CN210411470U - A sieving mechanism for food processing - Google Patents

Abstract

The utility model relates to a food processing technology field especially relates to a sieving mechanism for food processing. The to-be-solved technical problem of the utility model is that the existing part sieve separator can't sieve the starch layer on the flour circle surface. In order to solve the technical problem, the utility model provides a sieving mechanism of food processing. The utility model discloses a through the opening of driven shell one side with pay-off cabin overlap joint in the pay-off mouth during the use, the screening intracavity is sent into with the powder circle in rethread pay-off cabin, take out again the pay-off cabin and wait starter motor, the cylinder is rotatory with oval gyro wheel this moment, can exert pressure to one side of cylinder inner wall when oval gyro wheel rotates, and the same direction's of team spring application pressure, change when oval gyro wheel direction, the spring loses pressure and kick-backs and, the cylinder atress shakes this moment, make the starch casing of powder circle broken, the powder circle that accords with the size this moment gets into the arc and accomodates the under-deck, make be less than and get into screening on next step with the powder circle that accords with.

Description

A sieving mechanism for food processing

Technical Field

The utility model relates to a food processing technology field specifically is a sieving mechanism for food processing.

Background

At present, in the mechanical processing of food, the pearl balls are prepared into granules and then are screened out in multiple ways to meet the required size and specification in the processing process, and then are processed into finished products;

most of the existing screening devices in the market can only screen according to the caliber, but part of the flour balls are not only in accordance with the size specification, but also in accordance with the requirements, the starch possibly stained on the surface is excessive, so that the starch shells wrap the surfaces of the flour balls and the flour balls cannot pass through the filtering openings, and the existing screening devices cannot shatter the starch balls so that the flour balls with the original specification can be reprocessed.

SUMMERY OF THE UTILITY MODEL

Technical problem to be solved

The utility model provides a not enough to prior art, the utility model provides a sieving mechanism for food processing has solved the problem that current partial sieve separator can't sieve whitewashed round surface starch layer.

(II) technical scheme

In order to achieve the above purpose, the utility model discloses a following technical scheme realizes: a screening device for food processing comprises a kinetic energy shell, wherein a cavity formed in one side of the kinetic energy shell is movably connected with one end of a roller, the other end of the roller is movably connected with a cavity formed in one side of a driven shell, one side of the inner wall of the kinetic energy shell is welded with one side of a motor, the output end of the motor is fixedly connected with one end of a kinetic energy rotating shaft, the other end of the kinetic energy rotating shaft is welded with one side of a driven U-shaped shaft, two ends of the driven U-shaped shaft are respectively welded with two sides of one end of the roller, the surface of the kinetic energy rotating shaft is welded with one end of an auxiliary U-shaped shaft, the other end of the auxiliary U-shaped shaft penetrates through a driven through hole formed in one side of the roller and extends to the other side of the driven through hole, the other end of the U-shaped shaft is welded with the surface of the driven rotating shaft, the other side of the auxiliary block is welded with one side of the inner wall of the driven shell, the other end of the driven rotating shaft is welded with a driven cavity formed in one side of the elliptic roller, one side of the elliptic roller is lapped on one side of the inner wall of the roller, one sides of the kinetic energy shell and the inner wall of the driven shell are fixedly connected with an annular slide rail, the bottom and the top of the annular slide rail are respectively sleeved with an arc-shaped slide block, one side of the arc-shaped slide block, which faces the roller, is fixedly connected with one end of a spring, the other end of the spring is lapped on the surface of the roller, one side of the arc-shaped slide block, which faces the roller, is welded with one end of the spring, the other end of the spring is lapped on the surface of the roller, a screening cavity is formed in the inner part of the roller, a feeding port communicated with the screening cavity is formed in one side of the roller, and the other side of the arc containing cabin is welded with one side of the driven shell.

Further preferably, annular baffles are extended from two sides of the roller, and the roller is overlapped at the other end of the spring through the two annular baffles.

Preferably, the diameter of the screening opening is one centimeter, and a cushion pad is sleeved on one side of the screening opening communicated with the screening cavity.

Further preferably, the diameter of the screening chamber is forty centimeters, and the interior of the screening chamber is made of soft plastic.

Preferably, one side of the driven shell is provided with a through hole, and the through hole extends into a cavity formed in one side of the kinetic energy shell.

It is further preferred that the number of screening openings is sixty-five and that the sixty-five screening openings are provided in the surface of the drum in an annular array.

(III) advantageous effects

The utility model provides a sieving mechanism for food processing possesses following beneficial effect:

(1) the opening through driven shell one side sends the pay-off cabin overlap joint in the pay-off mouth, the screening intracavity is sent into with the powder circle to the rethread pay-off cabin, take out the restart motor with the pay-off cabin this moment, the cylinder is rotatory with oval gyro wheel this moment, can exert pressure to one side of cylinder inner wall when oval gyro wheel rotates then, the one side of cylinder exerts pressure to the spring this moment, when oval gyro wheel is rotatory to other directions, the spring loses pressure and kick-backs and exert pressure to the cylinder, the inside vibrations that carry out of cylinder this moment, thereby make the surperficial starch shell of its inside powder circle broken, thereby make the powder circle that accords with the size through sieve the selection mouth get into the arc and accomodate the under-deck, make be less than and can get into screening link on.

(2) The soft plastic material through the inner wall of the screening cavity can prevent the flour balls from being directly cracked due to the fact that the material passing through the screening cavity is too hard when the flour balls roll, and the flour balls are guaranteed to be broken only by the starch shells on the surfaces in the screening process.

Drawings

FIG. 1 is a sectional view of the front structure of the present invention;

FIG. 2 is a cross-sectional view of the drum structure of the present invention;

fig. 3 is a side view of the drum structure of the present invention;

fig. 4 is a side view of the present invention using the novel elliptical roller.

In the figure: 1 kinetic energy shell, 2 cylinders, 3 driven shells, 4 motors, 5 kinetic energy rotating shafts, 6 driven U-shaped shafts, 7 auxiliary U-shaped shafts, 8 driven through ports, 9 driven rotating shafts, 10 auxiliary blocks, 11 auxiliary cavities, 12 elliptical rollers, 13 driven cavities, 14 annular slide rails, 15 arc-shaped slide blocks, 16 springs, 17 screening cavities, 18 feeding ports, 19 screening ports and 20 arc-shaped storage compartments.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-4, the present invention provides a technical solution: a screening device for food processing comprises a kinetic energy shell 1, wherein a cavity formed in one side of the kinetic energy shell 1 is movably connected with one end of a roller 2, the other end of the roller 2 is movably connected with a cavity formed in one side of a driven shell 3, one side of the driven shell 3 is provided with an opening, and the opening extends into the cavity formed in one side of the driven shell 3, so that the stability of equipment is improved, the attractiveness of the equipment is improved, the roller 2 in the driven shell 3 cannot be in a closed space and can have the feeding and discharging capabilities, one side of the inner wall of the kinetic energy shell 1 is welded with one side of a motor 4, the motor 4 is connected with a 220v mains supply through a control power supply which is external, the output end of the motor is fixedly connected with one end of a kinetic energy rotating shaft 5, and the other end of the kinetic energy rotating shaft 5 is welded with one side of a driven U, two ends of a driven U-shaped shaft 6 are respectively welded with two sides of one end of a roller 2, the surface of a kinetic energy rotating shaft 5 is welded with one end of an auxiliary U-shaped shaft 7, the other end of the auxiliary U-shaped shaft 7 passes through a driven through hole 8 formed in one side of the roller 2 to extend to the other side of the roller, the other end of the U-shaped shaft 7 is welded with the surface of a driven rotating shaft 9, one end of the driven rotating shaft 9 is movably connected with an auxiliary cavity 11 formed in one side of an auxiliary block 10, the other side of the auxiliary block 10 is welded with one side of the inner wall of a driven shell 3, the other end of the driven rotating shaft 9 is welded with a driven cavity 13 formed in one side of an elliptical roller 12, one side of the elliptical roller 12 is lapped on one side of the inner wall of the roller 2, annular sliding rails 14 are fixedly connected with one sides of the inner walls of the kinetic energy shell 1 and the driven shell 3, arc sliding blocks 15 are sleeved, the other end of the spring 16 is lapped with the surface of the roller 2, annular baffles are extended from two sides of the roller 2, the roller 2 is lapped at the other end of the spring 16 through two annular baffles, the arrangement not only improves the stability of the equipment, but also improves the aesthetic degree of the equipment, ensures that the vibration caused by the rotation of the roller 2 can be controlled to a certain extent, a screening cavity 17 is arranged in the roller 2, the diameter of the screening cavity 17 is forty centimeters, and the interior of the screening cavity 17 is made of soft plastic, so that the stability of the equipment is improved, the aesthetic degree of the equipment is also improved, the starch shell on the surface can be crushed only in the screening process of the powder circles, a feeding port 18 communicated with the screening cavity 17 is arranged on one side of the roller 2, screening ports 19 are arranged on the surface of the roller 2, the number of the screening ports 19 is sixty five, and the sixty five screening ports 19 are arranged on the surface of the roller 2 in an annular array form, set up like this and not only improved the stability of equipment, the pleasing to the eye degree of equipment has been improved again, guaranteed that equipment can not be too much and unable timely work because of the powder circle of cylinder 2 inside when using, the work efficiency when having improved equipment operation, and screening mouth 19 is linked together with screening chamber 17, the diameter of screening mouth 19 is a centimetre, and one side of screening mouth 19 intercommunication screening chamber 17 has cup jointed the blotter, the setting has not only improved the stability of equipment like this, the pleasing to the eye degree of equipment has been improved again, it only can carry out the breakage to have guaranteed that the powder circle is in the screening process starch shell on surface, one side and the one side welding of cabin 20 is accomodate to the arc of kinetic energy shell 1, and the opposite side of cabin 20 is accomodate to the arc is welded with one side of driven shell 3.

The working principle is as follows: when a sieving mechanism for food processing uses, the pay-off cabin overlap joint is in pay-off mouth 18 through the opening of driven shell 3 one side, the powder circle is sent into in screening chamber 17 through the pay-off cabin, take out pay-off cabin this moment and restart motor 4, cylinder 2 and oval gyro wheel 12 rotate this moment, can exert pressure to one side of cylinder 2 inner wall when oval gyro wheel 12 rotates, one side of cylinder 2 exerts pressure to spring 16 this moment, when oval gyro wheel 12 rotates to other directions, spring 16 loses pressure and kick-backs and exert pressure to cylinder 2, the inside vibrations that carry on of cylinder 2 this moment, thereby make the starch shell on its inside powder circle surface broken, thereby make the powder circle that accords with the size get into the arc and accomodate the under-deck through screening mouth 19.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that various changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention.

Claims (6)

1. A screening device for food processing, comprising a kinetic energy housing (1), characterized in that: the inner wall of the kinetic energy shell (1) is movably connected with one end of a roller (2) in a cavity formed in one side of the kinetic energy shell (1), the other end of the roller (2) is movably connected with a cavity formed in one side of a driven shell (3), one side of the inner wall of the kinetic energy shell (1) is welded with one side of a motor (4), the output end of the motor is fixedly connected with one end of a kinetic energy rotating shaft (5), the other end of the kinetic energy rotating shaft (5) is welded with one side of a driven U-shaped shaft (6), two ends of the driven U-shaped shaft (6) are respectively welded with two sides of one end of the roller (2), the surface of the kinetic energy rotating shaft (5) is welded with one end of an auxiliary U-shaped shaft (7), the other end of the auxiliary U-shaped shaft (7) penetrates through a driven through hole (8) formed in one side of the roller (2) to extend to the other side of the roller, and the other, one end of the driven rotating shaft (9) is movably connected with an auxiliary cavity (11) formed in one side of an auxiliary block (10), the other side of the auxiliary block (10) is welded with one side of the inner wall of the driven shell (3), the other end of the driven rotating shaft (9) is welded with a driven cavity (13) formed in one side of an elliptical roller (12), one side of the elliptical roller (12) is lapped on one side of the inner wall of the roller (2), annular sliding rails (14) are fixedly connected to one sides of the inner walls of the kinetic energy shell (1) and the driven shell (3), arc-shaped sliding blocks (15) are sleeved at the bottoms and the tops of the annular sliding rails (14), one sides of the arc-shaped sliding blocks (15) facing the roller (2) are fixedly connected with one ends of springs (16), the other ends of the springs (16) are lapped on the surface of the roller (2), a screening cavity (17) is formed in the roller (2), and a feeding port (18) communicated with the screening cavity (17) is formed in one side of the roller (2), a screening port (19) is formed in the surface of the roller (2), the screening port (19) is communicated with the screening cavity (17), one side of the kinetic energy shell (1) is welded to one side of the arc containing cabin (20), and the other side of the arc containing cabin (20) is welded to one side of the driven shell (3).

2. A screening apparatus for food processing according to claim 1, wherein: annular baffles are extended from two sides of the roller (2), and the roller (2) is overlapped at the other end of the spring (16) through the two annular baffles.

3. A screening apparatus for food processing according to claim 1, wherein: the diameter of the screening opening (19) is one centimeter, and one side of the screening opening (19) communicated with the screening cavity (17) is sleeved with a cushion pad.

4. A screening apparatus for food processing according to claim 1, wherein: the diameter of the screening cavity (17) is forty centimeters, and the interior of the screening cavity (17) is made of soft plastic.

5. A screening apparatus for food processing according to claim 1, wherein: the opening is seted up to one side of driven shell (3), and the opening extends to in the cavity that driven shell (3) one side was seted up.

6. A screening apparatus for food processing according to claim 1, wherein: the number of the screening openings (19) is sixty-five, and the sixty-five screening openings (19) are arranged on the surface of the roller (2) in an annular array.

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