CN215278443U - Graphite vibration screening device capable of rapidly loading and unloading - Google Patents

Abstract

The utility model discloses a can swiftly go up graphite vibration screening plant of unloading, which comprises a housin, the both sides at casing top all are equipped with the silo, the inside intermediate position of casing is equipped with and separates the frame, the transfer groove has been seted up at the top that separates the frame, the both sides that separate the frame all are equipped with and casing matched with screening groove, the bottom in screening groove is equipped with the lower chute with casing matched with, the inside in screening groove is equipped with the screening frame, and the screening frame is located the below in transfer groove, the inclination of screening frame is the same with the inclination of transfer groove bottom, the one end that screening frame is close to the casing lateral wall is equipped with rather than matched with screening motor, the top of screening motor is equipped with the blanking groove with casing matched with, the top that separates the frame is equipped with and goes up silo matched with and goes up the work or material rest. The beneficial effects are that: equipment can utilize stable structure in whole use, realizes that equipment is swift, stable and can carry out the categorised material loading of adjusting to make equipment nimble more and practical.

Description

Graphite vibration screening device capable of rapidly loading and unloading

Technical Field

The utility model relates to a graphite screening field particularly, relates to a graphite vibrations screening plant of unloading in can swiftly.

Background

The sieving machine is a vibrating sieving mechanical device which utilizes the relative movement of bulk materials and a sieve surface to lead partial particles to penetrate through sieve pores and divide materials such as sand, gravel, broken stone and the like into different grades according to the particle size, in the technical field of graphite production and processing, a raw material required by graphite is generally crushed, the larger components of the raw material particles are generally required to be sieved out for additional grinding in the crushing process, when the traditional graphite material is sieved, the material is simply conveyed into the sieving device by utilizing a conveyor belt, which causes the material loading ratio to be disordered, and because the material directly falls into a sieving structure, the gravity of the material is easy to damage the structure, and the whole material loading process is simple but not fast enough, the graphite material can not be quickly, directly and stably sieved after being fed into the sieving structure, after the materials are quickly fed and screened, the screened materials can be reasonably and effectively distinguished, and meanwhile, the materials are quickly discharged.

An effective solution to the problems in the related art has not been proposed yet.

SUMMERY OF THE UTILITY MODEL

To the problem in the correlation technique, the utility model provides a graphite vibration screening plant of unloading can swiftly go up to overcome the above-mentioned technical problem that current correlation technique exists.

Therefore, the utility model discloses a specific technical scheme as follows:

a graphite vibration screening device capable of quickly loading and unloading materials comprises a shell, wherein feeding grooves are formed in two sides of the top of the shell, a separating frame is arranged in the middle of the inner portion of the shell, a transfer groove is formed in the top of the separating frame, screening grooves matched with the shell are formed in two sides of the separating frame, a discharging groove matched with the shell is formed in the bottom end of each screening groove, a screening frame is arranged in each screening groove and located below the transfer groove, the inclination angle of each screening frame is the same as that of the bottom of the transfer groove, a screening motor matched with the screening frame is arranged at one end, close to the side wall of the shell, of each screening frame, a discharging groove matched with the shell is formed above the screening motor, a loading frame matched with the feeding grooves is formed in the top end of the separating frame, and a function board is arranged in the loading frame, and auxiliary grooves matched with the feeding frame are formed in two sides of the function board.

Furthermore, a plurality of auxiliary rods which are uniformly distributed are arranged between the top of the function board and the inner wall of one side of the shell, the auxiliary rods incline for 30 degrees horizontally, and a connecting function strip is arranged between the auxiliary rods and the function board.

Furthermore, the cross section of each auxiliary groove is of a trapezoidal structure, and the space ratio of every two auxiliary grooves is 1: 2.

Furthermore, the internal thread of the transit groove is connected with a plurality of control rods which are uniformly distributed, and the outer wall of each control rod is sleeved with a control sleeve matched with the control rod.

Furthermore, a plurality of uniformly distributed blanking screening strips are arranged at the top end of the screening frame, and the blanking screening strips are of a triangular structure with 30-degree arc-shaped sides on one side.

Further, go up the work or material rest with be equipped with the mounting bracket between the casing top, the mounting bracket with be equipped with joint support pole between the shells inner wall.

The utility model has the advantages that: equipment can utilize stable structure in whole use, realize that equipment is swift, the categorised material loading of adjustment just can be carried out to stable, and let the material loading structure carry the material vibrations structure department completely when, the material loading can be very mild and stable, simultaneously, utilize the slope structure of progressive complex, let the sieve divide the material and be difficult to the material of screening through different openings respectively the unloading, let equipment can carry out secondary treatment to the material that can't satisfy the requirement, thereby make equipment nimble more and practical.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings required to be used in 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 invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

Fig. 1 is a schematic structural diagram of a graphite vibrating screening device capable of feeding and discharging materials rapidly according to an embodiment of the present invention;

fig. 2 is a top view of a graphite vibrating screening device capable of feeding and discharging materials rapidly according to an embodiment of the present invention;

fig. 3 is a top view of the feeding frame of the graphite vibrating and screening device capable of rapidly feeding and discharging materials according to the embodiment of the present invention.

In the figure:

1. a housing; 2. a feeding trough; 3. a spacer; 4. a transit trough; 5. a screening tank; 6. a discharging groove; 7. a screening rack; 8. a screening motor; 9. a charging chute; 10. a feeding frame; 11. a function board; 12. an auxiliary groove; 13. an auxiliary lever; 14. connecting a functional strip; 15. a control lever; 16. a control sleeve; 17. blanking and screening strips; 18. a mounting frame; 19. the supporting rod is connected.

Detailed Description

For further explanation of the embodiments, the drawings are provided as part of the disclosure and serve primarily to illustrate the embodiments and, together with the description, to explain the principles of operation of the embodiments, and to provide further explanation of the invention and advantages thereof, it will be understood by those skilled in the art that various other embodiments and advantages of the invention are possible, and that elements in the drawings are not to scale and that like reference numerals are generally used to designate like elements.

According to the utility model discloses an embodiment provides a graphite vibration screening plant of unloading in can swiftly.

The first embodiment is as follows:

as shown in fig. 1-3, the graphite vibration screening device capable of loading and unloading rapidly according to the embodiment of the present invention comprises a housing 1, wherein a loading chute 2 is disposed on both sides of the top of the housing 1, a separation frame 3 is disposed at the middle position inside the housing 1, a transfer chute 4 is disposed on the top of the separation frame 3, screening chutes 5 matched with the housing 1 are disposed on both sides of the separation frame 3, a discharge chute 6 matched with the housing 1 is disposed at the bottom end of the screening chute 5, a screening frame 7 is disposed inside the screening chute 5, the screening frame 7 is disposed below the transfer chute 4, the inclination angle of the screening frame 7 is the same as that of the bottom of the transfer chute 4, a screening motor 8 matched with the screening frame 7 is disposed at one end of the side wall of the housing 1, a discharge chute 9 matched with the housing 1 is disposed above the screening motor 8, the top end of the separation frame 3 is provided with a feeding frame 10 matched with the feeding groove 2, a function board 11 is arranged inside the feeding frame 10, and auxiliary grooves 12 matched with the feeding frame 10 are arranged on two sides of the function board 11.

The following is a detailed description of the specific arrangement and operation of the housing 1, the transfer chute 4, the screening frame 7, the function board 11, the partition frame 3, the auxiliary bar 13 and the loading chute 2.

As shown in figure 1, when the device is used, the loading frame 10 is arranged at the top end of the shell 1, then the conveyor belt is adjusted in position, the conveying direction is aligned with the auxiliary grooves 12 in the loading frame 10, the graphite material moves from the top end of the smaller auxiliary groove 12 to the larger auxiliary groove 12, the smaller graphite material directly falls into the smaller auxiliary groove 12, the larger graphite material moves into the larger auxiliary groove 12 through the plane formed by the auxiliary rods 13, and because of the trapezoidal structure of the auxiliary grooves 12, when the graphite material falls, a stable blanking speed is provided, during the blanking, different loading and blanking speeds and distinguishing conditions can be adjusted by adjusting the number and the spacing of the auxiliary rods 13, when the graphite material falls into the shell 1 through the auxiliary grooves 12, the loading frame 10 is different from the installation mode of the shell 1, and the smaller stone material and the larger stone material fall into different screening grooves 5 respectively after the loading, and because the shorter clearance between auxiliary tank 12 and the screening frame 7, let the graphite material more steady on dropping to screening frame 7, later screening motor 8 starts, high frequency vibration begins, and screen the graphite material, the graphite material that sieves out can directly fall down in silo 6, and the graphite material that can't sieve, can be because the inclination of screening frame 7, under the continuous vibrations of screening, slow roll, at the roll in-process, accomplish the screening, the graphite material that finally will be too big can't fall through silo 9 flows outside casing 1, and through subsequent processing, handle too big material, it is swift finally to accomplish, stable material loading unloading and accurate screening.

Example two:

as shown in fig. 1-3, a plurality of auxiliary rods 13 are uniformly distributed between the top of the function board 11 and the inner wall of one side of the housing 1, the auxiliary rod 13 is inclined 30 degrees relative to the horizontal, a connecting functional strip 14 is arranged between the auxiliary rod 13 and the functional board 11, the section of the auxiliary groove 12 is in a trapezoidal structure, the space ratio of every two auxiliary grooves 12 is 1:2, the interior of the transfer tank 4 is connected with a plurality of control rods 15 which are evenly distributed through screw threads, the outer wall of each control rod 15 is sleeved with a control sleeve 16 which is matched with the control rod, the top end of the screening frame 7 is provided with a plurality of blanking screening strips 17 which are evenly distributed, and the blanking screening strip 17 is a triangular structure with a 30-degree arc-shaped edge on one side, the feeding frame 10 is provided with an installation frame 18 between the top of the shell 1, and a connecting support rod 19 is arranged between the installation frame 18 and the inner wall of the shell 1.

For the convenience of understanding the technical solution of the present invention, the following detailed description is made on the working principle or the operation mode of the present invention in the practical process.

In practical application, the loading frame 10 is installed at the top end of the shell 1, then the conveyor belt is adjusted in position, the conveying direction is aligned to the auxiliary grooves 12 in the loading frame 10, the graphite material can move from the top end of the smaller auxiliary groove 12 to the larger auxiliary groove 12, the smaller graphite material can directly fall into the smaller auxiliary groove 12 during the moving process, the larger graphite material can move into the larger auxiliary groove 12 through the plane formed by the auxiliary rods 13, and because of the trapezoidal structure of the auxiliary grooves 12, when the graphite material can fall, a stable blanking speed is provided, during the period, different loading blanking speeds and different distinguishing conditions can be adjusted by adjusting the number and the spacing of the auxiliary rods 13, after the graphite material falls into the shell 1 through the auxiliary grooves 12, the loading frame 10 and the shell 1 are different in installation mode, and the smaller stone material and the larger stone material can respectively fall into different screening grooves 5 after the loading, and because the shorter clearance between auxiliary tank 12 and the screening frame 7, let the graphite material more steady on dropping to screening frame 7, later screening motor 8 starts, high frequency vibration begins, and screen the graphite material, the graphite material that sieves out can directly fall down in silo 6, and the graphite material that can't sieve, can be because the inclination of screening frame 7, under the continuous vibrations of screening, slow roll, at the roll in-process, accomplish the screening, the graphite material that finally will be too big can't fall through silo 9 flows outside casing 1, and through subsequent processing, handle too big material, it is swift finally to accomplish, stable material loading unloading and accurate screening.

To sum up, with the help of the above technical scheme of the utility model, equipment can utilize stable structure in whole use, realize that equipment is swift, stable and can carry out the categorised material loading of adjustment to let the material loading structure carry the material completely when vibrations structure department, the material loading can be very mild and stable, and simultaneously, utilize to advance complex slope structure one by one, let the sieve divide the material and be difficult to the material of screening through different openings respectively the unloading, let equipment can carry out secondary treatment to the material that can't satisfy the requirement, thereby make equipment nimble more and practical.

The above description is only a preferred embodiment of the present invention, and should not be taken as limiting the invention, and any modifications, equivalent replacements, improvements, etc. made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (6)

1. The graphite vibration screening device capable of quickly feeding and discharging is characterized by comprising a shell (1), wherein feeding grooves (2) are formed in two sides of the top of the shell (1), a separation frame (3) is arranged in the middle of the inside of the shell (1), a transfer groove (4) is formed in the top of the separation frame (3), screening grooves (5) matched with the shell (1) are formed in two sides of the separation frame (3), a discharging groove (6) matched with the shell (1) is formed in the bottom end of the screening groove (5), a screening frame (7) is arranged in the screening groove (5), the screening frame (7) is located below the transfer groove (4), the inclination angle of the screening frame (7) is the same as that of the bottom of the transfer groove (4), a screening motor (8) matched with the screening frame is arranged at one end, close to the side wall of the shell (1), of the screening frame (7), the screening machine is characterized in that a blanking groove (9) matched with the shell (1) is formed in the upper portion of the screening motor (8), a feeding frame (10) matched with the feeding groove (2) is arranged at the top end of the separation frame (3), a function board (11) is arranged inside the feeding frame (10), and auxiliary grooves (12) matched with the feeding frame (10) are formed in the two sides of the function board (11).

2. The graphite vibrating screen device capable of feeding and discharging rapidly as claimed in claim 1, wherein a plurality of auxiliary rods (13) are uniformly distributed between the top of the function board (11) and the inner wall of one side of the shell (1), the auxiliary rods (13) are inclined 30 degrees relative to the horizontal, and a connecting function strip (14) is arranged between the auxiliary rods (13) and the function board (11).

3. The graphite vibrating screen device capable of feeding and discharging materials rapidly as claimed in claim 1, wherein the cross section of the auxiliary grooves (12) is of a trapezoid structure, and the space ratio of every two auxiliary grooves (12) is 1: 2.

4. The graphite vibrating screen device capable of feeding and discharging materials rapidly as claimed in claim 1, wherein a plurality of control rods (15) are connected to the inner portion of the transit trough (4) in a threaded mode and are distributed evenly, and control sleeves (16) matched with the control rods are sleeved on the outer wall of each control rod (15).

5. The graphite vibrating screen device capable of feeding and discharging rapidly as claimed in claim 1, wherein a plurality of blanking screening strips (17) are uniformly distributed at the top end of the screening frame (7), and the blanking screening strips (17) are of a triangular structure with 30-degree arc-shaped sides on one side.

6. The graphite vibrating screen device capable of feeding and discharging materials rapidly as claimed in claim 1, wherein a mounting rack (18) is arranged between the feeding rack (10) and the top of the shell (1), and a connecting support rod (19) is arranged between the mounting rack (18) and the inner wall of the shell (1).

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