CN213657579U - Automatic temperature reducing device for protein powder discharging - Google Patents

Abstract

An automatic protein powder blanking cooling device relates to the technical field of protein powder blanking devices and comprises a cooling cylinder, wherein two groups of flow slowing plates which are obliquely and downwards arranged in parallel are oppositely arranged on the inner wall of the cooling cylinder, and the two groups of flow slowing plates are alternately arranged; the double-deck gas storage cavity that forms through its intermediate layer of section of thick bamboo wall of cooling section of thick bamboo, the rigid coupling has the air conditioning of intercommunication gas storage cavity to carry a section of thick bamboo on the outer wall of a cooling section of thick bamboo, still corresponds the air current distribution section of thick bamboo that the flow damper slope was equipped with a plurality of intercommunication gas storage cavity on the inner wall of a cooling section of thick bamboo, and air current distribution section of thick bamboo orientation is rather than relative and be in the flow damper of its below, and the lower port of a cooling section of thick bamboo still is connected with material storage ware. The utility model solves the problems of the prior art that the protein powder is bonded and hardened due to slow heat dissipation in the conveying process; and the protein powder is easy to adhere to the inner wall of the material storage device, so that the stable discharge of the protein powder cannot be realized, and the continuity of subsequent production equipment is influenced.

Description

Automatic temperature reducing device for protein powder discharging

Technical Field

The utility model relates to a albumen powder unloader technical field, concretely relates to automatic heat sink of albumen powder unloading.

Background

Starch belongs to the wet end chemicals of papermaking, and protein powder is a byproduct in the starch production process. Corn is widely planted, has sufficient sources of goods, low price, high starch content, low cost and easy processing, so the corn becomes a main raw material for starch production and can be used for producing modified starch, and the starch and the modified starch can be used as papermaking chemicals. In the production process of starch, in order to improve the economic value of corn, the by-product of the starch is subjected to resource utilization. The protein powder is one of the byproducts, can be prepared by concentrating, dehydrating and drying the protein separated from the corn, can be used for producing alcohol-soluble protein, bioactive peptide, amino acid, functional food ingredients and pigment, and can be prepared by concentrating, dehydrating and drying the protein separated from the corn.

The intellectual property office of china has disclosed a patent that application number is 201920268993.9, and this scheme includes support and auger conveyor, the inlet pipe is installed to auger conveyor's lower extreme, install the pipeline on the support, the inside of pipeline is pegged graft and is had the bearing, the inside of bearing is pegged graft and is had a sieve section of thick bamboo, the ring gear is installed to the one end of a sieve section of thick bamboo, the bottom meshing of ring gear is connected with the gear, the gear key-joint is on the output shaft of motor, the opening has been seted up on the surface of pipeline, the internally mounted of draw-in groove has the PVC scrubbing brush, the orificial opposite side is equipped with fixing device. The utility model discloses an auger conveyer carries rice protein powder to a sieve section of thick bamboo in, opens the motor and passes through ring gear and gear drive sieve section of thick bamboo and rotate, screens rice protein powder, in sieve section of thick bamboo pivoted, sieve section of thick bamboo and PVC scrubbing brush take place the friction, and the PVC scrubbing brush is favorable to scraping remaining rice protein powder on the sieve mesh, prevents that rice protein powder from plugging up the sieve mesh.

The device gradually exposes the defects of the technology along with the use, and mainly shows the following aspects:

firstly, the albumen powder is in transportation process, and the heat dissipation is slow, bonds easily, hardens to influence product quality, cause the wasting of resources, reduce product productivity effect.

Secondly, the albumen powder easily adheres to on the inner wall of stocker for can't realize the stable ejection of compact of albumen powder, influence the continuity of follow-up production facility.

In view of the above, the prior art is obviously inconvenient and disadvantageous in practical use, and needs to be improved.

SUMMERY OF THE UTILITY MODEL

Aiming at the defects in the prior art, the utility model provides an automatic temperature reduction device for protein powder blanking, which is used for solving the problems of bonding and hardening caused by slow heat dissipation in the process of conveying protein powder in the traditional technology; and the protein powder is easy to adhere to the inner wall of the material storage device, so that the stable discharge of the protein powder cannot be realized, and the continuity of subsequent production equipment is influenced.

In order to achieve the above object, the utility model provides a following technical scheme:

an automatic protein powder blanking cooling device comprises a cooling cylinder, wherein two groups of flow retarding plates which are obliquely and downwards arranged in parallel are oppositely arranged on the inner wall of the cooling cylinder, and the two groups of flow retarding plates are alternately arranged; the wall of the cooling cylinder is double-layer arranged and forms a gas storage cavity through an interlayer, the outer wall of the cooling cylinder is fixedly connected with a cold air conveying cylinder communicated with the gas storage cavity, the inner wall of the cooling cylinder is obliquely provided with a plurality of gas flow distribution cylinders communicated with the gas storage cavity, the gas flow distribution cylinders face to the baffle plate opposite to the baffle plate and below the baffle plate, the lower port of the cooling cylinder is further connected with a material storage device, and a material guide-out mechanism is arranged in the material storage device.

As an optimized scheme, the material storage device comprises a storage cylinder coaxially and fixedly connected with the lower port of the cooling cylinder, the lower port of the storage cylinder is fixedly connected with a bottom plate, and the lower surface of the bottom plate is further fixedly connected with a discharge cylinder communicated with the inner cavity of the storage cylinder.

As an optimized scheme, the guiding mechanism comprises a rotating shaft rotatably mounted in the center of the bottom plate, two discharging plates are uniformly distributed on the rotating shaft, and the lower surfaces of the discharging plates are in friction contact with the upper surface of the bottom plate.

As an optimized scheme, the end parts of the two discharging plates are respectively and fixedly connected with a scraping plate which is vertically arranged, and the side wall of the scraping plate is in frictional contact with the inner wall of the storage cylinder.

As an optimized scheme, the scraping plates are arranged in a spiral shape, and a material conveying surface is formed by the spiral lower surfaces of the scraping plates.

As an optimized scheme, the discharging plate is an arc-shaped plate, and the rotating shaft is rotatably arranged along the outward protruding direction of the arc-shaped plate.

As an optimized scheme, the outlet of the air flow distribution cylinder is fixedly connected with a filter screen.

As an optimized scheme, a driving machine is fixedly connected to the lower surface of the bottom plate, the lower end portion of the rotating shaft extends to the lower portion of the bottom plate and is fixedly connected with a driving gear, and the output end of the driving machine is meshed with the driving gear.

As an optimized scheme, the upper end part of the cooling cylinder is fixedly connected with a top plate, and a feeding cylinder communicated with the inner cavity of the cooling cylinder is fixedly connected to the top plate.

As an optimized scheme, an exhaust fan communicated with the inner cavity of the cooling cylinder is further fixedly connected to the top plate.

As an optimized scheme, a pulse dust collector is connected to the cold air conveying cylinder.

Compared with the prior art, the beneficial effects of the utility model are that:

the protein powder is quickly cooled by introducing cold air through the cooling cylinder, the descending speed of the protein powder is reduced through the slow flow plate, the contact time of the protein powder and the cold air is prolonged, the cooling efficiency is greatly improved, and the phenomena of bonding and hardening are reduced; the material adhered to the inner wall is scraped through the discharge plate and the scraper in the storage cylinder below, the material can be guided, the material can be smoothly guided out, and the production continuity of subsequent production equipment is ensured; the stability in the working process is improved; the parts are few, the working procedure is simple and convenient, and the failure rate is low; the structure is simple, and the service life is long; simple and convenient operation and control, easy large-scale manufacture and installation and wide application range.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the embodiments or the technical solutions in the prior art will be briefly described below. Throughout the drawings, like elements or portions are generally identified by like reference numerals. In the drawings, elements or portions are not necessarily drawn to scale.

Fig. 1 is a schematic structural view of the present invention;

in the figure: 1-a cooling cylinder; 2-a storage cylinder; 3, a buffer plate; 4-a gas flow distribution cylinder; 5-filtering the screen; 6-cold air conveying cylinder; 7-a scraper; 8-a stripper plate; 9-a rotating shaft; 10-a driver; 11-a discharge cylinder; 12-a feed cylinder; 13-exhaust fan.

Detailed Description

Embodiments of the present invention will be described in detail below with reference to the accompanying drawings. The following examples are only for illustrating the technical solutions of the present invention more clearly, and therefore are only examples, and the protection scope of the present invention is not limited thereby.

As shown in fig. 1, the automatic cooling device for protein powder blanking comprises a cooling cylinder 1, wherein two groups of flow slowing plates 3 which are obliquely and downwards arranged in parallel are oppositely arranged on the inner wall of the cooling cylinder 1, and the two groups of flow slowing plates 3 are alternately arranged; the double-deck setting of section of thick bamboo wall of a cooling section of thick bamboo 1 forms the gas storage cavity through its intermediate layer, the rigid coupling has the air conditioning of intercommunication gas storage cavity to carry a section of thick bamboo 6 on the outer wall of a cooling section of thick bamboo 1, air conditioning carries a section of thick bamboo 6 accessible compressor to improve the air conditioning air current, it is equipped with a plurality of intercommunication gas storage cavity's air current distribution section of thick bamboo 4 still to correspond the 3 slopes of air current baffle on the inner wall of a cooling section of thick bamboo 1, air current distribution section of thick bamboo 4 orientation is relative rather than and is in the air current baffle 3 of its below, the lower port.

The material storage device comprises a storage barrel 2 coaxially and fixedly connected with the lower port of the cooling barrel 1, the lower port of the storage barrel 2 is fixedly connected with a bottom plate, and the lower surface of the bottom plate is further fixedly connected with a discharging barrel 11 communicated with the inner cavity of the storage barrel 2.

The derivation mechanism is including rotating the pivot 9 of installing in the bottom plate center, and the equipartition has two stripper 8 on the pivot 9, and the lower surface of stripper 8 and the upper surface friction contact of bottom plate realize striking off the material thing on the bottom plate.

The end parts of the two stripper plates 8 are also respectively fixedly connected with a scraper 7 vertically arranged, and the side wall of the scraper 7 is in frictional contact with the inner wall of the storage cylinder 2, so that materials on the side wall can be scraped.

The scraping plate 7 is spirally arranged, and a material conveying surface is formed by the spiral lower surface of the scraping plate, so that materials are conveyed downwards.

The stripper 8 is the arc, and the pivot 9 rotates along the evagination direction rotation setting of arc, has not only realized scraping to realized carrying the direction of material thing, makeed material thing to discharge from the stripper 11.

The outlet of the airflow distribution cylinder 4 is also fixedly connected with a filter screen 5.

The lower surface of the bottom plate is fixedly connected with a driving machine 10, the lower end part of the rotating shaft 9 extends to the lower part of the bottom plate and is fixedly connected with a driving gear, and the output end of the driving machine 10 is meshed with the driving gear.

The upper end of the cooling cylinder 1 is fixedly connected with a top plate, and the top plate is fixedly connected with a feeding cylinder 12 communicated with the inner cavity of the cooling cylinder 1.

An exhaust fan 13 communicated with the inner cavity of the cooling cylinder 1 is further fixedly connected to the top plate, so that air circulation is realized.

The pulse dust collector is connected to the cold air conveying cylinder 6, the pulse dust collector filters cold air, and the pulse air flow is used for blowing the cold air to discharge, so that the heat exchange efficiency of materials is improved.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; although the present invention has been described in detail with reference to the foregoing embodiments, it should be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; such modifications and substitutions do not substantially depart from the scope of the embodiments of the present invention, and are intended to be covered by the claims and the specification.

Claims (10)

1. An automatic heat sink of albumen powder unloading which characterized in that: the cooling device comprises a cooling cylinder (1), wherein two groups of flow baffles (3) which are obliquely arranged downwards in parallel are oppositely arranged on the inner wall of the cooling cylinder (1), and the two groups of flow baffles (3) are alternately arranged; the double-deck setting of section of thick bamboo wall of cooling section of thick bamboo (1) forms the gas storage cavity through its intermediate layer, the rigid coupling has the intercommunication on the outer wall of a cooling section of thick bamboo (1) the air conditioning of gas storage cavity carries a section of thick bamboo (6), still correspond on the inner wall of a cooling section of thick bamboo (1) the oblique a plurality of intercommunication of flow damper (3) is equipped with a plurality of intercommunication the gas flow distribution section of thick bamboo (4) of gas storage cavity, gas flow distribution section of thick bamboo (4) orientation rather than relative and be in its below flow damper (3), the lower port of a cooling section of thick bamboo (1) still is connected with material storage ware, be equipped with material guide-out mechanism.

2. The automatic protein powder discharging cooling device according to claim 1, characterized in that: the material storage device comprises a storage cylinder (2) coaxially fixedly connected with a lower port of the cooling cylinder (1), a bottom plate is fixedly connected with a lower port of the storage cylinder (2), and a discharge cylinder (11) communicated with an inner cavity of the storage cylinder (2) is fixedly connected to the lower surface of the bottom plate.

3. The automatic protein powder discharging cooling device according to claim 2, characterized in that: the guiding mechanism comprises a rotating shaft (9) rotatably installed on the center of the bottom plate, two discharging plates (8) are uniformly distributed on the rotating shaft (9), and the lower surfaces of the discharging plates (8) are in friction contact with the upper surface of the bottom plate.

4. An automatic temperature-reducing device for protein powder blanking according to claim 3, which is characterized in that: the end parts of the two discharging plates (8) are respectively and fixedly connected with a scraper (7) which is vertically arranged, and the side wall of the scraper (7) is in friction contact with the inner wall of the storage cylinder (2).

5. An automatic temperature-reducing device for protein powder blanking according to claim 4, which is characterized in that: the scraping plate (7) is spirally arranged, and a material conveying surface is formed by the spiral lower surface of the scraping plate.

6. An automatic temperature-reducing device for protein powder blanking according to claim 5, which is characterized in that: the discharging plate (8) is an arc-shaped plate, and the rotating shaft (9) is arranged in a rotating mode along the outward protruding direction of the arc-shaped plate.

7. The automatic protein powder discharging cooling device according to claim 1, characterized in that: the outlet of the airflow distribution cylinder (4) is also fixedly connected with a filter screen (5).

8. An automatic temperature-reducing device for protein powder blanking according to claim 3, which is characterized in that: the lower surface of bottom plate rigid coupling has driver (10), the lower tip of pivot (9) extends to the below of bottom plate and rigid coupling has drive gear, the output of driver (10) with drive gear meshes mutually.

9. The automatic protein powder discharging cooling device according to claim 1, characterized in that: the upper end of the cooling cylinder (1) is fixedly connected with a top plate, and a feeding cylinder (12) communicated with the inner cavity of the cooling cylinder (1) is fixedly connected to the top plate.

10. An automatic temperature-reducing device for protein powder blanking according to claim 9, characterized in that: and the top plate is also fixedly connected with an exhaust fan (13) communicated with the inner cavity of the cooling cylinder (1).

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