CN218088974U - Feed mechanism of activation converter - Google Patents

Abstract

The utility model provides a feed mechanism of activation converter, including support frame, conveyer belt mounting bracket, conveyer belt, set up the conveyer belt mounting bracket on the support frame, fixed connection conveyer belt between the conveyer belt mounting bracket, be provided with the refining subassembly on the support frame of conveyer belt discharge end one side, the raw materials that the conveyer belt was carried is evenly carried to the furnace body in through the refining subassembly. The utility model discloses in the conveyer belt starts the back and carries the conveyer trough in the refining subassembly to the raw materials, roll at the raw materials and fall when the refining plate, extending structure starts can promote the pulling that the connecting block made the refining plate by coming and going and promotes, when the refining plate is promoted, the raw materials can fall than far away, the refining plate is promoted the back, the position that the raw materials fell is relatively nearer, consequently, the refining plate is promoted the back by the pulling that comes and goes, can make the raw materials of process fall in the furnace body by the dispersion, thereby the realization can not accumulational effect to the raw materials is even.

Description

Feed mechanism of activation converter

Technical Field

The utility model relates to an active carbon technical field, concretely relates to loading mechanism of activation converter.

Background

The activation converter mainly conveys the raw materials to a blanking pipe through a conveying belt in the feeding process and then falls into a furnace body.

For example, in the invention patent of the patent number "201810114822.0" with the patent name of "a coal-made activated carbon furnace", a feeding port is positioned above a furnace body, and raw materials are fed into the furnace body through a raw material inlet, so that the mode has the advantage of low cost and is popularized and used by the industry; however, problems to be solved in use, such as uneven scattering of raw materials caused by the fact that the raw materials directly fall into the furnace body through the raw material inlet, are also existed, so that a feeding mechanism for activating the converter is provided.

SUMMERY OF THE UTILITY MODEL

The utility model discloses a main aim at provides a feed mechanism of activation converter can effectively solve the inhomogeneous problem that scatters of raw materials that exists among the background art.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

the utility model provides a feed mechanism of activation converter, includes support frame, conveyer belt mounting bracket, conveyer belt, set up the conveyer belt mounting bracket on the support frame, fixed connection conveyer belt between the conveyer belt mounting bracket, be provided with the refining subassembly on the support frame of conveyer belt discharge end one side, the raw materials that the conveyer belt was carried is evenly carried to the furnace body through the refining subassembly in, because the temperature of activation converter is higher, the conveyer belt can seriously shorten the life of conveyer belt apart from the feed inlet too closely, consequently through carrying the raw materials on the conveyer belt in the refining subassembly, evenly spill the activation converter into by the refining subassembly again.

Preferably, the refining assembly comprises a conveying groove, a refining plate and a refining driving part; the conveying trough is a U-shaped trough body and is obliquely arranged on the supporting frame, the port on the higher side of the conveying trough is positioned on the lower side of the discharge end of the conveying belt, the bottom of the other end of the conveying trough is rotatably connected with the material homogenizing plate through a rotating shaft, the other end of the material homogenizing plate is positioned in the material inlet of the furnace body, the material homogenizing driving part is arranged at the bottom of the conveying trough and is movably connected with the bottom of the material homogenizing plate to drive the free end of the material homogenizing plate to swing in a reciprocating manner in the material inlet of the furnace body,

the conveying groove is used for receiving raw materials from the discharging end of the conveying belt, the refining plate drives the raw materials to uniformly scatter in the furnace body through reciprocating swing, and the refining driving portion is used for driving the refining plate to reciprocate.

Preferably, the refining drive part sets up the second installation piece at the conveyer trough lower surface including setting up the first installation piece at refining plate lower surface, first installation piece has the connecting block through the second connecting pin hinge joint, and the second installation piece rotates through first connecting pin to be connected with extending structure, extending structure's flexible end is connected with the connecting block, extending structure's stiff end and first connecting pin fixed connection.

Preferably, the telescopic structure is an electric telescopic rod, and the material homogenizing plate is pushed and pulled to swing back and forth through the telescopic action of the electric telescopic rod.

Preferably, baffles are arranged on two sides of the upper surface of the homogenizing plate along the length direction and used for preventing raw materials from sliding off from two sides of the homogenizing plate.

Compared with the prior art, the utility model discloses following beneficial effect has:

carry the conveyer belt after the start-up to the raw materials in the conveyer trough in the refining subassembly, roll when the raw materials falls through the refining plate, extending structure starts and can promote the connecting block and drive the reciprocating swing of refining plate, when the refining plate is promoted, the raw materials can fall than far away, the refining plate is by the pulling back, the position that the raw materials fell is relatively nearer, consequently, the refining plate is promoted the back by the pulling that comes and goes, can make the raw materials that fall in the furnace body by the homodisperse, thereby solved the raw materials and piled up uneven problem.

Drawings

Fig. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic structural view of the refining assembly of the present invention;

fig. 3 is a schematic view of the bottom structure of the refining assembly of the present invention;

FIG. 4 is an enlarged schematic view of the structure a of the present invention;

in the figure: 1. support frame, 2, conveyer belt mounting bracket, 3, conveyer belt, 4, refining subassembly, 401, conveyer trough, 402, refining plate, 403, first connecting pin, 404, extending structure, 405, first installation piece, 406, connecting block, 407, second connecting pin, 408, pivot, 409, baffle, 410, second installation piece.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely below with reference to the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, rather than all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Examples

As shown in fig. 1 to 4, a feeding mechanism of an activation converter comprises a support frame 1, a conveyor belt mounting frame 2 and a conveyor belt 3, the conveyor belt mounting frame 2 is fixedly connected to the support frame 1, the conveyor belt 3 is fixedly connected between the conveyor belt mounting frames 2, a refining assembly 4 is arranged on one side of the support frame 1 close to the discharge end of the conveyor belt, raw materials conveyed by the conveyor belt 3 are uniformly conveyed into a furnace body through the refining assembly 4, and the refining assembly 4 comprises a conveying groove 401, a refining plate 402 and a refining driving part; conveyer trough 401 is the U-shaped groove, and its one end is located 3 discharge end downsides of conveyer belt, and the other end of conveyer trough 401 rotates through pivot 408 and connects homogenizing plate 402, and conveyer trough 401 is the slope setting, and the other end of homogenizing plate 402 is located the pan feeding mouth of furnace body, conveyer trough 401 and support frame 1 fixed connection, and the setting of refining drive division is in conveyer trough 401 bottom to with homogenizing plate 402 bottom swing joint, drive the free end of homogenizing plate 402 at the intraoral reciprocating swing of furnace body pan feeding.

The refining drive part comprises a first mounting block 405 fixedly connected with the lower surface of a refining plate 402, the first mounting block 405 is hinged with a connecting block 406 through a second connecting pin 407, a second mounting block 410 fixedly connected with the lower surface of a conveying groove 401, the second mounting block 410 is rotatably connected with a telescopic structure 404 through a first connecting pin 403, the telescopic end of the telescopic structure 404 is fixedly connected with the connecting block 406, the fixed end of the telescopic structure 404 is fixedly connected with the first connecting pin 403, and two ends of the first connecting pin 403 penetrate through the second mounting block 410. The first mounting block 405 is internally connected with the connecting block 406 in a rotating manner through a second connecting pin 407, the connecting block 406 is fixedly connected with the second connecting pin 407, two ends of the second connecting pin 407 penetrate through the first mounting block 405, the refining plate 402 is obliquely arranged, and the upper surface of the refining plate 402 is fixedly connected with the baffle 409.

The telescoping structure 404 is preferably an electrically powered telescoping rod, or a pneumatically or hydraulically powered telescoping rod may be used.

The working principle is as follows: after the conveyer belt 3 is started, raw materials are conveyed to a conveying groove 401 in the refining assembly 4, when the raw materials roll down to pass through the refining plate 402, the telescopic structure 404 is started to push the connecting block 406 to enable the refining plate 402 to be pulled and pushed back and forth, when the refining plate 402 is pushed, the raw materials can fall far, after the refining plate 402 is pulled, the position where the raw materials fall down is relatively close, therefore, after the refining plate 402 is pulled and pushed back and forth, the passing raw materials can be scattered and fall in a furnace body, and therefore the effect that the raw materials are scattered uniformly and can not be accumulated is achieved, when the telescopic structure 404 is telescopic, a first connecting pin at the fixed end of the telescopic structure 404 rotates in a second mounting block 410, meanwhile, a telescopic end of the telescopic structure 404 can drive the connecting block 406 and a second connecting pin 407 to rotate in a first mounting block 405, two sides of the refining plate 402 are fixedly connected with a rotating shaft 408, when the refining plate 402 rotates, the rotating shaft 408 can be driven to rotate in one end of the conveying groove 401, and the refining plate 401 and the refining plate 402 are made of metal high-temperature resistant materials.

Obviously, the above embodiments of the present invention are only examples for clearly illustrating the present invention, and are not intended to limit the embodiments of the present invention, and it is obvious for those skilled in the art to make other variations or changes based on the above descriptions, and all embodiments cannot be exhausted here, and all obvious variations or changes introduced by the technical solution of the present invention are still within the protection scope of the present invention.

Claims (4)

1. The utility model provides a feed mechanism of activation converter, includes support frame, conveyer belt mounting bracket, conveyer belt, set up the conveyer belt mounting bracket on the support frame, fixed connection conveyer belt, its characterized in that between the conveyer belt mounting bracket: a material homogenizing assembly is arranged on the support frame at one side of the discharge end of the conveyer belt, and the raw materials conveyed by the conveyer belt are uniformly conveyed into the furnace body through the material homogenizing assembly;

the material homogenizing assembly comprises a conveying groove, a material homogenizing plate and a material homogenizing driving part; the conveyer trough is the U-shaped cell body, and the slope sets up on the support frame, and the port of its higher one side is located conveyer belt discharge end downside, the other end bottom and the refining plate of conveyer trough rotate through the pivot to be connected, the other end of refining plate is located the pan feeding mouth of furnace body, the refining drive division sets up in the conveyer trough bottom to with refining plate bottom swing joint, the free end that drives the refining plate is at the interior reciprocating swing of furnace body pan feeding mouth.

2. The charging mechanism of the activation converter according to claim 1, wherein: the refining driving part comprises a first mounting block arranged on the lower surface of the refining plate and a second mounting block arranged on the lower surface of the conveying groove, the first mounting block is hinged to a connecting block through a second connecting pin, the second mounting block is rotatably connected with a telescopic structure through a first connecting pin, the telescopic end of the telescopic structure is connected with the connecting block, and the fixed end of the telescopic structure is fixedly connected with the first connecting pin.

3. The charging mechanism of an activation converter according to claim 2, wherein: the telescopic structure is an electric telescopic rod.

4. A charging mechanism of an activation converter according to any one of claims 1 to 3, characterized in that: baffles are arranged on two sides of the upper surface of the material homogenizing plate along the length direction.

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