CN218641844U - Material distributing mechanism for head of belt conveyor - Google Patents

Abstract

A material distribution mechanism used for a belt conveyor head is characterized in that an intersection area is formed at the upper ends of a first chute channel and a second chute channel of a chute body, a flange connector is formed above the intersection area, a baffle is arranged at the bottom of the intersection area, a partition plate is connected to the middle position of the intersection area, a first turning plate movable opening is formed in one side of the partition plate, and a second turning plate movable opening is formed in the other side of the partition plate; the movable opening of the first turning plate is connected with a first material distribution turning plate, and the lower end of the first material distribution turning plate is provided with a first turning plate shaft; the movable opening of the second turning plate is connected with a second material distribution turning plate, and the lower end of the second material distribution turning plate is provided with a second turning plate shaft; the first material distribution turning plate rotates through a first turning plate shaft to block the first chute channel or the second chute channel; the second distribution turning plate rotates through the second turning plate shaft to block the first chute channel or the second chute channel. The utility model discloses occupation space is little, can divide the material for one or two equipment in the front and back of the head chute that loads into the belt feeder.

Description

Material distributing mechanism for head of belt conveyor

Technical Field

The utility model relates to a feed mechanism that belt feeder head used belongs to the material and carries technical field.

Background

The belt feeder is common material conveying equipment, not only can be at the inside transported substance material of enterprise, can also transport in the enterprise outside, and the universal use is in trades such as chemical industry, food, harbour, power plant, mining and metallurgy. In the belt feeder transportation process, because the multiple spot is unloaded, need use the branch material equipment, if: the belt conveyor comprises a discharge trolley, a plow discharger, a turnover chute and the like, wherein the discharge trolley and the plow discharger are mainly used for material distribution in the middle of the belt conveyor, and the turnover chute is usually used at the head of the belt conveyor.

In the prior art, a turning plate chute is usually made into a three-way form and is arranged at the head of a belt conveyor, if one piece of equipment is required to be distributed, the single turning plate is mainly used for distributing materials, if two pieces of equipment are required to be distributed, the running direction of the turning plate is mostly perpendicular to the running direction of the belt conveyor, and the turning plate needs to be static in the middle part when distributing materials, so that the material flow can be cut. After material distribution, material using equipment needs to be arranged on two sides of the chute and a certain chute turning height needs to be reserved, so that the equipment transferring height is increased, and the workshop layout effect after equipment installation is influenced. In order to solve the above problems, it is necessary to develop a material distribution technical scheme capable of feeding two feeding points simultaneously.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a feed mechanism that belt feeder head used can be under the limited condition in space, divides the material for one or two equipment along belt feeder traffic direction.

The utility model provides an above-mentioned technical problem's technical scheme as follows: a material distribution mechanism used for a belt conveyor head comprises a chute body, wherein a first chute channel is formed on one side of the chute body, and a second chute channel is formed on the other side of the chute body;

an intersection area is formed at the upper ends of the first chute channel and the second chute channel, a flange connector is formed above the intersection area, a baffle is arranged at the bottom of the intersection area, a partition plate is connected to the middle of the intersection area, a first turning plate moving opening is formed in one side of the partition plate, and a second turning plate moving opening is formed in the other side of the partition plate;

the lower end of the first material-dividing turning plate is provided with a first turning plate shaft; the movable opening of the second turning plate is connected with a second material distribution turning plate, and the lower end of the second material distribution turning plate is provided with a second turning plate shaft;

the first distribution turning plate rotates through the first turning plate shaft to block the first chute channel or the second chute channel;

the second distribution flap rotates via the second flap shaft to block the first chute channel or the second chute channel.

The preferable scheme of the material distribution mechanism used as the head of the belt conveyor also comprises a first driving component; one end of the first flap shaft is connected with the partition plate, and the other end of the first flap shaft extends out of the outer side of the chute body and is connected with the first driving assembly.

The preferable scheme of the material distribution mechanism used as the head of the belt conveyor also comprises a second driving component; one end of the second flap shaft is connected with the partition plate, and the other end of the second flap shaft extends out of the outer side of the chute body and is connected with the second driving assembly.

The preferable scheme of the material distributing mechanism used as the head of the belt conveyor is that the position of the first flap shaft is higher than that of the second flap shaft.

The chute body is connected with a loading belt conveyor through the flange interface; the first chute channel is butted with a first crusher; the second chute channel is in butt joint with a transshipment belt conveyor, and the transshipment belt conveyor is in butt joint with a second crusher.

The first chute channel is formed on one side of the chute body, and the second chute channel is formed on the other side of the chute body; an intersection area is formed at the upper ends of the first chute channel and the second chute channel, a flange connector is formed above the intersection area, a baffle is arranged at the bottom of the intersection area, a partition plate is connected to the middle position of the intersection area, a first turning plate moving opening is formed in one side of the partition plate, and a second turning plate moving opening is formed in the other side of the partition plate; the movable opening of the first turning plate is connected with a first material distribution turning plate, and the lower end of the first material distribution turning plate is provided with a first turning plate shaft; the movable opening of the second turning plate is connected with a second material distribution turning plate, and the lower end of the second material distribution turning plate is provided with a second turning plate shaft; the first material distribution turning plate rotates through a first turning plate shaft to block the first chute channel or the second chute channel; the second distribution turning plate rotates through the second turning plate shaft to block the first chute channel or the second chute channel. The utility model discloses can make relevant equipment (first breaker, reprint belt feeder, second breaker) and load belt feeder design on a straight line, arrange pleasing to the eye, occupation space is little, can follow the belt feeder traffic direction that loads, at the head chute front and back side of loading the belt feeder, divides the material for one or two equipment.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below. It should be apparent that the drawings in the following description are merely exemplary, and that other embodiments can be derived from the drawings provided by those of ordinary skill in the art without inventive effort.

The structures, ratios, sizes, and the like shown in the present specification are only used for matching with the contents disclosed in the specification, so that those skilled in the art can understand and read the present invention, and do not limit the conditions for implementing the present invention, so that the present invention has no technical significance, and any structural modifications, changes in the ratio relationship, or adjustments of the sizes, without affecting the functions and purposes of the present invention, should still fall within the scope of the present invention.

Fig. 1 is a schematic view of a material distribution mechanism used in a head of a belt conveyor provided in an embodiment of the present invention;

fig. 2 is a schematic top view and a schematic cross-sectional view of a material distribution mechanism used in a belt conveyor head according to an embodiment of the present invention;

fig. 3 is a schematic view of a material distribution mechanism used in the head of the belt conveyor according to the embodiment of the present invention.

In the figure, 1, a chute body; 2. a first chute channel; 3. a second chute channel; 4. a junction region; 5. a flange interface; 6. a baffle plate; 7. a partition plate; 8. a first flap movable opening; 9. a second flap movable port; 10. a first material dividing turning plate; 11. a first flap shaft; 12. a second material dividing turning plate; 13. a second flap shaft; 14. a first drive assembly; 15. a second drive assembly; 16. loading the belt conveyor; 17. a first crusher; 18. transferring the belt conveyor; 19. a second crusher.

Detailed Description

In order to make the above objects, features and advantages of the present invention more comprehensible, embodiments of the present invention are described in detail below with reference to the accompanying drawings. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein, as those skilled in the art will be able to make similar modifications without departing from the spirit and scope of the present invention.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used herein in the description of the invention is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention.

Referring to fig. 1, 2 and 3, an embodiment of the present invention provides a material distribution mechanism for a head of a belt conveyor, including a chute body 1, a first chute channel 2 formed on one side of the chute body 1, and a second chute channel 3 formed on the other side of the chute body 1;

the device comprises a first chute channel 2, a second chute channel 3, a baffle plate 7, a first turnover plate moving opening 8, a second turnover plate moving opening 9, a flange joint 5, a first baffle plate 6, a baffle plate 7, a first turnover plate moving opening 8 and a second turnover plate moving opening 9, wherein the first chute channel 2 and the second chute channel 3 are arranged at the upper ends of the first chute channel and the second chute channel;

the first material distribution turning plate 10 is connected with the first turning plate movable opening 8, and a first turning plate shaft 11 is arranged at the lower end of the first material distribution turning plate 10; the second turning plate movable port 9 is connected with a second material dividing turning plate 12, and the lower end of the second material dividing turning plate 12 is provided with a second turning plate shaft 13;

the first distribution turning plate 10 rotates through a first turning plate shaft 11 to block the first chute channel 2 or the second chute channel 3;

the second distribution flap 12 is rotated by a second flap shaft 13 in order to block the first chute channel 2 or the second chute channel 3.

In this embodiment, a first drive assembly 14 is also included; one end of the first flap shaft 11 is connected with the partition plate 7, and the other end of the first flap shaft 11 extends out of the chute body 1 and is connected with a first driving assembly 14.

Specifically, the first driving assembly 14 may adopt a motor, the first driving assembly 14 may drive the first flap shaft 11 to rotate, the first flap shaft 11 drives the first material distribution flap 10 to swing, and when the first material distribution flap 10 swings to the inlet of the first chute channel 2, the first chute channel 2 is blocked, so that the material enters the second chute channel 3; when the first distribution flap 10 is swung to the inlet of the second chute channel 3, the second chute channel 3 is blocked, so that the material enters the first chute channel 2.

In this embodiment, a second drive assembly 15 is also included; one end of the second flap shaft 13 is connected with the partition plate 7, and the other end of the second flap shaft 13 extends out of the outer side of the chute body 1 and is connected with a second driving assembly 15.

Specifically, the second driving assembly 15 may adopt a motor, the second driving assembly 15 may drive the second flap shaft 13 to rotate, the second flap shaft 13 drives the second distribution flap 12 to swing, and when the second distribution flap 12 swings to the inlet of the first chute channel 2, the first chute channel 2 is blocked, so that the material enters the second chute channel 3; when the second distribution flap 12 is pivoted to the inlet of the second chute channel 3, the second chute channel 3 is blocked, so that the material enters the first chute channel 2.

The first material dividing turning plate 10 and the second material dividing turning plate 12 are made of manganese steel and have the characteristics of wear resistance and impact resistance, the first material dividing turning plate 10 and the first turning plate shaft 11 are welded into a whole, and the second material dividing turning plate 12 and the second turning plate shaft 13 are welded into a whole.

In the present embodiment, the position of the first flap shaft 11 is higher than the position of the second flap shaft 13. The first flap shaft 11 and the second flap shaft 13 adopt a split type high-low shaft design, the overlapping part of the first flap shaft 11 at the partition plate 7 does not influence the overturning of the second flap shaft 13, the shaft head is not exposed during the use, and the shaft heads are overlapped in the partition plate 7. In addition, a baffle 6 is arranged for preventing feed back.

In the embodiment, the chute body 1 is connected with a loading belt conveyor 16 through a flange interface 5; the first chute channel 2 is butted with a first crusher 17; the second chute channel 3 is butted with a transshipment belt conveyor 18, and the transshipment belt conveyor 18 is butted with a second crusher 19.

Specifically, the whole chute body 1 is made of carbon steel, and a manganese steel lining plate is arranged on the inclined plane of the downward sliding of the material. The flange interface 5 is connected with a funnel at the head of an upper loading belt conveyor 16 through bolts, the partition plate 7 plays a role in material distribution, and separated material flow plays a role in adjustment through the first material distribution turning plate 10 and the second material distribution turning plate 12. The flange connector 5 is made of angle steel, the partition plate 7 is made of a common carbon steel plate, and two sides and the lower end of the partition plate 7 are welded on the chute body 1.

Supplementary figure 3, through the utility model discloses, the material that comes is carried in belt feeder 16 passes through the flange of head funnel, and the butt joint is on 4 upper portions of intersection district that first chute passageway 2 and 3 upper ends of second chute passageways formed, and baffle 7 stands in the middle of the material stream, plays the branch material effect, and half gets into first board activity mouth 8 that turns over of material stream, and half gets into the second and turns over board activity mouth 9, turns over the switching of board 12 through first branch material and can realize three function through first branch material turns over board 10, second branch material:

function one: the first material dividing turning plate 10 and the second material dividing turning plate 12 are arranged on the side of the transfer belt conveyor 18, and all materials are conveyed to a first crusher 17 through a crusher chute;

and a second function: the first material dividing turning plate 10 and the second material dividing turning plate 12 are arranged on the side of a first crusher 17, and all materials are connected with a transfer belt conveyor 18 through a chute of the transfer belt conveyor 18 and enter a second crusher 19;

and a third function: the first material dividing turning plate 10 and the second material dividing turning plate 12 are arranged on different sides, half of raw materials are used by the first crusher 17, and the other half of raw materials are used by the first crusher 17 through the transfer belt conveyor 18.

To sum up, one side of the chute body 1 of the utility model is provided with a first chute channel 2, and the other side of the chute body 1 is provided with a second chute channel 3; an intersection area 4 is formed at the upper ends of the first chute channel 2 and the second chute channel 3, a flange connector 5 is formed above the intersection area 4, a baffle 6 is arranged at the bottom of the intersection area 4, a partition plate 7 is connected to the middle position of the intersection area 4, a first turning plate movable opening 8 is arranged on one side of the partition plate 7, and a second turning plate movable opening 9 is arranged on the other side of the partition plate 7; the first turning plate movable port 8 is connected with a first material dividing turning plate 10, and the lower end of the first material dividing turning plate 10 is provided with a first turning plate shaft 11; the second turning plate movable port 9 is connected with a second material dividing turning plate 12, and the lower end of the second material dividing turning plate 12 is provided with a second turning plate shaft 13; the first distribution flap 10 is rotated by a first flap shaft 11 to block the first chute channel 2 or the second chute channel 3; the second distribution flap 12 is rotated by means of a second flap shaft 13 in order to block the first chute channel 2 or the second chute channel 3. The first driving component 14 can adopt a motor, the first turning plate shaft 11 can be driven to rotate by the first driving component 14, the first turning plate shaft 11 drives the first material-dividing turning plate 10 to swing, and when the first material-dividing turning plate 10 swings to the inlet of the first chute channel 2, the first chute channel 2 is blocked, so that the material enters the second chute channel 3; when the first distribution flap 10 swings to the inlet of the second chute channel 3, the second chute channel 3 is blocked, so that the material enters the first chute channel 2. The second driving component 15 can adopt a motor, the second driving component 15 can drive the second turning plate shaft 13 to rotate, the second turning plate shaft 13 drives the second distribution turning plate 12 to swing, and when the second distribution turning plate 12 swings to the inlet of the first chute channel 2, the first chute channel 2 is blocked, so that the material enters the second chute channel 3; when the second distribution flap 12 is swung to the inlet of the second chute channel 3, the second chute channel 3 is blocked, so that material enters the first chute channel 2. The material that the loading belt feeder 16 carried passes through the flange of head funnel, and the butt joint is in the intersection zone 4 upper portion that first chute passageway 2 and second chute passageway 3 upper end formed, and baffle 7 stands in the middle of the material stream, plays the branch material effect, and half the material stream gets into first board activity mouth 8 that turns over, and half gets into second board activity mouth 9 that turns over, turns over board 10, the switching that the board 12 was turned over to the second branch material through first branch material and can realize three functions: function one: the first material dividing turning plate 10 and the second material dividing turning plate 12 are arranged on the side of the transfer belt conveyor 18, and all materials are conveyed to a first crusher 17 through a crusher chute; and a second function: the first material dividing turning plate 10 and the second material dividing turning plate 12 are arranged on the side of a first crusher 17, and all materials are connected with a transfer belt conveyor 18 through a chute of the transfer belt conveyor 18 and enter a second crusher 19; and function III: the first material dividing turning plate 10 and the second material dividing turning plate 12 are arranged on different sides, half of raw materials are used by the first crusher 17, and the other half of raw materials are used by the first crusher 17 through the transfer belt conveyor 18. The utility model discloses can make relevant equipment (first breaker 17, reprint belt feeder 18, second breaker 19) and load belt feeder 16 design on a straight line, arrange pleasing to the eye, occupation space is little, can follow the load belt feeder 16 traffic direction, in the front and back of the head chute that loads belt feeder 16, divides the material for one or two equipment.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only represent several embodiments of the present invention, and the description thereof is specific and detailed, but not to be construed as limiting the scope of the invention. It should be noted that, for those skilled in the art, without departing from the concept of the present invention, several variations and modifications can be made, which all fall within the scope of the present invention. Therefore, the protection scope of the present invention should be subject to the appended claims.

Claims (5)

1. The material distribution mechanism used for the head of the belt conveyor is characterized by comprising a chute body (1), wherein a first chute channel (2) is formed on one side of the chute body (1), and a second chute channel (3) is formed on the other side of the chute body (1);

an intersection area (4) is formed at the upper ends of the first chute channel (2) and the second chute channel (3), a flange connector (5) is formed above the intersection area (4), a baffle (6) is arranged at the bottom of the intersection area (4), a partition plate (7) is connected to the middle position of the intersection area (4), a first flap moving opening (8) is arranged at one side of the partition plate (7), and a second flap moving opening (9) is arranged at the other side of the partition plate (7);

the first turning plate movable opening (8) is connected with a first material distribution turning plate (10), and the lower end of the first material distribution turning plate (10) is provided with a first turning plate shaft (11); the second turning plate movable opening (9) is connected with a second material dividing turning plate (12), and a second turning plate shaft (13) is arranged at the lower end of the second material dividing turning plate (12);

the first distribution flap (10) is rotated by the first flap shaft (11) in order to block the first chute channel (2) or the second chute channel (3);

the second distribution flap (12) is rotated by means of the second flap shaft (13) in order to block the first chute channel (2) or the second chute channel (3).

2. A feed mechanism for a belt conveyor head as in claim 1 further comprising a first drive assembly (14); one end of the first flap shaft (11) is connected with the partition plate (7), and the other end of the first flap shaft (11) extends out of the outer side of the chute body (1) and is connected with the first driving assembly (14).

3. A feed mechanism for a belt conveyor head as in claim 2 further comprising a second drive assembly (15); one end of the second flap shaft (13) is connected with the partition plate (7), and the other end of the second flap shaft (13) extends out of the outer side of the chute body (1) and is connected with the second driving assembly (15).

4. A feed mechanism for a belt conveyor head as claimed in claim 3, characterized in that the first flap shaft (11) is located at a higher level than the second flap shaft (13).

5. The material distributing mechanism for the head of the belt conveyor according to claim 1, wherein the chute body (1) is connected with a loading belt conveyor (16) through the flange interface (5); the first chute channel (2) is butted with a first crusher (17); the second chute channel (3) is in butt joint with a transshipment belt conveyor (18), and the transshipment belt conveyor (18) is in butt joint with a second crusher (19).

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