CN214609647U

CN214609647U - Multifunctional sphere feeding machine

Info

Publication number: CN214609647U
Application number: CN202120369892.8U
Authority: CN
Inventors: 王鸿飞; 王猛; 杨旭; 徐东安; 李伟; 孙巧玉; 单铁城; 朱正旺
Original assignee: Shenyang Amorphous Metal Materials Manufacturing Co ltd; Institute of Metal Research of CAS
Current assignee: Shenyang Amorphous Metal Materials Manufacturing Co ltd; Institute of Metal Research of CAS
Priority date: 2021-02-10
Filing date: 2021-02-10
Publication date: 2021-11-05
Anticipated expiration: 2031-02-10

Abstract

The utility model relates to a material loading machine field specifically is a multi-functional spheroid material loading machine, mainly includes: the device comprises a machine base, a first feeding hopper, a first slide rail, a second feeding hopper, a first roundness screening mechanism, a first charging bucket, a first slide way, a first induction module, a first induction signal receiver, a machine base support, a machine base upright post, a first pipeline, a first base, a second base, a rotating shaft, a second pipeline, a second slide rail, a third feeding hopper, a second roundness screening mechanism, a second induction module, a second slide way, a second charging bucket, a charging tray and a second induction signal receiver. The utility model discloses a to the structural design of a multi-functional spheroid material loading machine, make the spheroid material loading in succession and carry out the detection of some indexes, it is low to have solved current material loading machine degree of automation for the spheroid, does not possess the problem of screening function, possesses the advantage that degree of automation is high and the inspection function, and the spheroid can overcome frictional force at the uniform velocity material loading, makes spheroidal material loading detect the integration.

Description

Multifunctional sphere feeding machine

Technical Field

The utility model relates to a material loading machine field specifically is a multi-functional spheroid material loading machine.

Background

The material loading machine is also called a feeder or a feeder, is indispensable equipment for conveying products from a previous sequence to a next sequence for inspection or processing, and is divided into a belt type, a rotary type and an oscillating type, and the weight detection process of the high-strength and high-brittleness ball material is as follows: slide a spheroid and examine heavy equipment, present spheroid automatic feeding device can't overcome spheroid sliding friction power material loading, and the material loading speed can't reach steady at the uniform velocity material loading, can't carry out the inspection of other indexs of spheroid at the in-process of material loading and save time, detects an index and will use an equipment usually, has wasted a large amount of time and money, and it is troublesome to have caused unnecessary for a lot of work, has greatly influenced each major enterprise and user's work efficiency.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a multi-functional spheroid material loading machine possesses spheroid and stabilizes material loading, spheroid size screening, spheroid circularity screening, body classification counting function, and it has overcome on the existing market that the spheroid can't overcome the stable at the uniform velocity material loading of sliding friction power, and material loading machine function singleness's problem has improved work efficiency.

In order to realize the purpose, the technical scheme of the utility model is that:

a multi-functional spheroid material loading machine includes: frame, first feeding funnel, first slide track, second feeding funnel, first circularity screening mechanism, first storage bucket, first slide, first response module, first response signal receiver, frame support, frame stand, first pipeline, first base, second base, rotation axis, second pipeline, second slide track, third feeding funnel, second circularity screening mechanism, second response module, second slide, second storage bucket, second response signal receiver, concrete structure is as follows:

the machine base is provided with a machine base support, a machine base upright post, a first base and a second base, wherein the machine base support is a right-angle frame formed by integrating a vertical plate and a horizontal plate at the top of the vertical plate, the machine base upright post is vertically arranged at the bottom of the horizontal plate of the machine base support and is relatively parallel to the vertical plate of the machine base support, the first base is arranged on the outer side of the machine base upright post, the first material barrel and the second material barrel are obliquely arranged on the first base up and down, the second base is arranged between the machine base upright post and the vertical plate of the machine base support, and the second feeding hopper and the third feeding hopper are obliquely arranged on the second base up and down;

a first feeding hopper is arranged at the top of a horizontal plate of a machine base support, a rotating shaft is vertically arranged to penetrate through a bottom center hole of the first feeding hopper, a first pipeline communicated with an inner cavity of the first feeding hopper is arranged at the edge of the bottom of the first feeding hopper, the first pipeline vertically penetrates through the horizontal plate of the machine base support, an inclined first slide rail and an inclined second slide rail are arranged below the first pipeline and are arranged on the machine base support, the first slide rail and the second slide rail are vertically arranged, a lower end outlet of the first slide rail corresponds to a second feeding hopper on a second base, a lower end outlet of the second slide rail corresponds to a third feeding hopper on the second base, a second pipeline is vertically arranged at the bottom of the first slide rail, the upper end of the second pipeline is communicated with the first slide rail, and a lower end outlet of the second pipeline corresponds to the second slide rail;

a first roundness screening mechanism is obliquely arranged between the second feeding hopper and the first charging bucket, the upper end of the first roundness screening mechanism corresponds to a sample outlet of the second feeding hopper, the lower end of the first roundness screening mechanism corresponds to the first charging bucket through a first slide way, a first sensing module is arranged on the outer side of the first slide way, the first sensing module is connected with a first sensing signal receiver through a circuit, and the first slide rail, the second feeding hopper, the first roundness screening mechanism and the first charging bucket are sequentially arranged in an oblique line to form a first feeding line;

the second roundness screening mechanism is obliquely arranged between the third feeding hopper and the second charging bucket, the upper end of the second roundness screening mechanism corresponds to a sample outlet of the second feeding hopper, the lower end of the first roundness screening mechanism corresponds to the second charging bucket through a second slide, a second sensing module is arranged on the outer side of the second slide, the second sensing module is connected with a second sensing signal receiver through a circuit, and the second slide rail, the third feeding hopper, the second roundness screening mechanism and the second charging bucket are sequentially arranged in an oblique line to form a second feeding line.

The multifunctional sphere feeding machine is characterized in that a first motor is arranged on a horizontal plate of a stand bracket.

The multifunctional sphere feeding machine is characterized in that a second motor, a first induction signal receiver and a second induction signal receiver are arranged on the second base.

Multifunctional ball material loading machine, first circularity screening mechanism or second circularity screening mechanism are equipped with right screening track, left screening track, the track fixed plate, two track fixed plate relative parallel arrangement, install two sets of cylindrical biax roller between two track fixed plates, every group biax roller is right screening track, left screening track sets up the structure relatively, right screening track, the interval of left screening track and second feeding funnel or the corresponding one end of third feeding funnel sample outlet, be less than right screening track, the interval of left screening track and the corresponding one end of first storage bucket or second storage bucket.

The multifunctional sphere feeding machine is characterized in that a third motor is arranged on the first roundness screening mechanism, and the output end of the third motor is in transmission connection with the right screening track and the left screening track of the first roundness screening mechanism respectively; and the output end of the fourth motor is in transmission connection with the right screening track and the left screening track of the second roundness screening mechanism respectively.

The multifunctional sphere feeding machine is characterized in that a track fixing plate at one end, corresponding to the first charging bucket or the second charging bucket, of the right screening track and the left screening track is provided with a middle fixing part and two side moving parts, the moving parts are connected with the fixing parts through roundness specification fine-tuning bolts respectively, and the roundness specification fine-tuning bolts are used for adjusting the distance between the moving parts and the fixing parts and further adjusting the distance between one ends of the right screening track and the left screening track.

The utility model has the advantages and beneficial effects that:

1. the utility model discloses a structural design to a multi-functional spheroid material loading machine makes the spheroid material loading in succession and carries out the detection of some indexs, has filled the trade blank, has improved production efficiency. Therefore, the multifunctional feeding ball solves the problems that the ball cannot overcome sliding friction force for feeding, has a multi-purpose function, saves time, releases manpower and saves cost.

2. The utility model provides a current material loading machine for the spheroid degree of automation low, do not possess the problem of screening function, frictional force at the uniform velocity material loading can be overcome to the spheroid, makes spheroidal material loading detect the integration. This multi-functional spheroid material loading machine possesses degree of automation height and inspection function's advantage, is worth promoting.

Drawings

Fig. 1 is a schematic structural diagram of the present invention.

Fig. 2 is a schematic structural diagram of the feeding hopper.

Fig. 3 is a front view of the structure of the feeding tray.

Fig. 4 is a structural perspective view of the feeding tray.

Fig. 5 is a schematic structural view of the roundness screening mechanism.

In the drawings, each reference numeral and reference numeral name is: 1-a first feeding hopper, 2-a first motor, 3-a first slide rail, 4-a second feeding hopper, 5-a first roundness screening mechanism, 6-a second motor, 7-a third motor, 8-a first charging bucket, 9-a first slide way, 10-a first induction module, 11-a first induction signal receiver, 12-a base support, 13-a base upright column, 14-a first pipeline, 15-a first base, 16-a second base, 17-a rotating shaft, 18-a second pipeline, 19-a second slide rail, 20-a third feeding hopper, 21-a fourth motor, 22-a second roundness screening mechanism, 23-a second induction module, 24-a second slide way, 25-a second charging bucket, 26-a feeding tray, 27-U-shaped groove, 28-upper tray edge hole, 29-upper tray key slot hole, 30-gear-like disc, 31-disc, 32-roundness specification fine adjustment bolt, 33-right screening track, 34-left screening track, 35-track fixing plate, 36-second induction signal receiver, 37-fixing part and 38-movable part.

Detailed Description

Referring to fig. 1-5, the utility model provides a concrete example, a multi-functional spheroid material loading machine mainly includes: the frame, first feeding funnel 1, first motor 2, first slide track 3, second feeding funnel 4, first circularity screening mechanism 5, second motor 6, third motor 7, first storage bucket 8, first slide 9, first induction module 10, first induction signal receiver 11, frame support 12, frame stand 13, first pipeline 14, first base 15, second base 16, rotation axis 17, second pipeline 18, second slide track 19, third feeding funnel 20, fourth motor 21, second circularity screening mechanism 22, second induction module 23, second slide 24, second storage bucket 25, feeding disc 26, second induction signal receiver 36, etc., and the concrete structure is as follows:

the machine base is provided with a machine base support 12, a machine base upright column 13, a first base 15 and a second base 16, the machine base support 12 is a right-angle frame with a vertical plate and a top horizontal plate integrated, the machine base upright column 13 is vertically arranged at the bottom of the horizontal plate of the machine base support 12 and is relatively parallel to the vertical plate of the machine base support 12, the first base 15 is arranged on the outer side of the machine base upright column 13, the first material barrel 8 and the second material barrel 25 are vertically inclined and arranged on the first base 15, the second base 16 is arranged between the machine base upright column 13 and the vertical plate of the machine base support 12, the second feeding hopper 4 and the third feeding hopper 20 are vertically inclined and arranged on the second base 16, and the second base 16 is further provided with a second motor 6, a first induction signal receiver 11 and a second induction signal receiver 36.

The top of a horizontal plate of a machine base support 12 is provided with a first feeding hopper 1, a rotating shaft 17 is vertically arranged to penetrate through a central hole at the bottom of the first feeding hopper 1, the output end of a first motor 2 on the horizontal plate of the machine base support 12 is in transmission connection with the rotating shaft 17 through a chain, the bottom edge of the first feeding hopper 1 is provided with a first pipeline 14 communicated with the inner cavity of the first feeding hopper 1, the first pipeline 14 vertically penetrates through the horizontal plate of the machine base support 12, an inclined first slide rail 3 and a second slide rail 19 are arranged below the first pipeline 14 on the machine base support 12, the first slide rail 3 and the second slide rail 19 are arranged up and down, the lower end outlet of the first slide rail 3 corresponds to a second feeding hopper 4 on a second base 16, the lower end outlet of the second slide rail 19 corresponds to a third feeding hopper 20 on the second base 16, the bottom of the first slide rail 3 is vertically provided with a second pipeline 18, the upper end of the second duct 18 communicates with the first slide rail 3, and the lower end outlet of the second duct 18 corresponds to the second slide rail 19. When the sample with smaller granularity passes through the first slide rail 3, the sample falls into the second slide rail 19 through the second pipeline 18, so as to achieve the purpose of size screening.

The first roundness screening mechanism 5 is obliquely arranged between the second feeding hopper 4 and the first charging bucket 8, the third motor 7 is arranged on the first roundness screening mechanism 5, the upper end of the first roundness screening mechanism 5 corresponds to a sample outlet of the second feeding hopper 4, the lower end of the first roundness screening mechanism 5 corresponds to the first charging bucket 8 through a first slide 9, a first induction module 10 is arranged on the outer side of the first slide 9, the first induction module 10 is connected with a first induction signal receiver 11 through a circuit, the first slide rail 3, the second feeding hopper 4, the first roundness screening mechanism 5 and the first charging bucket 8 are sequentially arranged in an oblique line mode, and a first feeding circuit is formed. Every time the ball sample finally coming out of the first roundness screening mechanism 5 enters the first charging barrel 8 through the first slide way 9, the first sensing module 10 counts and then is displayed by the first sensing signal receiver 11, and the functions of classifying, counting and summarizing can be achieved. The rear side of the first material barrel 8 can be connected with other devices, such as: check weighing, and the like.

A second roundness screening mechanism 22 is obliquely arranged between the third feeding hopper 20 and the second charging bucket 25, a fourth motor 21 is arranged on the second roundness screening mechanism 22, the upper end of the second roundness screening mechanism 22 corresponds to a sample outlet of the second feeding hopper 4, the lower end of the first roundness screening mechanism 5 corresponds to the second charging bucket 25 through a second slide way 24, a second induction module 23 is arranged on the outer side of the second slide way 24, the second induction module 23 is connected with a second induction signal receiver 36 through a circuit, and the second slide rail 19, the third feeding hopper 20, the second roundness screening mechanism 22 and the second charging bucket 25 are sequentially arranged in an oblique line to form a second feeding circuit. When a ball sample finally discharged from the second roundness screening mechanism 22 enters the second material barrel 25 through the second slide way 24, the second sensing module 23 counts and then displays the ball sample by the second sensing signal receiver 36, so that the functions of classifying, counting and summarizing can be achieved. The rear side of the second charging barrel 25 can be connected with other devices, such as: check weighing, and the like.

As shown in fig. 2, 3 and 4, an upper material tray 26 is arranged at the bottom in the first upper material hopper 1, the second upper material hopper 4 or the third upper material hopper 20, an upper material tray keyed slot 29 is arranged at the center of the upper material tray 26, three rotating shafts are respectively arranged at the bottom center holes of the first upper material hopper 1, the second upper material hopper 4 and the third upper material hopper 20 and are in key connection with the upper material tray keyed slot 29, the upper material tray 26 is an integrated structure of a similar gear plate 30 and a disc 31 which are arranged up and down, the similar gear plate 30 and the disc 31 have the same outer diameter, U-shaped slots 27 are uniformly distributed at the edge of the similar gear plate 30 to form a similar gear structure, an upper material tray edge hole 28 corresponding to the U-shaped slot 27 is arranged at the edge of the disc 31, and the U-shaped slots 27 and the upper material tray edge holes 28 ensure that only one sample can be loaded at a time.

When the sample feeding device works, the output end of the first motor 2 is in transmission connection with the rotating shaft 17 through a chain, the rotating shaft 17 drives the feeding tray 26 to rotate, and when the feeding tray edge holes 28 correspond to the first pipeline 14, samples in the first feeding hopper 1 fall into the inclined first slide rail 3 through the feeding hopper edge holes 18 through the first pipeline 14. Similarly, the output end of the second motor 6 is in transmission connection with the rotating shaft on the second feeding hopper 4 through a chain, the rotating shaft drives the feeding tray 26 to rotate, and when the edge hole 28 of the feeding tray corresponds to the sample outlet of the second feeding hopper 4, the sample in the second feeding hopper 4 falls into the inclined first roundness screening mechanism 5 through the sample outlet from the edge hole 18 of the feeding hopper. Meanwhile, the output end of the second motor 6 is also in transmission connection with a rotating shaft on the third feeding hopper 20 through a chain, the rotating shaft drives the feeding tray 26 to rotate, and when the edge hole 28 of the feeding tray corresponds to the sample outlet of the third feeding hopper 20, the sample in the third feeding hopper 20 falls into the inclined second roundness screening mechanism 22 through the sample outlet from the edge hole 18 of the feeding hopper.

As shown in fig. 5, the first roundness screening mechanism 5 or the second roundness screening mechanism 22 is provided with a roundness specification fine adjustment bolt 32, a right screening rail 33, a left screening rail 34, and a rail fixing plate 35, the two rail fixing plates 35 are arranged in parallel, two sets of cylindrical double-shaft rolling rods are installed between the two rail fixing plates 35, each set of double-shaft rolling rods is in a structure that the right screening rail 33 and the left screening rail 34 are arranged oppositely, the output end of the third motor 7 is in transmission connection with the right screening rail 33 and the left screening rail 34 of the first roundness screening mechanism 5 respectively, the output end of the fourth motor 21 is in transmission connection with the right screening rail 33 and the left screening rail 34 of the second roundness screening mechanism 22 respectively, the distance between the right screening rail 33 and the left screening rail 34 and the end corresponding to the sample outlet of the second feeding hopper 4 or the third feeding hopper 20 is smaller than the distance between the right screening rail 33 and the end corresponding to the left screening rail 34 and the first material barrel 8 or the second material barrel 25, and the right screening track 33, the left screening track 34 and the track fixing plate 35 at the corresponding end of the first charging bucket 8 or the second charging bucket 25 are provided with a middle fixed part 37 and two side movable parts 38, the movable parts 38 and the fixed parts 37 are respectively connected through roundness specification fine adjustment bolts 32, the roundness specification fine adjustment bolts 32 adjust the distance between the movable parts 38 and the fixed parts 37, and further adjust the distance between one ends of the right screening track 33 and the left screening track 34, so that screening can be conveniently carried out according to the required sample granularity, the inclination angle of the high-precision double-shaft rolling rod is adjustable, the roundness of the screening ball can be adjusted through angle adjustment, the speed of the double-shaft rolling rod controlled by the third motor is adjustable, and the high precision of the roundness can be ensured.

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 can substitute or change the technical solution and the inventive concept of the present invention within the technical scope disclosed in the present invention.

Claims

1. The utility model provides a multi-functional spheroid material loading machine which characterized in that includes: frame, first feeding funnel, first slide track, second feeding funnel, first circularity screening mechanism, first storage bucket, first slide, first response module, first response signal receiver, frame support, frame stand, first pipeline, first base, second base, rotation axis, second pipeline, second slide track, third feeding funnel, second circularity screening mechanism, second response module, second slide, second storage bucket, second response signal receiver, concrete structure is as follows:

2. A multi-function ball feeder as claimed in claim 1, wherein the first motor is provided on the horizontal plate of the frame support.

3. The multifunctional sphere feeding machine according to claim 1, wherein the second base is provided with a second motor, a first induction signal receiver and a second induction signal receiver.

4. The multifunctional sphere feeding machine according to claim 1, wherein the first roundness screening mechanism or the second roundness screening mechanism is provided with a right screening rail, a left screening rail and a rail fixing plate, the two rail fixing plates are arranged in parallel, two sets of cylindrical double-shaft rolling rods are arranged between the two rail fixing plates, each set of double-shaft rolling rods is of a structure that the right screening rail and the left screening rail are arranged oppositely, and the distance between the right screening rail and the end, corresponding to the sample outlet, of the left screening rail and the second feeding hopper or the third feeding hopper is smaller than the distance between the right screening rail and the end, corresponding to the first material barrel or the second material barrel, of the left screening rail and the corresponding end of the first material barrel or the second material barrel.

5. The multifunctional sphere feeding machine according to claim 4, wherein the first roundness screening mechanism is provided with a third motor, and the output end of the third motor is in transmission connection with the right screening rail and the left screening rail of the first roundness screening mechanism respectively; and the output end of the fourth motor is in transmission connection with the right screening track and the left screening track of the second roundness screening mechanism respectively.

6. The multifunctional sphere feeding machine according to claim 4, wherein the rail fixing plate at one end of the right screening rail and the left screening rail corresponding to the first bucket or the second bucket is provided with a middle fixing part and two movable parts at two sides, the movable parts and the fixing parts are respectively connected through roundness specification fine adjustment bolts, and the roundness specification fine adjustment bolts adjust the distance between the movable parts and the fixing parts, so as to adjust the distance between one end of the right screening rail and one end of the left screening rail.