CN217797328U - Graphite material sieving mechanism - Google Patents

Abstract

The utility model discloses a graphite material sieving mechanism relates to graphite material processing technology field. The utility model comprises a material placing module which is used for placing the graphite material in a centralized way and providing the environment required by the screening; a group of material buffer receiving modules which are connected with the material placing modules and used for carrying out material supply and receiving; any one material buffering and bearing module comprises a rotating motor connected to one side of the upper part of the front surface of the material placing module, a buffer plate connected to the front output end of the rotating motor and arranged in the material placing module, and a bearing plate connected to the upper end of the buffer plate, wherein a weighing sensor is arranged in the bottom end of the bearing plate; still include, connect in putting the inside lower extreme of material module, carry out the vibration screening module of screening. The utility model discloses a set up the material buffering and accept the module, solved current graphite material sieving mechanism, by the opening of putting the workbin top, accept graphite material, and have certain difference in height between top opening and the below screening net, increased graphite material and damaged the problem of probability.

Description

Graphite material sieving mechanism

Technical Field

The utility model relates to a graphite material processing technology field especially relates to a graphite material sieving mechanism.

Background

Graphite material is generally referred to as graphite refractory material. Graphite is a main component of the refractory material. Some refractory products made of graphite and clay as main raw materials are also listed, the refractory products are respectively called clay graphite products according to the content of the clay and the content of the graphite, and the graphite materials need to be screened by a screening device in the processing process so as to meet the processing and production requirements.

However, the following disadvantages still exist in the practical use:

the existing graphite material screening device generally directly receives the conveyed graphite material through an opening above a material placing box, a certain height difference is formed between the opening above the graphite material and a screening net below the opening above the graphite material, the graphite material vertically falls, and the damage probability of the graphite material is increased.

Therefore, the requirement of practical use cannot be satisfied, so that there is a strong need for improved technology to solve the above problems.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a graphite material sieving mechanism accepts the module through setting up the material buffering, has solved current graphite material sieving mechanism, by putting the opening of workbin top, accepts graphite material, and has certain difference in height between top opening and the below screening net, has increased the problem of graphite material damage probability.

In order to solve the technical problem, the utility model discloses a realize through following technical scheme:

the utility model relates to a graphite material screening device, which comprises a material placing module, a material conveying module and a material conveying module, wherein the material placing module is used for centrally placing graphite materials and providing an environment required by screening;

a group of material buffer receiving modules which are connected with the material placing modules and used for carrying out material supply and receiving;

any one of the material buffering and bearing modules comprises a rotating motor connected to one side of the upper part of the front surface of the material placing module, a buffer plate connected to the front output end of the rotating motor and arranged in the material placing module, and a bearing plate connected to the upper end of the buffer plate, wherein a weighing sensor is arranged in the bottom end of the bearing plate;

still include, connect in put the inside lower extreme of material module, carry out the vibration screening module of screening.

Furthermore, the vibration screening module comprises a screening net, a group of movable plates symmetrically connected to the upper end part of the screening net, and a group of vibration motors symmetrically connected to the lower parts of the two sides of the screening net;

any one movable plate is arranged in a movable groove formed in the position corresponding to the material placing module;

specifically, under outer control end, exert the power of vibration by vibrating motor to the screen cloth to the graphite material that accepts by the screen cloth carries out the processing of moving, under continuous vibrational force, accessible screen cloth carries out its screening, and the activity of fly leaf in the activity inslot can avoid moving upward and rock the middle-sized graphite material and take place to fall outward.

Furthermore, the material placing module comprises a material placing box, a material discharging pipe and an electromagnetic valve, wherein the material discharging pipe is connected to the middle of the bottom end of the material placing box and penetrates through the material placing box, and the electromagnetic valve is connected to the lower part of one side of the material discharging pipe and penetrates through the material discharging pipe;

specifically, put the workbin and carry out the concentrated of graphite material and place to provide the required environment of screening, the discharging pipe then exports the graphite material after the screening, and the solenoid valve then exports the switching process of in-process.

Furthermore, the bottom end of the material placing box is connected with a supporting module;

the supporting module comprises a supporting pore plate, two groups of supporting blocks which are symmetrically connected to the front and the back of the bottom end part of the supporting pore plate and a supporting leg connected to the middle part of the bottom of any one of the supporting blocks;

specifically, the supporting hole plate is used for supporting the supporting block and the positioning module, the supporting block is used for supporting the supporting leg, and after the supporting block is placed in contact with the ground, the whole device is stably processed.

Furthermore, the edge of the upper end of the support pore plate is connected with a positioning module;

the positioning module comprises two groups of symmetrical fixing blocks, a positioning plate connected to the inner side of any group of fixing blocks through a threaded rod and a group of positioning studs symmetrically penetrating through the upper end part of the positioning plate in a front-back mode;

specifically, the fixed block carries out the support of a set of locating plate structure under the threaded rod, and the contact between the inner side of a set of locating plate and the material placing box is put into the locating stud, and after the tightening force is applied, the locating stud can carry out structure location on the material placing box.

Furthermore, the upper part of the outer side of any one of the positioning plates is provided with a rectangular groove, and a clamping block which is arranged on the outer side of any one of the vibration motors in a penetrating manner is clamped in the rectangular groove;

specifically, the clamping connection between the rectangular groove and the clamping block is used for installing and fixing the vibration motor structure, and the clamping connection is easy to disassemble and assemble.

The utility model discloses following beneficial effect has:

the utility model discloses by the setting of material buffering supporting module, specifically, set up a set of receiving plate to the upper portion of workbin inboard, and through rotating motor drive, and receive the built-in weighing sensor in the board bottom, can weigh the graphite material of accepting to realize quantitative feed screening, in order to avoid too much graphite material, cause the jam of screening net itself, help the improvement of operating efficiency;

meanwhile, a vibration screening module is additionally arranged, a screening net for screening graphite materials is arranged at the lower part of the material placing box and is in a penetrating structure, a movable plate is connected to the upper end part of the screening net to prevent the graphite materials from falling to the outside environment in the process of up-and-down movement and screening, the vibration motor is in threaded connection with the screening net, and the screening net can be taken out, maintained or replaced at a low position after the bolts are disassembled, so that the graphite material screening machine is easy to use.

Of course, it is not necessary for any particular product to achieve all of the above-described advantages at the same time.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings used in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to these drawings without creative efforts.

FIG. 1 is a front view of the present invention;

fig. 2 is a bottom view of the present invention;

FIG. 3 is a structural diagram of the vibration screening module of the present invention;

fig. 4 is a structural diagram of the positioning module of the present invention.

In the drawings, the components represented by the respective reference numerals are listed below:

100. a material placing module; 110. a material placing box; 120. a discharge pipe; 130. an electromagnetic valve; 200. a support module; 210. supporting the orifice plate; 220. supporting a block; 230. supporting legs; 300. a material buffer receiving module; 310. rotating the motor; 320. a buffer plate; 330. a bearing plate; 400. a vibration screening module; 410. A clamping block; 420. a vibration motor; 430. screening a net; 440. a movable plate; 500. a positioning module; 510. A fixed block; 520. positioning a plate; 530. and positioning the stud.

Detailed Description

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention.

Example 1

Referring to fig. 1, the present embodiment is a graphite material screening apparatus, including a material placing module 100, configured to place graphite materials in a centralized manner and provide an environment for screening the graphite materials;

a set of material buffer receiving module 300 connected to the material placing module 100 for receiving the material;

any material buffering and receiving module 300 comprises a rotating motor 310 connected to one side of the upper part of the front surface of the material placing module 100, a buffer plate 320 connected to the front output end of the rotating motor 310 and arranged in the material placing module 100, and a receiving plate 330 connected to the upper end of the buffer plate 320, wherein a weighing sensor is arranged in the bottom end of the receiving plate 330;

the material buffering receiving module 300 is used;

when the graphite material to be screened is supplied to the material box 110 by the external conveying structure, under the external control end, the group of rotating motors 310 sequentially apply rotating force to the buffer plates 320 so as to perform contact horizontal arrangement on the inner sides of the group of buffer plates 320;

at this time, the upper end surface of the bearing plate 330 bears the graphite material, and the weighing sensor is arranged in the bottom end of the bearing plate 330, so that the graphite material can be weighed in real time, and the operation of the external conveying structure is stopped after the weighing data detected by the external control end is within the rated range;

next, the set of rotating motors 310 performs the above reverse steps, so that the set of buffer plates 320 are disposed at an inward inclined angle, and the received graphite material is slowly conveyed to the screen 430 at a lower position under its own weight.

Example 2

As shown in fig. 3, the device further includes a vibration screening module 400 connected to the lower end of the material placing module 100 for screening;

the vibratory screening module 400 includes a screening net 430, a set of movable plates 440 symmetrically connected to the upper end of the screening net 430, and a set of vibration motors 420 symmetrically connected to the lower portions of both sides of the screening net 430;

any one of the movable plates 440 is disposed in a movable groove formed at a position corresponding to the material placing module 100;

the upper part of the outer side of any positioning plate 520 is provided with a rectangular groove, and a fixture block 410 which is arranged through the outer side of any vibration motor 420 is clamped in the rectangular groove;

using the vibration screening module 400;

after the above steps are performed, the graphite material to be screened is received by the screening net 430;

at this time, under the external control end, a set of vibration motors 420 applies a force of vibration to the screen mesh 430, and the generated vibration force is transmitted to the graphite material to be screened through the screen mesh 430;

during the screening of the graphite material, the movable plate 440 moves up and down in the movable groove, so that the graphite material can be prevented from falling from the through hole at the lower part of the material placing box 110;

meanwhile, the bolts connecting the vibration motor 420 and the screening net 430 can be disassembled, and the structure of the screening net 430 is moved out from the lower part in the material placing box 110 through the through hole, so that the screening net 430 can be overhauled or replaced.

Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described above, or equivalents may be substituted for elements thereof. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (6)

1. A graphite material screening device is characterized in that;

the device comprises a material placing module (100) which is used for placing graphite materials in a centralized manner and providing an environment required by screening;

a material buffer receiving module (300) connected to the material placing module (100) for receiving the material;

any one material buffering and receiving module (300) comprises a rotating motor (310) connected to one side of the upper portion of the front surface of the material placing module (100), a buffer plate (320) connected to the front output end of the rotating motor (310) and placed in the material placing module (100), and a receiving plate (330) connected to the upper end of the buffer plate (320), wherein a weighing sensor is arranged in the bottom end of the receiving plate (330);

still include, connect in put the inside lower extreme of material module (100), carry out the vibration screening module (400) of screening.

2. The graphite material screening apparatus as claimed in claim 1, wherein the vibrating screen module (400) comprises a screen mesh (430), a set of movable plates (440) symmetrically connected to the upper end of the screen mesh (430), a set of vibrating motors (420) symmetrically connected to the lower sides of the screen mesh (430);

any one movable plate (440) is arranged in a movable groove formed in the position corresponding to the material placing module (100).

3. The graphite material screening device according to claim 2, wherein the material placing module (100) comprises a material placing box (110), a material discharging pipe (120) connected to the middle of the bottom end of the material placing box (110) and penetrating through the material placing box, and an electromagnetic valve (130) connected to the lower part of one side of the material discharging pipe (120) and penetrating through the material discharging pipe.

4. The graphite material screening device according to claim 3, wherein a supporting module (200) is connected to the bottom end of the material placing box (110);

the supporting module (200) comprises a supporting pore plate (210), two groups of supporting blocks (220) which are symmetrically connected to the front and the rear of the bottom end part of the supporting pore plate (210), and supporting legs (230) which are connected to the middle part of the bottom of any one of the supporting blocks (220).

5. The graphite material screening device according to claim 4, wherein a positioning module (500) is connected to the upper end edge of the supporting orifice plate (210);

the positioning module (500) comprises two groups of symmetrical fixing blocks (510), a positioning plate (520) connected to the inner side of any one group of the fixing blocks (510) through a threaded rod, and a group of positioning studs (530) symmetrically penetrating through the upper end of the positioning plate (520) from front to back.

6. The graphite material screening device according to claim 5, wherein a rectangular groove is formed in the upper portion of the outer side of any one of the positioning plates (520), and a fixture block (410) penetrating through the outer side of any one of the vibration motors (420) is clamped in the rectangular groove.

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