CN222427864U - Automatic weighing and batching blending system - Google Patents

Abstract

The utility model discloses an automatic weighing and batching blending system, and relates to the technical field of batching correlation. The utility model comprises a proportioning bin, a material conveying sleeve and a material conveying bin, wherein the material conveying sleeves are symmetrically and fixedly communicated with the upper part of the peripheral side of the proportioning bin, three discharge pipes are fixedly and fixedly communicated with the top end of each discharge pipe through fixed plates on the upper part of the peripheral side of each material conveying sleeve, a supporting disc is movably connected in the material conveying bin, weighing sensors are symmetrically and fixedly arranged at the bottom ends of the supporting discs, and the bottoms of the weighing sensors are fixedly arranged at the bottoms in the material conveying bin. The utility model solves the problems that the weighing operation of the batching device is long in time consumption and the working efficiency is not high enough when the batching device works, and partial materials are easy to hang on an inclined surface and the material discharge is insufficient by arranging the batching bin, the conveying sleeve and the conveying bin.

Description

Automatic weighing and batching blending system

Technical Field

The utility model belongs to the technical field of ingredients, and particularly relates to an automatic weighing and ingredient mixing system.

Background

The batching device is a device used in various production processes, is mainly used for accurately mixing and distributing different raw materials so as to ensure the consistency of product quality and the high efficiency of the production process, is widely applied to industries such as food, pharmacy and chemical industry, can improve the production efficiency, reduce the errors of manual operation and labor intensity, and simultaneously ensure the consistency and the stability of the product quality, but has the following defects in actual use:

When the batching device works, materials are directly conveyed into the batching device for weighing and then conveyed into the bin, but different batching materials are required to be weighed and conveyed step by step in the using process, so that the operation is inconvenient;

The dosing unit is when working, mixes in carrying the feed bin through different material, mixes the back in the feed bin, needs to discharge the material, but in the during operation, in order to fully discharge the material, the bottom of feed bin is the bucket-shaped usually, but the material is on the face of slope, hangs partial material easily, and the material discharge is insufficient.

Disclosure of utility model

The utility model aims to provide an automatic weighing and batching blending system, which solves the problems that the weighing operation time is long, the working efficiency is not high enough, partial materials are easy to hang on an inclined surface, and the material discharge is insufficient when a batching device works by arranging a batching bin, a conveying sleeve and a conveying bin.

In order to solve the technical problems, the utility model is realized by the following technical scheme:

The utility model relates to an automatic weighing and material mixing system which comprises a material mixing bin, material conveying sleeves and material conveying bins, wherein the material conveying sleeves are symmetrically and fixedly communicated with the upper parts of the peripheral sides of the material mixing bins, three discharge pipes are fixedly communicated with the upper parts of the peripheral sides of the material conveying sleeves through equidistant fixing plates, the top ends of the discharge pipes are fixedly and fixedly communicated with the material conveying bins, supporting plates are movably connected in the material conveying bins, weighing sensors are symmetrically and fixedly arranged at the bottom ends of the supporting plates, the bottoms of the weighing sensors are fixedly arranged at the inner bottoms of the material conveying bins, materials are accommodated in the material conveying bins through the material mixing bins, the supporting plates are movably connected in the material conveying bins through the material conveying bins during operation, and the materials are intensively conveyed into the material mixing bins during operation through the material conveying sleeves.

Further, a first driving motor is fixed in the center of the top of the proportioning bin, a first transmission shaft is fixed at the output end of the first driving motor, a connecting plate is fixed at the lower part of one side of the transmission shaft in an annular array, and the proportioning bin drives the first transmission shaft to rotate through the first driving motor.

Further, the bottom of proportioning bins is the bucket shape, the one end that the transmission shaft one was kept away from to the connecting plate is fixed with scrapes the flitch, scrape the flitch setting on proportioning bins's inner wall for during operation, scrape the material on proportioning bins's inner wall.

Further, the bottom fixed intercommunication of proportioning bins has the output tube, the week side middle part of output tube is fixed with automatically controlled valve one, and during operation of proportioning bins is through the material discharge of output tube wherein, the transport break-make of output tube is controlled through automatically controlled valve one.

Further, one end of the material conveying sleeve, which is far away from the proportioning bin, is fixedly provided with a second driving motor, the output end of the second driving motor is fixedly provided with a second driving shaft, the second driving shaft penetrates through one end of the material conveying sleeve, which is far away from the proportioning bin, the two peripheral sides of the driving shaft in the material conveying sleeve are fixedly provided with helical blades, and the second driving motor drives the second driving shaft to rotate so as to drive the helical blades to rotate, so that materials are conveyed.

Further, the material conveying hole has been seted up vertically to the inside central authorities of supporting disk, the material conveying hole outside of supporting disk bottom is fixed with the inner tube, the week side upper portion of inner tube is fixed with automatically controlled valve two, the bottom of inner tube sets up the top at the discharge pipe, the top fixed intercommunication of material conveying storehouse has the input tube, and the during operation of supporting disk will ride on the material through the material conveying hole in carrying the inner tube, through the transport break-make of automatically controlled valve two control inner tubes.

The utility model has the following beneficial effects:

According to the utility model, the problems that weighing operation is long and working efficiency is not high enough when the batching device works are solved by arranging the material conveying sleeve and the material conveying bin, when the material conveying bin works, materials are conveyed into the material conveying bin through the input pipe and are supported by the supporting disc in the material conveying bin, after weighing is carried out by the weighing sensor, the weight of the materials is determined, the second electric control valve on the peripheral side of the inner pipe is started, so that the materials on the supporting disc are conveyed into the inner pipe through the material conveying hole and then conveyed into the discharge pipe through the inner pipe, the materials are conveyed into the material conveying sleeve through the discharge pipe, the second driving motor drives the transmission shaft to rotate, the spiral blade is driven to rotate, and the materials entering the material conveying sleeve are spirally mixed and conveyed into the batching bin through the rotation of the spiral blade, so that weighing operation is shorter in working, and the working efficiency is higher.

According to the utility model, the problem that partial materials are easy to hang on an inclined surface in the proportioning device and insufficient in material discharge is solved by arranging the proportioning device, after the materials are conveyed into the proportioning device, the driving motor I is started, the driving motor I drives the driving shaft I to rotate, the connecting plate is driven to rotate through the rotation of the driving shaft I, the scraping plate is driven to rotate through the rotation of the connecting plate, the materials in the inner wall of the proportioning device are scraped through the rotation of the scraping plate, the deposition of the materials on the bottom in the proportioning device is reduced, the materials in the proportioning device are more difficult to hang on the inclined surface, and the material discharge is more sufficient.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present utility model, the drawings that are needed for the description of the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present utility model, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a perspective view of an assembled structure of an automatic weighing and blending system;

FIG. 2 is a perspective view of a part of a sectional structure of a proportioning bin;

FIG. 3 is a perspective view of a partial cross-sectional structure of a material conveying sleeve;

FIG. 4 is a perspective view of a partial cross-sectional structure of the conveying bin;

Fig. 5 is an enlarged view of the structure at a in fig. 4.

Reference numerals:

1. Proportioning bins 101, driving motors I, 102, transmission shafts I, 103, connecting plates 104, scraping plates 105, output pipes 106, electric control valves I, 2, material conveying sleeves 201, driving motors II, 202, transmission shafts II, 203, spiral blades, 3, material conveying bins 301, supporting discs 302, material conveying holes 303, inner pipes 304, electric control valves II, 305, weighing sensors 306, output pipes 307 and input pipes.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Detailed description of the preferred embodiments

Referring to fig. 1-5, the utility model discloses an automatic weighing and material mixing system, which comprises a material mixing bin 1, material conveying sleeves 2 and material conveying bins 3, wherein the material conveying sleeves 2 are symmetrically and fixedly connected to the upper parts of the peripheral sides of the material mixing bin 1, when the material mixing bin 1 works, proportioned materials are contained in the material mixing bin, the materials are conveyed to the material mixing bin 1 through the material conveying sleeves 2, three discharge pipes 306 are equidistantly and fixedly connected to the upper parts of the peripheral sides of the material conveying sleeves 2, when the material conveying bin 3 works, the materials discharged from the material conveying bin 3 are conveyed to the material conveying sleeves 2 through the discharge pipes 306, the top ends of the discharge pipes 306 are fixedly connected to the material conveying bin 3, the materials entering the material conveying bin 3 are conveyed to the material conveying sleeve 2 through the discharge pipes 306 after being weighed, a supporting disc 301 is movably connected to the material conveying bin 3, weighing sensors 305 are symmetrically and fixedly arranged at the bottom parts of the material conveying bin 3, the material entering the material conveying bin 3 is supported by the supporting disc 301, and the material entering the material conveying bin 3 is weighed through the weighing sensors 305, and the material entering the material conveying bin 3 is determined.

Specifically, a first driving motor 101 is fixed in the center of the top of the proportioning bin 1, a first transmission shaft 102 is fixed at the output end of the first driving motor 101, a connecting plate 103 is fixed at the lower part of the periphery of the first transmission shaft 102 in an annular array, and when the proportioning bin 1 works, the first driving motor 101 drives the first transmission shaft 102 to rotate so as to drive the connecting plate 103 to rotate.

Further, the bottom of the proportioning bins 1 is in a bucket shape, one end, far away from the transmission shaft I102, of the connecting plate 103 is fixedly provided with a scraping plate 104, the scraping plate 104 is arranged on the inner wall of the proportioning bins 1, the scraping plate 104 is driven to rotate through rotation of the connecting plate 103, and materials in the inner wall of the proportioning bins 1 are scraped through rotation of the scraping plate 104, so that deposition of the materials at the bottom in the proportioning bins 1 is reduced.

Further, an output pipe 105 is fixedly communicated with the bottom end of the proportioning bin 1, an electric control valve I106 is fixed in the middle of the peripheral side of the output pipe 105, and when the proportioning bin 1 works, materials in the proportioning bin 1 are discharged through the output pipe 105, and the on-off of the transmission of the output pipe 105 is controlled through the electric control valve I106.

When the material conveying device works, after the material is conveyed into the proportioning bin 1, the first driving motor 101 is started, the first driving motor 101 drives the first transmission shaft 102 to rotate, the first transmission shaft 102 rotates to drive the connecting plate 103 to rotate, the scraping plate 104 is driven to rotate through the rotation of the connecting plate 103, the material in the inner wall of the proportioning bin 1 is scraped through the rotation of the scraping plate 104, and the deposition of the material at the bottom in the proportioning bin 1 is reduced.

Second embodiment

Referring to fig. 1, 3, 4 and 5, on the basis of the first embodiment, a second driving motor 201 is fixed at one end of the material conveying sleeve 2 away from the material mixing bin 1, a second driving shaft 202 is fixed at an output end of the second driving motor 201, the second driving shaft 202 penetrates through one end of the material conveying sleeve 2 away from the material mixing bin 1, a spiral blade 203 is fixed at a peripheral side of the second driving shaft 202 in the material conveying sleeve 2, and when the material conveying sleeve 2 works, the second driving motor 201 drives the second driving shaft 202 to rotate so as to drive the spiral blade 203 to rotate, and materials entering the material conveying sleeve 2 are spirally mixed and conveyed into the material mixing bin 1 through rotation of the spiral blade 203.

Specifically, the center inside the supporting plate 301 is vertically penetrated and provided with a material conveying hole 302, an inner pipe 303 is fixed on the outer side of the material conveying hole 302 at the bottom end of the supporting plate 301, an electric control valve II 304 is fixed on the upper part of the periphery side of the inner pipe 303, the bottom end of the inner pipe 303 is arranged at the top end of a discharge pipe 306, the top end of a material conveying bin 3 is fixedly communicated with an input pipe 307, the top end of the input pipe 307 is communicated with equipment for conveying various raw materials, the top end of the supporting plate 301 is concavely arranged, when the material conveying bin 3 works, the material is conveyed into the material conveying bin 3 through the input pipe 307, the material is supported by the supporting plate 301 in the material conveying bin 3, after weighing is carried out by a weighing sensor 305, the electric control valve II 304 on the periphery side of the inner pipe 303 is started, the material on the supporting plate 301 is conveyed into the inner pipe 303 through the material conveying hole 302, and then conveyed into the discharge pipe 306 through the inner pipe 303, and conveyed into the material conveying sleeve 2 through the discharge pipe 306.

When the material conveying bin 3 works, materials are conveyed into the material conveying bin 3 through an input pipe 307 and are supported by a supporting disc 301 in the material conveying bin 3, after the weight of the materials is determined by a weighing sensor 305, an electric control valve II 304 on the periphery of an inner pipe 303 is started, the materials on the supporting disc 301 are conveyed into the inner pipe 303 through a material conveying hole 302 and then conveyed into a discharge pipe 306 through the inner pipe 303, and conveyed into a material conveying sleeve 2 through the discharge pipe 306, a driving motor II 201 drives a transmission shaft II 202 to rotate to drive a spiral blade 203 to rotate, and the materials entering the material conveying sleeve 2 are spirally mixed and conveyed into a material mixing bin 1 through the rotation of the spiral blade 203.

In the description of the present specification, the descriptions of the terms "one embodiment," "example," "specific example," and the like, mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the present utility model. In this specification, schematic representations of the above terms do not necessarily refer to the same embodiments or examples. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The preferred embodiments of the utility model disclosed above are intended only to assist in the explanation of the utility model. The preferred embodiments are not exhaustive or to limit the utility model to the precise form disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the utility model and the practical application, to thereby enable others skilled in the art to best understand and utilize the utility model. The utility model is limited only by the claims and the full scope and equivalents thereof.

Claims (6)

1. The automatic weighing and material mixing system comprises a material mixing bin (1), a material conveying sleeve (2) and a material conveying bin (3), and is characterized in that the material conveying sleeve (2) is symmetrically and fixedly communicated with the upper part of the periphery of the material mixing bin (1), three discharge pipes (306) are fixedly communicated with the upper part of the periphery of each material conveying sleeve (2) through equidistant fixing plates, the material conveying bin (3) is fixedly communicated with the top end of each discharge pipe (306), a supporting disc (301) is movably connected in the material conveying bin (3), weighing sensors (305) are symmetrically and fixedly arranged at the bottom ends of the supporting discs (301), and the bottoms of the weighing sensors (305) are fixedly arranged at the bottoms of the material conveying bin (3).

2. The automatic weighing and batching blending system according to claim 1, wherein a first driving motor (101) is fixed in the center of the top of the batching bin (1), a first transmission shaft (102) is fixed at the output end of the first driving motor (101), and a connecting plate (103) is fixed at the lower part of the peripheral side of the first transmission shaft (102) in an annular array.

3. The automatic weighing and batching blending system according to claim 2, wherein the bottom end of the batching bin (1) is in a bucket shape, one end of the connecting plate (103) far away from the transmission shaft I (102) is fixedly provided with a scraping plate (104), and the scraping plate (104) is arranged on the inner wall of the batching bin (1).

4. The automatic weighing and batching blending system according to claim 1, wherein the bottom end of the batching bin (1) is fixedly communicated with an output pipe (105), and an electric control valve I (106) is fixed in the middle of the peripheral side of the output pipe (105).

5. The automatic weighing and batching blending system according to claim 1, wherein one end of the material conveying sleeve (2) far away from the batching bin (1) is fixedly provided with a second driving motor (201), the output end of the second driving motor (201) is fixedly provided with a second driving shaft (202), the second driving shaft (202) penetrates through one end of the material conveying sleeve (2) far away from the batching bin (1), and a spiral blade (203) is fixedly arranged on the peripheral side of the second driving shaft (202) in the material conveying sleeve (2).

6. The automatic weighing and batching blending system according to claim 1, wherein a material conveying hole (302) is vertically formed in the center of the inside of the supporting disc (301), an inner pipe (303) is fixed on the outer side of the material conveying hole (302) at the bottom end of the supporting disc (301), an electric control valve II (304) is fixed on the upper portion of the periphery of the inner pipe (303), the bottom end of the inner pipe (303) is arranged at the top end of a discharge pipe (306), and an input pipe (307) is fixedly communicated with the top end of the material conveying bin (3).