CN116268027A

CN116268027A - Sandwich food forming device and using method

Info

Publication number: CN116268027A
Application number: CN202310197831.1A
Authority: CN
Inventors: 高珊; 王淼; 房玉国
Original assignee: Heilongjiang Province Green Food Science Research Institute
Current assignee: Heilongjiang Province Green Food Science Research Institute
Priority date: 2023-03-03
Filing date: 2023-03-03
Publication date: 2023-06-23
Anticipated expiration: 2043-03-03
Also published as: CN116268027B

Abstract

A sandwich food forming device and a using method thereof belong to the field of sandwich food manufacturing equipment. Comprises a power device, a storage cylinder and a plurality of cutting devices; the power device is arranged at the lower end of the storage cylinder, and a plurality of cutting devices are arranged at the bottom end of the storage cylinder; the power device comprises a vibration device, and the lower end of the vibration device is fixedly connected with a supporting rod. The power device also comprises a bidirectional motor; the bidirectional motor is fixedly connected to the lower end of the storage cylinder through a motor support, the lower end of the motor support is fixedly connected with a connecting rod, and the lower end of the connecting rod is fixedly connected with the vibration device. The utility model not only can manufacture the sweet dumplings in batches, but also can ensure the thickness of the glutinous rice flour at the cutting position of the sweet dumplings by adding the device, thereby avoiding the influence on the edible mouthfeel of the sweet dumplings due to the exposed stuffing of the sweet dumplings when consumers cook.

Description

Sandwich food forming device and using method

Technical Field

The utility model relates to a sandwich food forming device and a using method thereof, belonging to the field of sandwich food manufacturing equipment.

Background

Most of the common devices for manufacturing the sweet dumplings in the market can only manufacture one sweet dumpling after one filling, and the manufacturing efficiency is low;

the utility model patent number is CN2305062Y, the patent name is a sweet dumpling automatic molding machine, the utility model can realize continuous production, the size of the sweet dumpling, the quantity of stuffing and the thickness of the dough cover can be adjusted, and meanwhile, the requirements of different stuffing such as beans, vegetables and meat can be met, the product quality is stable, but the glutinous rice flour thickness of a cutting position of the stuffed sweet dumpling is thinner when the stuffed sweet dumpling is cut, and the condition of exposing the stuffing is easy to occur when the stuffed sweet dumpling is cooked, so the utility model is necessary to be improved.

Disclosure of Invention

The utility model aims to solve the problems in the prior art and provides a sandwich food forming device and a using method thereof.

The utility model achieves the above purpose, adopts the following technical scheme:

a sandwich food forming device comprises a power device, a storage cylinder and a plurality of cutting devices; the power device is arranged at the lower end of the storage cylinder, and a plurality of cutting devices are arranged at the bottom end of the storage cylinder; the power device comprises a vibration device, and the lower end of the vibration device is fixedly connected with a supporting rod.

A method of using a sandwich food product forming apparatus, the method comprising the steps of:

step one: the raw materials are respectively placed into a storage cylinder I and a storage cylinder II;

step two: starting a bidirectional motor, and driving the sliding plate and the storage cylinder I to move downwards by the bidirectional motor to squeeze raw materials into the cutting device;

step three: starting a micro motor to drive the arc-shaped section I and the arc-shaped section III to move relatively and complete cutting;

step four: and the finished product after cutting falls into the chute, and finally falls into the container below along the chute.

Compared with the prior art, the utility model has the beneficial effects that: the utility model not only can manufacture the sweet dumplings in batches, but also can ensure the thickness of the glutinous rice flour at the cutting position of the sweet dumplings by adding the device, thereby avoiding the influence on the edible mouthfeel of the sweet dumplings due to the exposed stuffing of the sweet dumplings when consumers cook.

Drawings

FIG. 1 is a front view of a center-filled food forming device of the present utility model;

FIG. 2 is a front view of a power plant of a center-filled food forming device of the utility model;

FIG. 3 is a cross-sectional view of a cartridge of a center-filled food forming device of the present utility model;

FIG. 4 is a front view of a cutting device of a center-filled food forming device of the present utility model;

FIG. 5 is a front view of an adding device of a center-filled food forming device of the present utility model;

FIG. 6 is a rear view of the addition device of a center-filled food forming device of the present utility model;

FIG. 7 is a schematic structural view of a connecting block of a center-filled food forming device of the present utility model;

FIG. 8 is a schematic view of the structure of the arc-shaped section I and the arc-shaped section II of the sandwich food forming device of the utility model;

FIG. 9 is a schematic view of the location of a circular aperture of a center-filled food forming device of the present utility model;

FIG. 10 is a schematic diagram showing the relative movement of the arcuate sections I, III of a sandwich food forming apparatus of the present utility model;

FIG. 11 is an enlarged schematic view of the structure of FIG. 10A;

FIG. 12 is a schematic diagram II of the opposite movement states of the arc-shaped section I and the arc-shaped section III of the sandwich food forming device;

FIG. 13 is an enlarged schematic view of the structure of B in FIG. 12;

fig. 14 is a schematic view showing a state of moving the arc-shaped section i and the arc-shaped section iii toward each other in the sandwich food forming apparatus according to the present utility model.

Detailed Description

The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model, and it is apparent that the described embodiments are only some embodiments of the utility model, but not all embodiments, and all other embodiments obtained by those skilled in the art without making creative efforts based on the embodiments of the present utility model are all within the protection scope of the present utility model.

The first embodiment is as follows: as shown in fig. 1 to 14, the present embodiment describes a sandwich food product forming apparatus comprising a power unit 2, a cartridge 3 and a plurality of cutting devices 4; the power device 2 is arranged at the lower end of the storage cylinder 3, and a plurality of cutting devices 4 are arranged at the bottom end of the storage cylinder 3; the power device 2 comprises a vibration device, and the lower end of the vibration device is fixedly connected with a supporting rod 1.

The power plant 2 also comprises a bi-directional motor 23; the bidirectional motor 23 is fixedly connected to the lower end of the storage cylinder 3 through a motor bracket 22, the lower end of the motor bracket 22 is fixedly connected with a connecting rod 24, and the lower end of the connecting rod 24 is fixedly connected with the vibration device.

The storage cylinder 3 comprises a sliding plate 31, a storage cylinder I32 and a storage cylinder II 33; the storage cylinder I32 is arranged in the storage cylinder II 33, the storage cylinder I and the storage cylinder II can slide relatively, the sliding plate 31 is arranged in the storage cylinder I32, and the sliding plate 31 is in sliding fit with the storage cylinder I32; the bottom of the storage cylinder I32 is provided with a threaded hole I35, and the sliding plate 31 is provided with a threaded hole II 34; one of the output shafts of the bidirectional motor 23 is provided with a rectangular lug, one end of the screw 21 is provided with a rectangular jack, the screw 21 is sleeved on the rectangular lug through the rectangular jack, and the screw 21 passes through a through hole 36 on the storage barrel II 33 to be in threaded fit with the threaded hole I35 and the threaded hole II 34.

The cross sections of the storage cylinder I32 and the storage cylinder II 33 are rectangular.

The pitch of the middle-lower thread of the screw 21 is smaller than that of the middle-upper thread of the screw 21, the threaded hole I35 is matched with the middle-lower thread of the screw 21, and the threaded hole II 34 is matched with the middle-upper thread of the screw 21.

The vibration device comprises a hemispherical outer shell 25 and a rotating block 210; the upper end of the hemispherical shell 25 is fixedly connected with a connecting rod 24, and a chute 26 is arranged on the outer circular surface of the hemispherical shell 25; the rotating block 210 is arranged in the hemispherical shell 25, and the rotating block 210 penetrates through the hemispherical shell 25 to be fixedly connected with the other output shaft of the bidirectional motor 23; a groove 27 is formed in the cambered surface, close to the hemispherical shell 25, of the rotating block 210, a spring block 29 is connected in the groove 27 through a spring 28, and an inclined surface is formed on one side of the spring block 29; the inner circular surface of the hemispherical shell 25 is provided with a clamping groove which is in sliding fit with the elastic block 29; the lower end of the hemispherical shell 25 is fixedly connected with a supporting rod 1.

The cutting device 4 comprises a U-shaped connecting rod 41, a discharging pipe 42, a telescopic pipe 43, a sliding pipe 44, a connecting pipe I45, an adding device 46 and a connecting pipe II 47; the lower end of the adding device 46 is fixedly connected with a connecting pipe II 47, and the upper end of the adding device 46 is fixedly connected with a connecting pipe I45; the sliding tube 44 is in sliding fit with the connecting tube I45, and the sliding tube 44 is fixedly connected in the connecting hole I38 at the lower end of the storage cylinder II 33; the upper end of the discharging pipe 42 is fixedly connected in a connecting hole II 39 at the lower end of the storage barrel I32, and the lower end of the discharging pipe 42 is positioned in the sliding pipe 44 and the connecting pipe I45; one end of the U-shaped connecting rod 41 is fixedly connected to the side face of the adding device 46, and the other end of the U-shaped connecting rod 41 is fixedly connected to the side face of the storage cylinder I32 through a bolt.

The adding device 46 comprises a miniature motor 461, a rectangular housing 462, an arc-shaped section I463, an arc-shaped section II 464, a cylinder 467, an arc-shaped section III 468, a slide 4611, a roller I4613, a conveyor 4614, a connecting block 4615, a roller II 4616 and a round bar 4617; the upper end and the lower end of the rectangular housing 462 are respectively communicated with a connecting pipe I45 and a connecting pipe II 47, and a slideway I465 and a slideway II 466 are arranged on the side wall of the rectangular housing 462; the miniature motor 461 is fixedly connected to the U-shaped connecting rod 41 through a bracket, and the output shaft of the miniature motor 461 is fixedly connected with a roller I4613; the roller II 4616 is connected to the outer side surface of the rectangular shell 462 through a central shaft, and a conveyor belt 4614 is sleeved between the roller I4613 and the roller II 4616; two notches are arranged on the inner side surface of the conveyor belt 4614; the number of the connecting blocks 4615 is two, each connecting block 4615 is embedded into a corresponding notch, the other end of each connecting block 4615 is fixedly connected with a round rod 4617, and the two connecting blocks 4615 are respectively in sliding fit with the slide ways I465 and II 466; round holes 4612 are formed in the side faces of the arc-shaped section I463 and the arc-shaped section III 468, and the two round holes 4612 are respectively sleeved with a corresponding round rod 4617; the widths of the arc-shaped section I463, the arc-shaped section II 464 and the arc-shaped section III 468 are equal to the width of the rectangular shell 462, and the outer circular surfaces of the arc-shaped section I463 and the arc-shaped section II 464 are respectively provided with a T-shaped chute 4610; two ends of the sliding block 4611 are respectively in sliding fit with two T-shaped sliding grooves 4610; the cylinder 467 is fixedly connected to the inner wall of the rectangular housing 462, the length of the cylinder 467 is smaller than the difference between the width of the rectangular housing 462 and the diameter of the connecting pipe I45, and when the arc-shaped section II 464 moves through the position of the cylinder 467, the cylinder 467 contacts with the inner circular surface of the arc-shaped section II 464; the upper end of the rectangular shell 462 is provided with a connecting hole III 469; one end of the telescopic tube 43 is communicated with the connecting hole III 469, and the other end of the telescopic tube 43 is communicated with the connecting Kong 37 at the bottom of the storage cylinder II 33. The effect of slider 4611 is to be connected arc section I463 and arc section II 464, avoids the two separation, and arc section II 464 can not remove thereupon when leading to the removal of arc section I463, and then influences the thickness of the outer raw materials of sweet dumpling top cutting face.

The central angles of the arc-shaped section I463, the arc-shaped section II 464 and the arc-shaped section III 468 are 90 degrees, and the inner diameter of the arc-shaped section I463 is equal to the outer diameter of the arc-shaped section III 468; the arc-shaped section I463 is arranged above the arc-shaped section II 464.

step one: the raw materials are respectively placed into a storage cylinder I32 and a storage cylinder II 33;

step two: starting a bidirectional motor 23, and driving a sliding plate 31 and a storage cylinder I32 to move downwards by the bidirectional motor 23 to squeeze raw materials into a cutting device 4;

step three: starting the micro motor 461 to drive the arc-shaped section I463 and the arc-shaped section III 468 to move relatively and complete cutting;

step four: the finished cut product falls into chute 26 and eventually along chute 26 into the container below.

The working principle of the utility model is as follows: when the utility model is used, the outer layer raw material is poured into the storage cylinder II 33, the inner layer raw material is poured into the storage cylinder I32, as shown in fig. 1 or 4, the U-shaped connecting rod 41 is telescopic in the vertical direction, the relative movement between the storage cylinder I32 and the storage cylinder II 33 is convenient, and the length of the U-shaped connecting rod 41 is shortest when the storage cylinder I32 is contacted with the storage cylinder II 33;

starting a bidirectional motor 23, wherein the bidirectional motor 23 drives the screw rod 21 to rotate, the screw rod 21 drives the sliding plate 31 and the storage cylinder I32 to move downwards through the threaded holes I35 and the threaded holes II 34, and as the threaded holes I35 and II 34 have different screw pitches, after the screw rod 21 rotates by 360 degrees, the downward moving distance of the sliding plate 31 corresponding to the threaded hole II 34 with the large screw pitch is larger than the downward moving distance of the storage cylinder I32 corresponding to the threaded hole I35 with the small screw pitch, so that the sliding plate 31 and the storage cylinder I32 can move relatively, and further, when the outer raw material is extruded out of the storage cylinder II 33, the inner raw material can be extruded out of the storage cylinder I32;

the outer layer raw material enters the rectangular shell 462 through the gap between the slide tube 44 and the discharge tube 42, the inner layer raw material directly enters the rectangular shell 462 through the discharge tube 42, and the outer layer raw material wraps the inner layer raw material extruded from the inside of the discharge tube 42; after the raw materials move downwards and pass through the rectangular shell 462 to enter the connecting cylinder II 47, the micro motor 461 is started, the micro motor 461 drives the roller I4613 to rotate, the conveyor 4614 is driven to move, the conveyor 4614 drives the connecting blocks 4615 embedded in the notch of the conveyor 4614 to move, the two connecting blocks 4615 in the state shown in figure 6 are further driven to move in opposite directions by the two round rods 4617, the arc-shaped cut piece I463 and the arc-shaped cut piece III 468 are driven to move in opposite directions, the arc-shaped cut piece I463 also drives the arc-shaped cut piece II 464 to move, and when the storage cylinder I32 moves downwards, the outer raw materials are pushed into the telescopic tube 43, so that the outer raw materials directly enter the rectangular shell 462, the arc-shaped cut piece I463 and the arc-shaped cut piece III 468 move in opposite directions, the outer raw materials in the rectangular shell 462 are pushed to the middle position, and when the arc-shaped cut piece I463 and the arc-shaped cut piece III 468 approach to the state shown in figure 10, the arc-shaped section I463 and the arc-shaped section III 468 cut the raw material into an upper part and a lower part, and as the arc-shaped section I463 and the arc-shaped section III 468 continue to move towards each other, the outer diameter of the arc-shaped section III 468 is equal to the inner diameter of the arc-shaped section I463, so that after the arc-shaped section I463 and the arc-shaped section III 468 approach each other, the arc-shaped section I463 and the arc-shaped section III 468 respectively rotate around the corresponding round bar 4617 to the state shown in FIG. 12 under the influence of interaction force, and simultaneously the inner circular surface of the arc-shaped section II 464 is contacted with the cylinder 467, and further moves to the state shown in fig. 12, in which the arc-shaped cut pieces ii 464 and iii 468 are respectively brought into contact with the top surface of the lower raw material and the bottom surface of the upper raw material, and as the two push the outer raw material to move, when moving around the top surface of the lower raw material and the bottom surface of the upper raw material, the outer raw material is smeared on the top surface of the lower raw material and the bottom surface of the upper raw material, thereby increasing the thickness of the outer raw material, the thickness of the cutting position of the rice dumplings is ensured, and the occurrence of stuffing exposure during cooking is reduced; with the arc-shaped cut piece I463 and the arc-shaped cut piece III 468 continuing to move to the state shown in FIG. 14, the raw material continues to be extruded downwards, and the above operation is repeated.

Claims

1. A sandwich food forming device, characterized in that: comprises a power device (2), a storage cylinder (3) and a plurality of cutting devices (4); the power device (2) is arranged at the lower end of the storage cylinder (3), and a plurality of cutting devices (4) are arranged at the bottom end of the storage cylinder (3); the power device (2) comprises a vibration device, and the lower end of the vibration device is fixedly connected with a supporting rod (1).

2. A sandwich food product forming apparatus in accordance with claim 1 wherein: the power device (2) also comprises a bidirectional motor (23); the bidirectional motor (23) is fixedly connected to the lower end of the storage cylinder (3) through a motor support (22), the lower end of the motor support (22) is fixedly connected with a connecting rod (24), and the lower end of the connecting rod (24) is fixedly connected with the vibration device.

3. A sandwich food product forming apparatus in accordance with claim 2 wherein: the storage cylinder (3) comprises a sliding plate (31), a storage cylinder I (32) and a storage cylinder II (33); the storage cylinder I (32) is arranged in the storage cylinder II (33), the storage cylinder I and the storage cylinder II can slide relatively, the sliding plate (31) is arranged in the storage cylinder I (32), and the sliding plate (31) is in sliding fit with the storage cylinder I (32); the bottom of the storage cylinder I (32) is provided with a threaded hole I (35), and the sliding plate (31) is provided with a threaded hole II (34); one of them output shaft of bi-directional motor (23) is equipped with the rectangle lug, and the one end of screw rod (21) is equipped with the rectangle jack, and screw rod (21) are overlapped on the rectangle lug through the rectangle jack, and through-hole (36) and screw hole I (35), screw hole II (34) screw-thread fit on screw rod (21) passed storage section of thick bamboo II (33).

4. A sandwich food product forming apparatus as claimed in claim 3 wherein: the cross sections of the storage cylinder I (32) and the storage cylinder II (33) are rectangular.

5. A sandwich food product forming apparatus as claimed in claim 3 wherein: the pitch of the middle-lower thread of the screw rod (21) is smaller than that of the middle-upper thread of the screw rod (21), the threaded hole I (35) is matched with the middle-lower thread of the screw rod (21), and the threaded hole II (34) is matched with the middle-upper thread of the screw rod (21).

6. A center-fill food product forming apparatus as defined in claim 5 wherein: the vibration device comprises a hemispherical shell (25) and a rotating block (210); the upper end of the hemispherical shell (25) is fixedly connected with the connecting rod (24), and a chute (26) is arranged on the outer circular surface of the hemispherical shell (25); the rotating block (210) is arranged in the hemispherical shell (25), and the rotating block (210) penetrates through the hemispherical shell (25) to be fixedly connected with the other output shaft of the bidirectional motor (23); a groove (27) is formed in the cambered surface, close to the hemispherical shell (25), of the rotating block (210), a spring block (29) is connected in the groove (27) through a spring (28), and an inclined surface is formed in one side of the spring block (29); the inner circular surface of the hemispherical shell (25) is provided with a clamping groove which is in sliding fit with the elastic block (29); the lower end of the hemispherical shell (25) is fixedly connected with a supporting rod (1).

7. The center-filled food product forming apparatus of claim 6 wherein: the cutting device (4) comprises a U-shaped connecting rod (41), a discharging pipe (42), a telescopic pipe (43), a sliding pipe (44), a connecting pipe I (45), an adding device (46) and a connecting pipe II (47); the lower end of the adding device (46) is fixedly connected with a connecting pipe II (47), and the upper end of the adding device (46) is fixedly connected with a connecting pipe I (45); the sliding tube (44) is in sliding fit with the connecting tube I (45), and the sliding tube (44) is fixedly connected in the connecting hole I (38) at the lower end of the storage cylinder II (33); the upper end of the discharging pipe (42) is fixedly connected in a connecting hole II (39) at the lower end of the storage barrel I (32), and the lower end of the discharging pipe (42) is positioned in the sliding pipe (44) and the connecting pipe I (45); one end of the U-shaped connecting rod (41) is fixedly connected to the side face of the adding device (46), and the other end of the U-shaped connecting rod (41) is fixedly connected to the side face of the storage cylinder I (32) through a bolt.

8. The center-fill food product forming apparatus of claim 7, wherein: the adding device (46) comprises a miniature motor (461), a rectangular shell (462), an arc-shaped section I (463), an arc-shaped section II (464), a cylinder (467), an arc-shaped section III (468), a sliding block (4611), a roller I (4613), a conveyor belt (4614), a connecting block (4615), a roller II (4616) and a round rod (4617); the upper end and the lower end of the rectangular shell (462) are respectively communicated with a connecting pipe I (45) and a connecting pipe II (47), and a slideway I (465) and a slideway II (466) are arranged on the side wall of the rectangular shell (462); the miniature motor (461) is fixedly connected to the U-shaped connecting rod (41) through a bracket, and a roller I (4613) is fixedly connected to an output shaft of the miniature motor (461); the roller II (4616) is connected to the outer side surface of the rectangular shell (462) through a central shaft, and a conveyor belt (4614) is sleeved between the roller I (4613) and the roller II (4616); two notches are arranged on the inner side surface of the conveyor belt (4614); two connecting blocks (4615) are arranged, each connecting block (4615) is embedded into a corresponding notch, the other end of each connecting block (4615) is fixedly connected with a round rod (4617), and the two connecting blocks (4615) are respectively in sliding fit with a slide way I (465) and a slide way II (466); round holes (4612) are formed in the side faces of the arc-shaped section I (463) and the arc-shaped section III (468), and the two round holes (4612) are respectively sleeved with a corresponding round rod (4617); the widths of the arc-shaped section I (463), the arc-shaped section II (464) and the arc-shaped section III (468) are equal to the width of the rectangular shell (462), and the outer circular surfaces of the arc-shaped section I (463) and the arc-shaped section II (464) are respectively provided with a T-shaped chute (4610); two ends of the sliding block (4611) are respectively in sliding fit with two T-shaped sliding grooves (4610); the cylinder (467) is fixedly connected to the inner wall of the rectangular shell (462), the length of the cylinder (467) is smaller than the difference between the width of the rectangular shell (462) and the diameter of the connecting pipe I (45), and when the arc-shaped section II (464) moves through the position of the cylinder (467), the cylinder (467) is in contact with the inner circular surface of the arc-shaped section II (464); the upper end of the rectangular shell (462) is provided with a connecting hole III (469); one end of the telescopic tube (43) is communicated with the connecting hole III (469), and the other end of the telescopic tube (43) is communicated with the connecting Kong (37) at the bottom of the storage cylinder II (33).

9. A sandwich food product forming apparatus in accordance with claim 8 wherein: the corresponding central angles of the arc-shaped section I (463), the arc-shaped section II (464) and the arc-shaped section III (468) are 90 degrees, and the inner diameter of the arc-shaped section I (463) is equal to the outer diameter of the arc-shaped section III (468); the arc-shaped section I (463) is arranged above the arc-shaped section II (464).

10. The method of using a center-fill food product forming apparatus of claim 9, wherein: the using method comprises the following steps:

step one: the raw materials are respectively put into a storage cylinder I (32) and a storage cylinder II (33);

step two: starting a bidirectional motor (23), and driving a sliding plate (31) and a storage cylinder I (32) to move downwards by the bidirectional motor (23) so as to squeeze raw materials into a cutting device (4);

step three: starting a micro motor (461) to drive the arc-shaped section I (463) and the arc-shaped section III (468) to move relatively and complete cutting;

step four: the finished product after cutting falls into the chute (26) and finally falls into the container below along the chute (26).