CN216827219U - Particle screening device for probiotic production - Google Patents

Abstract

The application provides a granule screening plant is used in probiotic production belongs to probiotic production technical field. This particle screening plant is used in probiotic production includes screening subassembly and categorised subassembly. The screening assembly comprises a support, three shunting boxes, screening winnowing, an outer pipe and an inner pipe, wherein the shunting boxes are fixedly connected with the support, the screening winnowing is at least three, all the screening winnowing is fixedly connected with the outer pipe, the inner pipe is fixedly connected with the outer pipe, the outer pipe and the inner pipe are rotatably connected with the support, the classification assembly comprises a driving part and an annular groove, the driving part and the annular groove are fixedly connected with the support, the driving part is fixedly connected with the inner pipe, and an outlet at the lower end of the outer pipe is aligned to the annular groove. In the present application, the screening assembly can improve the screening speed and screening effect and maintain a smaller overall volume.

Description

Particle screening device for probiotic production

Technical Field

The application relates to the technical field of probiotic production, and particularly relates to a particle screening device for probiotic production.

Background

The probiotics are microorganisms beneficial to human health, can maintain the health balance of intestinal tracts, mainly comprise bifidobacterium and lactobacillus, and have the functions of health care of the intestinal tracts, immunity enhancement, regulation and the like. In the production process of probiotics, manufacturing raw materials of probiotic powder need to be crushed, and the crushing is difficult to ensure the uniformity of the size, so that crushed probiotic particles need to be screened.

The raw materials granule volume is big and little, and current sieving mechanism is in order to guarantee the screening speed, then the screening effect can't be guaranteed, and great granule directly drops into the fermentation production on next step and can influence the fermentation production of probiotic to cause the waste of raw materials, if adopt a plurality of sieving mechanism, then the increase of volume and cost is unfavorable for the realization.

SUMMERY OF THE UTILITY MODEL

In order to make up for the above deficiencies, the present application provides a particle screening device for probiotic production, which aims to improve the problems mentioned in the background art.

The application provides a particle screening device is used in probiotic production, including screening subassembly and categorised subassembly.

The screening assembly comprises a support, three shunting boxes, screening winnowing, an outer pipe and an inner pipe, wherein the shunting boxes are fixedly connected with the support, the screening winnowing is at least three, all the screening winnowing is fixedly connected with the outer pipe, the inner pipe is fixedly connected with the outer pipe, the outer pipe and the inner pipe are rotatably connected with the support, the classification assembly comprises a driving part and an annular groove, the driving part and the annular groove are fixedly connected with the support, the driving part is fixedly connected with the inner pipe, and an outlet at the lower end of the outer pipe is aligned to the annular groove.

In the above scheme, probiotic particles to be screened are added into the diversion box, particles are respectively thrown into the outer edge area of the three sifting fans through the diversion box, the driving part drives the inner tube to rotate, so that the outer tube and the three sifting fans rotate together, the sifting fans are arranged in an inverted cone shape, the particles roll towards the central area along the sifting fans, larger particles enter the inner tube along the outer surface of the sifting fans, qualified particles leak into the sifting fans, then enter the outer tube and finally flow into the annular groove, the outer tube is in a rotating state, the annular groove can always collect the particles flowing out of the outer tube and collect the particles for subsequent treatment, the moving speed and the centrifugal force of the particles can be changed through the rotating speed of the sifting fans, so that the optimal screening effect can be conveniently adjusted, the diversion box only shunts a specified amount of particles for each sifting fan to reduce the accumulation of the particles, the screening effect is improved, in this embodiment, three sifting fans are provided, be axial array distribution, have less gap each other, be favorable to increasing more sieves the winnowing, can also keep less equipment volume after improving screening efficiency, to sum up, the screening subassembly can improve screening speed and screening effect and keep less overall volume.

Furthermore, the flow dividing box comprises a box body and a flow dividing pipe, and the box body is fixedly connected with the support.

Furthermore, the number of the shunt tubes is at least three, all the shunt tubes are communicated with the box body, and the outlet of each shunt tube corresponds to one sieve dustpan.

In the scheme, the shunt tubes throw the particles to the edge area of the sieve winnowing, so that the particles roll towards the center along the conical surface to be screened, the shunt tubes can control the amount of the particles shunted to each sieve winnowing through selection of different diameters so as to ensure the screening effect, and the arrangement of the conical surface can change the moving speed and the centrifugal force of the particles through adjustment of the rotating speed of the sieve winnowing, so that the optimal screening effect is conveniently adjusted.

Furthermore, the sifter comprises a screen and an outer cover, the screen is fixedly connected with the outer cover, and both the screen and the outer cover are fixedly connected with the outer pipe.

Furthermore, a connecting pipe is fixedly connected between the outer pipe and the inner pipe, the screen is communicated to the inner pipe through the corresponding connecting pipe, and the outer cover is communicated to the outer pipe.

In the above scheme, the granule rolls on the screen cloth, and big granule is stayed and is entered into the inner tube through the connecting pipe on the screen cloth, and qualified granule leaks from the screen cloth and falls into in the dustcoat, flows into between outer tube and the inner tube along the dustcoat, reaches the effect of screening, and the setting of connecting pipe is used for preventing that the granule after the screening from taking place the condition of compounding in getting into the outer tube to the joint strength of outer tube and inner tube has been increased.

Furthermore, the screening subassembly still includes the gyro wheel, gyro wheel evenly distributed fixes on the support, every the dustcoat corresponds at least three respectively the gyro wheel, all the gyro wheel respectively with correspond dustcoat roll connection.

In the above scheme, the sieve winnowing machine has the advantages that the sieve winnowing machine is large in size and thin, the structural strength is not high, dynamic balance is difficult to guarantee when the sieve winnowing machine rotates, the idler wheels are arranged to support the rolling sieve winnowing machine, the condition that the sieve winnowing machine shakes during rotation is prevented, and the overall structural strength is improved.

Furthermore, the driving part comprises a motor and a main gear, the motor is fixedly connected with the bracket, and the main gear is fixedly connected with an output shaft of the motor.

Furthermore, the driving member further comprises a driven gear, the driven gear is fixedly connected with the inner tube, and the driven gear is meshed with the main gear.

In the scheme, the motor drives the inner pipe to rotate through the meshing of the main gear and the auxiliary gear, the screen winnowing is finally driven to rotate, the rotating speed of the screen winnowing is changed through adjusting the rotating speed of the motor, the moving speed and the centrifugal force of particles are finally changed, and the optimal screening effect is conveniently adjusted.

Further, the classification component also comprises a discharge pipe, the discharge pipe is communicated with the annular groove, and the inner pipe movably penetrates through the annular groove and the support.

Further, categorised subassembly is still including the skip, the skip is provided with two, two the skip corresponds respectively the inner tube with arrange the material pipe.

In the scheme, the qualified particles in the outer pipe are poured into the annular groove, the outlet at the lower end of the outer pipe rotates along with the sieve winnowing, the annular groove can still be accurately collected and is discharged into the skip car right below through the discharge pipe, and the larger particles directly fall into the other skip car below through the inner pipe, so that the classified collection of the large particles and the small particles is completed.

Drawings

In order to more clearly explain the technical solutions of the embodiments of the present application, the drawings that are required to be used in the embodiments will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present application and therefore should not be considered as limiting the scope, and that for those skilled in the art, other related drawings can be obtained from these drawings without inventive effort.

Fig. 1 is a schematic structural diagram of a particle screening device for probiotic production provided by an embodiment of the application;

fig. 2 is a schematic structural view of a connection relationship between a flow distribution box and a bracket according to an embodiment of the present application;

FIG. 3 is an enlarged view of a portion of the structure at A in FIG. 1 according to an embodiment of the present disclosure;

fig. 4 is a schematic view of a partially enlarged structure at B in fig. 1 according to an embodiment of the present disclosure.

In the figure: 100-a screening component; 110-a scaffold; 120-a flow splitting box; 121-a box body; 122-a shunt tube; 130-sieving and winnowing; 131-a screen mesh; 132-a housing; 140-an outer tube; 150-inner tube; 160-connecting pipe; 170-a roller; 200-a classification component; 210-a driver; 211-a motor; 212-a main gear; 213-slave gear; 220-an annular groove; 230-a discharge pipe; 240-skip car.

Detailed Description

The technical solutions in the present application will be described below with reference to the drawings in the present application.

To make the objects, technical solutions and advantages of the embodiments of the present application clearer, the technical solutions of the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are some embodiments of the present application, but not all embodiments. All other embodiments obtained by a person of ordinary skill in the art without any inventive work based on the embodiments in the present application are within the scope of protection of the present application.

Referring to fig. 1, the present application provides a particle screening device for probiotic production, which comprises a screening component 100 and a sorting component 200.

Among other things, the screen assembly 100 may increase the screening speed and effectiveness and maintain a smaller overall volume.

Referring to fig. 1 to 4, the screening assembly 100 includes a support 110, a distribution box 120, three screening pans 130, an outer tube 140 and an inner tube 150, the distribution box 120 is fixedly connected to the support 110, the number of the screening pans 130 is at least three, all the screening pans 130 are fixedly connected to the outer tube 140, the inner tube 150 is fixedly connected to the outer tube 140, the outer tube 140 and the inner tube 150 are rotatably connected to the support 110, the sorting assembly 200 includes a driving member 210 and an annular groove 220, the driving member 210 and the annular groove 220 are fixedly connected to the support 110, the driving member 210 is fixedly connected to the inner tube 150, and an outlet at a lower end of the outer tube 140 is aligned to the annular groove 220. Probiotic particles to be screened are added into the diversion box 120, particles are respectively thrown into the outer edge area of the three sifting pans 130 through the diversion box 120, the driving element 210 drives the inner pipe 150 to rotate, so the outer pipe 140 and the three sifting pans 130 rotate together, the sifting pans 130 are arranged in an inverted cone shape, the particles roll towards the central area along the sifting pans 130, larger particles enter the inner pipe 150 along the outer surface of the sifting pans 130, qualified particles leak into the sifting pans 130, then enter the outer pipe 140, and finally flow into the annular groove 220, wherein the outer pipe 140 is in a rotating state, the annular groove 220 can always collect the particles flowing out of the outer pipe 140 and collect the particles for subsequent treatment, the moving speed and the centrifugal force of the particles can be changed through the rotating speed of the sifting pans 130, the optimal sifting effect is convenient to adjust, the diversion box 120 only diverts a specified amount of particles to each sifting pan 130, so as to reduce the accumulation of the particles, improve the screening effect, sieve the winnowing 130 in this embodiment is provided with threely, is axial array distribution, has less gap each other, is favorable to increasing more sieve winnowing 130, can also keep less equipment volume after improving the screening efficiency, to sum up, the screening subassembly 100 can improve screening speed and screening effect and keep less overall volume.

The shunt box 120 comprises a box body 121 and a shunt tube 122, and the box body 121 is fixedly connected with the bracket 110. At least three shunt tubes 122 are arranged, all the shunt tubes 122 are communicated with the box body 121, and the outlet of each shunt tube 122 corresponds to one sieving dustpan 130. The shunt tubes 122 are used for throwing the particles to the edge area of the sieving winnowing 130, so that the particles roll towards the center along the conical surface for sieving, the shunt tubes 122 can control the amount of the particles shunted to each sieving winnowing 130 through selection of different diameters so as to ensure the sieving effect, and the arrangement of the conical surface can change the moving speed and the centrifugal force of the particles through adjustment of the rotating speed of the sieving winnowing 130, so that the optimal sieving effect is conveniently adjusted.

Referring to fig. 1 to 4, the sifter pan 130 includes a screen 131 and an outer cover 132, the screen 131 is fixedly connected to the outer cover 132, and both the screen 131 and the outer cover 132 are fixedly connected to the outer tube 140. A connecting pipe 160 is fixedly connected between the outer pipe 140 and the inner pipe 150, the screen 131 is communicated to the inner pipe 150 through the corresponding connecting pipe 160, and the outer cover 132 is communicated to the outer pipe 140. The particles roll on the screen 131, large particles are left on the screen 131 and enter the inner pipe 150 through the connecting pipe 160, qualified particles fall into the outer cover 132 from the screen 131 and flow into the space between the outer pipe 140 and the inner pipe 150 along the outer cover 132, the screening effect is achieved, the connecting pipe 160 is used for preventing the screened particles from mixing in the outer pipe 140, and the connecting strength of the outer pipe 140 and the inner pipe 150 is increased.

The screening assembly 100 further includes rollers 170, the rollers 170 are uniformly distributed and fixed on the bracket 110, each of the housings 132 corresponds to at least three rollers 170, and all the rollers 170 are respectively connected with the corresponding housings 132 in a rolling manner. The screen dustpan 130 has a large and thin volume and low structural strength, and is difficult to ensure dynamic balance when rotating, the roller 170 is arranged to support the rolling screen dustpan 130, so that the screen dustpan 130 is prevented from shaking during rotation, and the overall structural strength is improved.

Referring to fig. 1 to 4, the driving member 210 includes a motor 211 and a main gear 212, the motor 211 is fixedly connected to the bracket 110, and the main gear 212 is fixedly connected to an output shaft of the motor 211. The driving member 210 further comprises a driven gear 213, the driven gear 213 is fixedly connected with the inner tube 150, and the driven gear 213 is engaged with the main gear 212. The motor 211 drives the inner tube 150 to rotate through the engagement of the main gear 212 and the slave gear 213, and finally drives the sifting dustpan 130 to rotate, and the rotation speed of the sifting dustpan 130 is changed through the adjustment of the rotation speed of the motor 211, and finally the moving speed and the centrifugal force of the particles are changed, so that the optimal screening effect is conveniently adjusted.

Referring to fig. 1 to 4, the sorting assembly 200 further includes a discharge pipe 230, the discharge pipe 230 is communicated with the annular groove 220, and the inner pipe 150 movably penetrates through the annular groove 220 and the support 110. The sorting assembly 200 further comprises two skip cars 240, and the two skip cars 240 correspond to the inner pipe 150 and the discharge pipe 230 respectively. The qualified granules in the outer tube 140 are poured into the annular groove 220, the outlet at the lower end of the outer tube 140 rotates along with the sieving winnowing 130, the annular groove 220 can still accurately collect the granules, the granules are discharged into the skip 240 which is opposite to the lower part through the discharge pipe 230, and the larger granules directly fall into the other skip 240 which is opposite to the lower part through the inner tube 150, so that the classification and collection of the large granules and the small granules are completed.

This granule screening plant is used in probiotic production's theory of operation: probiotic particles to be screened are added into the diversion box 120, particles are respectively thrown to the outer edge areas of the three sifting fans 130 through the diversion box 120, the motor 211 drives the inner tube 150 to rotate through the meshing of the main gear 212 and the driven gear 213, finally the three sifting fans 130 are driven to rotate together, the sifting fans 130 are arranged in a reverse cone shape, the particles roll to the central area along the sifting fans 130, larger particles enter the inner tube 150 along the outer surface of the sifting fans 130, qualified particles leak into the sifting fans 130, then enter the outer tube 140, finally flow into the annular groove 220, the outer tube 140 is in a rotating state, the annular groove 220 can always collect the particles flowing out of the outer tube 140 and collect for subsequent processing, the moving speed and centrifugal force of the particles can be changed through the rotating speed of the sifting fans 130, the optimal screening effect can be conveniently adjusted, the diversion box 120 only diverts a specified amount of particles to each sifting fan 130, in order to reduce the condition that the granule is piled up, improve the screening effect, sieve the winnowing fan 130 in this embodiment is provided with threely, is axial array distribution, has less gap each other, is favorable to increasing more sieve winnowing fans 130, can also keep less equipment volume after improving the screening efficiency, to sum up, screening subassembly 100 can improve screening speed and screening effect and keep less overall volume.

It should be noted that the specific model specifications of the box 121, the roller 170, the motor 211, the main gear 212, the secondary gear 213, and the skip 240 need to be determined according to the actual specification of the device, and the specific model selection calculation method adopts the prior art, so detailed description is omitted.

The power supply of the motor 211 and its principle will be clear to a person skilled in the art and will not be described in detail here.

The above embodiments are merely examples of the present application and are not intended to limit the scope of the present application, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, improvement and the like made within the spirit and principle of the present application shall be included in the protection scope of the present application. It should be noted that: like reference numbers and letters refer to like items in the following figures, and thus, once an item is defined in one figure, it need not be further defined and explained in subsequent figures.

The above description is only for the specific embodiments of the present application, but the scope of the present application is not limited thereto, and any person skilled in the art can easily conceive of the changes or substitutions within the technical scope of the present application, and shall be covered by the scope of the present application. Therefore, the protection scope of the present application shall be subject to the protection scope of the claims.

Claims (10)

1. Particle screening device for probiotic production is characterized by comprising

The screening assembly (100) comprises a support (110), a flow distribution box (120), screening pans (130), an outer pipe (140) and an inner pipe (150), wherein the flow distribution box (120) is fixedly connected with the support (110), at least three screening pans (130) are arranged, all the screening pans (130) are fixedly connected with the outer pipe (140), the inner pipe (150) is fixedly connected with the outer pipe (140), and the outer pipe (140) and the inner pipe (150) are rotatably connected with the support (110);

categorised subassembly (200), categorised subassembly (200) including driving piece (210) and ring channel (220), driving piece (210) with ring channel (220) all with support (110) fixed connection, driving piece (210) with inner tube (150) fixed connection, outer tube (140) lower extreme export is aimed at ring channel (220).

2. The particle screening device for probiotic production according to claim 1, wherein the flow dividing box (120) comprises a box body (121) and a flow dividing pipe (122), and the box body (121) is fixedly connected with the bracket (110).

3. The particle screening device for probiotic production according to claim 2, wherein at least three shunt tubes (122) are provided, all the shunt tubes (122) are communicated with the box body (121), and the outlet of each shunt tube (122) corresponds to one screening dustpan (130).

4. The particle screening device for probiotic production according to claim 1, wherein the screening pan (130) comprises a screen (131) and a housing (132), the screen (131) is fixedly connected with the housing (132), and both the screen (131) and the housing (132) are fixedly connected with the outer tube (140).

5. The particle screening device for probiotic production according to claim 4, wherein a connecting pipe (160) is fixedly connected between the outer pipe (140) and the inner pipe (150), the screen (131) is communicated to the inner pipe (150) through the corresponding connecting pipe (160), and the outer cover (132) is communicated to the outer pipe (140).

6. The particle screening device for probiotic production according to claim 5, wherein the screening assembly (100) further comprises rollers (170), the rollers (170) are uniformly distributed and fixed on the bracket (110), each of the at least three rollers (170) corresponds to each of the at least three outer covers (132), and all the rollers (170) are respectively in rolling connection with the corresponding outer covers (132).

7. The particle screening device for probiotic production according to claim 1, wherein the driving member (210) comprises a motor (211) and a main gear (212), the motor (211) is fixedly connected with the bracket (110), and the main gear (212) is fixedly connected with an output shaft of the motor (211).

8. The particle screening device for probiotic production according to claim 7, wherein the driving member (210) further comprises a slave gear (213), the slave gear (213) is fixedly connected to the inner tube (150), and the slave gear (213) is engaged with the master gear (212).

9. The particle screening device for probiotic production according to claim 1, wherein the classification component (200) further comprises a discharge pipe (230), the discharge pipe (230) is communicated with the annular groove (220), and the inner pipe (150) movably penetrates through the annular groove (220) and the bracket (110).

10. The particle screening device for probiotic production according to claim 9, wherein the classification assembly (200) further comprises two skip cars (240), and the two skip cars (240) correspond to the inner pipe (150) and the discharge pipe (230), respectively.

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