production processing slicer comprising an operating table (1), a plurality of blades (4) and a moving frame (2), characterized in that, The movable frames (2) are fixedly connected to each other by a housing (3). The housing (3) is connected to the blade (4) through a spacing adjustment component (5). The blade (4) is provided with an angle adjustment component (6) at its top. The spacing adjustment component (5) includes a first lead screw (51) and a gear (52). The two sides of the gear (52) are fixedly connected to a connecting frame (56) by bearings. The connecting frame (56) is slidably connected to the inside of the housing (3). A rubber block (57) is fixedly connected to the bottom of the connecting frame (56). The angle adjustment assembly (6) includes a cylindrical body (61), a rotating block (62) is movably inserted inside the cylindrical body (61), the bottom of the rotating block (62) is fixedly connected to the blade (4) by bolts, a ring body (65) is sleeved on the outside of the cylindrical body (61), the bottom of the ring body (65) is provided with an annular insert rod (66), the annular insert rod (66) slides radially along the cylindrical body (61) through a slide rail, a number of insert rods are evenly fixedly connected to the bottom of the annular insert rod (66), and the top of the rotating block (62) is evenly provided with matching slots (67).

2. The food processing slicer according to claim 1, characterized in that, The box body (3) has a first through groove (54) on one side and a second through groove (55) adapted to the rubber block (57) on the bottom.

3. A food processing slicer according to claim 1, characterized in that, The inner wall of the cylinder (61) is fixedly connected to an annular slider (63), and the outer side of the rotating block (62) is provided with an annular groove (64) that is adapted to the annular slider (63).

4. A food processing slicer according to claim 3, characterized in that, The box (3) has a scale (53) on one side, and the cross-section of the annular slider (63) is T-shaped.

5. A food processing slicer according to claim 1, characterized in that, The surface of the cylinder (61) is provided with a dial (69), and the top of the cylinder (61) is fixedly connected to the bottom of the rubber block (57).

6. A food slicing machine according to claim 1, characterized in that, The outer side of the cylinder (61) is provided with an external thread (68), and the inside of the ring (65) is provided with an internal thread. The ring (65) is rotatably connected to the top of the ring rod (66) through an annular guide rail.

7. A food processing slicer according to claim 1, characterized in that, A three-phase asynchronous geared motor (7) is installed on one side of the operating table (1). The output end of the three-phase asynchronous geared motor (7) is fixedly connected to a second lead screw (8). The bottom of the moving frame (2) is provided with a threaded hole that matches the second lead screw (8). The moving frame (2) is slidably connected to the top of the operating table (1).

8. A food processing slicer according to claim 7, characterized in that, The bottom of the operating table (1) is fixedly connected to two guide rods (9), and two guide holes (10) adapted to the guide rods (9) are opened on one side of the moving frame (2).