CN216550466U - Corn peptide production is with high temperature enzyme-deactivating digester feed mechanism - Google Patents

Abstract

The utility model discloses a feeding mechanism of a high-temperature enzyme-inactivating digester for producing corn peptides, which comprises a storage box and an enzyme-inactivating tank, wherein a discharge pipe is connected between the storage box and the enzyme-inactivating tank, the outer wall of the storage box is fixedly connected with a transverse plate, the outer wall of the transverse plate is fixedly provided with a motor, a driving end of the motor is fixedly provided with an incomplete gear, the outer wall of the transverse plate is further provided with a gear meshed with the incomplete gear, the outer wall of the storage box is further fixedly provided with a guide rod, and the outer wall of the end part of the guide rod is slidably sleeved with a toothed plate meshed with the incomplete gear and the gear. According to the utility model, the intermittent communication between the discharge port and the discharge pipe is realized through the back-and-forth movement of the baffle plate, the intermittent falling of corn fermentation products is realized, meanwhile, the blockage of the discharge pipe is avoided through the up-and-down movement of the blockage prevention rod, the smooth falling of the fermentation products is ensured, then, the instantaneous enzyme deactivation work is realized by means of high-temperature steam led out by a plurality of air outlet pipes, and the enzyme deactivation is thorough and rapid.

Description

Corn peptide production is with high temperature enzyme-deactivating digester feed mechanism

Technical Field

The utility model relates to the technical field of corn peptide production, in particular to a feeding mechanism of a high-temperature enzyme-inactivating digester for corn peptide production.

Background

The corn peptide is a small molecular polypeptide substance obtained by directional enzyme digestion and a specific small peptide separation technology of protein extracted from corn.

The corn peptide is prepared by the steps of solid-liquid mixed fermentation, enzymolysis, high-temperature enzyme deactivation, separation and refining and the like in the production of the corn peptide, but the solid substances after the fermentation in the high-temperature enzymolysis process cannot be subjected to a small amount of intermittent enzyme deactivation, the enzyme deactivation efficiency of a large number of solid substances at one time is low, and the enzyme deactivation is not thorough.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the problems in the background art, and provides a feeding mechanism of a high-temperature enzyme-inactivating digester for producing corn peptides.

In order to achieve the purpose, the utility model adopts the following technical scheme:

a feeding mechanism of a high-temperature enzyme-inactivating digester for producing corn peptides comprises a storage box and an enzyme-inactivating box, wherein a discharge pipe is connected between the storage box and the enzyme-inactivating box, a transverse plate is fixedly connected to the outer wall of the material storage box, a motor is fixed to the outer wall of the transverse plate, an incomplete gear is fixed to the driving end of the motor, the outer wall of the transverse plate is also provided with a gear meshed with the incomplete gear, the outer wall of the storage box is also fixed with a guide rod, a toothed plate meshed with the incomplete gear and the gear is sleeved on the outer wall of the end part of the guide rod in a sliding manner, the lower side wall of the toothed plate is fixedly connected with a baffle plate through a connecting rod, the baffle plate is slidably inserted on a discharge pipe, the enzyme inactivating device is characterized in that a discharge port is formed in the baffle, a steam generator is fixed on the outer wall of the enzyme inactivating box, and an output end of the steam generator is connected with an air outlet pipe fixedly inserted on the outer wall of the enzyme inactivating box.

Preferably, the number of the air outlet pipes is multiple, and the air outlet pipes are symmetrically arranged on the outer walls of the two sides of the enzyme inactivating box.

Preferably, the air outlet pipe is obliquely arranged, and the height of one end of the air outlet pipe, which is positioned in the enzyme inactivating box, is higher than that of one end of the air outlet pipe, which is far away from the enzyme inactivating box.

Preferably, the last lateral wall of storage box slides and inserts and is equipped with and prevents stifled pole, the upper end of preventing stifled pole is fixed with the ball, be fixed with reset spring between the last lateral wall of ball and storage box, the last lateral wall of storage box is fixed with the right angle board, the tip slip cover of right angle board is equipped with right angle trapezoidal piece, the ball contacts with the inclined plane of right angle trapezoidal piece, the outer wall of gear rotates and is connected with the bull stick, the other end of bull stick rotates with the tip of right angle trapezoidal piece to be connected.

Preferably, the joint of the rotating rod and the gear is arranged deviating from the circle center of the gear.

Compared with the prior art, this maize peptide production is with high temperature enzyme-deactivating digester feed mechanism's advantage lies in:

according to the utility model, the intermittent communication between the discharge port and the discharge pipe is realized through the back-and-forth movement of the baffle plate, the intermittent falling of corn fermentation products is realized, meanwhile, the blockage of the discharge pipe is avoided through the up-and-down movement of the blockage prevention rod, the smooth falling of the fermentation products is ensured, then, the instantaneous enzyme deactivation work is realized by means of high-temperature steam led out by a plurality of air outlet pipes, and the enzyme deactivation is thorough and rapid.

Drawings

FIG. 1 is a schematic structural diagram of a feeding mechanism of a high-temperature enzyme-inactivating digester for producing corn peptides, which is provided by the utility model;

FIG. 2 is a top view of a baffle plate in a feeding mechanism of a high-temperature enzyme-inactivating digester for producing corn peptides.

In the figure: 1 storage box, 2 enzyme deactivation boxes, 3 discharging pipes, 4 transverse plates, 5 incomplete gears, 6 gears, 7 rotating rods, 8 right-angle plates, 9 right-angle trapezoidal blocks, 10 anti-blocking rods, 11 round balls, 12 guide rods, 13 toothed plates, 14 baffle plates, 15 steam generators, 16 air outlet pipes and 17 discharge ports.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

Referring to fig. 1-2, a feeding mechanism of a high-temperature enzyme-inactivating digester for producing corn peptides comprises a storage box 1 and an enzyme-inactivating tank 2, a discharge pipe 3 is connected between the storage box 1 and the enzyme-inactivating tank 2, a transverse plate 4 is fixedly connected to the outer wall of the storage box 1, a motor is fixed to the outer wall of the transverse plate 4, an incomplete gear 5 is fixed to the driving end of the motor, a gear 6 meshed with the incomplete gear 5 is further installed on the outer wall of the transverse plate 4, a guide rod 12 is further fixed to the outer wall of the storage box 1, a toothed plate 13 meshed with the incomplete gear 5 and the gear 6 is slidably sleeved on the outer wall of the end portion of the guide rod 12, a baffle plate 14 is fixedly connected to the lower side wall of the gear 13 through a connecting rod, the baffle plate 14 is slidably inserted on the discharge pipe 3, a discharge port 17 is formed in the baffle plate 14, the motor drives the incomplete gear 5 to rotate reversely, the incomplete gear 5 is firstly meshed with the gear 6 to drive the gear 6 to rotate forwardly, at the moment, the toothed plate 13 and the baffle 14 are driven to move towards the left side by the meshing of the gear 6 and the toothed plate 13, the discharge hole 17 is communicated with the discharge pipe 3, fermented corns fall out into the enzyme deactivation box 2 from the discharge pipe 3 and the discharge hole 17 to perform enzyme deactivation, when the incomplete gear 5 does not rotate and is not meshed with the gear 6 and is meshed with the toothed plate 13, the incomplete gear 5 drives the toothed plate 13 to move towards the right side, the toothed plate 13 drives the gear 6 to reversely rotate at the moment, the discharge hole 17 is staggered with the discharge pipe 3, and the discharge of fermented products is stopped, so that the intermittent communication between the discharge hole 17 and the discharge pipe 3 is realized through the continuous rotation of the incomplete gear 5, the intermittent falling of the fermented products is realized, the phenomenon that the amount of the fermented products poured at one time is too large, and the problem that the enzyme deactivation is incomplete is caused is solved.

The outer wall of enzyme deactivation case 2 is fixed with steam generator 15, steam generator 15's output is connected with the fixed outlet duct 16 of inserting on enzyme deactivation case 2 outer wall of establishing, the quantity of outlet duct 16 is a plurality of, and the symmetry sets up on enzyme deactivation case 2's both sides outer wall, the slope of outlet duct 16 sets up, and the one end height that is located enzyme deactivation case 2 of outlet duct 16 is higher than the one end height of keeping away from enzyme deactivation case 2, the tip of outlet duct 16 sets up towards discharge gate 17 promptly, will be blown away by high temperature steam when making the solid after the fermentation just fall out, the high temperature steam that steam generator 15 produced gets into from outlet duct 16 and blows away and the high temperature instantaneous enzyme deactivation work to the maize zymolite after the fermentation in enzyme deactivation case 2.

An anti-blocking rod 10 is inserted into the upper side wall of the storage box 1 in a sliding manner, a round ball 11 is fixed at the upper end of the anti-blocking rod 10, a return spring is fixed between the round ball 11 and the upper side wall of the storage box 1, a right-angle plate 8 is fixed on the upper side wall of the storage box 1, a right-angle trapezoidal block 9 is sleeved at the end part of the right-angle plate 8 in a sliding manner, the round ball 11 is in contact with the inclined plane of the right-angle trapezoidal block 9, a rotating rod 7 is rotatably connected to the outer wall of the gear 6, the joint of the rotating rod 7 and the gear 6 is deviated from the circle center of the gear 6, the other end of the rotating rod 7 is rotatably connected with the end part of the right-angle trapezoidal block 9, the gear 6 is rotated and rotated in a reciprocating manner through the intermittent meshing of an incomplete gear 5, the gear 6 and a toothed plate 13, the right-angle trapezoidal block 9 is pushed by the rotating rod 7 to move to the right side when the gear 6 rotates, the anti-blocking round ball 11 and the rod 10 are extruded by the right-angle trapezoidal block 9 and the rotating rod 7 is pulled back when the gear 6 rotates, at the moment, the anti-blocking rod 10 moves back under the elastic action of the reset spring, and the problem that the discharging pipe 3 cannot fall off due to blockage of corn fermentation materials is avoided by reciprocating up and down movement of the anti-blocking rod 10.

Further, unless otherwise specifically stated or limited, the above-described fixed connection is to be understood in a broad sense, and may be, for example, welded, glued, or integrally formed as is conventional in the art.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and equivalent alternatives or modifications according to the technical solution of the present invention and the inventive concept thereof should be covered by the scope of the present invention.

Claims (5)

1. The utility model provides a maize peptide production is with high temperature enzyme digester feed mechanism that goes out, includes storage box (1) and goes out enzyme case (2), its characterized in that, be connected with discharging pipe (3) between storage box (1) and the enzyme case that goes out (2), fixedly connected with diaphragm (4) on the outer wall of storage box (1), the outer wall of diaphragm (4) is fixed with the motor, the drive end of motor is fixed with incomplete gear (5), still install gear (6) with incomplete gear (5) engaged with on the outer wall of diaphragm (4), still be fixed with guide bar (12) on the outer wall of storage box (1), the tip outer wall sliding sleeve of guide bar (12) is equipped with pinion rack (13) with incomplete gear (5) and gear (6) engaged with, the lower lateral wall of pinion rack (13) passes through connecting rod fixedly connected with baffle (14), the enzyme inactivating device is characterized in that the baffle (14) is inserted on the discharge pipe (3) in a sliding manner, a discharge hole (17) is formed in the baffle (14), a steam generator (15) is fixed on the outer wall of the enzyme inactivating box (2), and an output end of the steam generator (15) is connected with an air outlet pipe (16) fixedly inserted on the outer wall of the enzyme inactivating box (2).

2. The feeding mechanism of the high-temperature enzyme deactivation digester for corn peptide production as claimed in claim 1, wherein the number of the air outlet pipes (16) is multiple and symmetrically arranged on the outer walls of two sides of the enzyme deactivation tank (2).

3. The feeding mechanism of the high-temperature enzyme deactivation digester for corn peptide production as claimed in claim 1, wherein the air outlet pipe (16) is arranged obliquely, and the height of the end of the air outlet pipe (16) located in the enzyme deactivation tank (2) is higher than the height of the end far away from the enzyme deactivation tank (2).

4. The feeding mechanism of the high-temperature enzyme-inactivating digester for producing the corn peptides, according to claim 1, is characterized in that an anti-blocking rod (10) is slidably inserted into the upper side wall of the storage box (1), a round ball (11) is fixed to the upper end of the anti-blocking rod (10), a return spring is fixed between the round ball (11) and the upper side wall of the storage box (1), a right-angle plate (8) is fixed to the upper side wall of the storage box (1), a right-angle trapezoidal block (9) is slidably sleeved on the end portion of the right-angle plate (8), the round ball (11) is in contact with the inclined surface of the right-angle trapezoidal block (9), a rotating rod (7) is rotatably connected to the outer wall of the gear (6), and the other end of the rotating rod (7) is rotatably connected with the end portion of the right-angle trapezoidal block (9).

5. The feeding mechanism of the high-temperature enzyme deactivation digester for corn peptide production as claimed in claim 4, wherein the junction of the rotating rod (7) and the gear (6) is arranged off the center of the circle of the gear (6).

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