MD584Z - Belt conveyor - Google Patents

Abstract

The invention relates to mechanical engineering, in particular to belt conveyors, and can be used for transportation at a wide angle relative to the horizon of dry bulk, semi-dry and wet materials and lump goods.The belt conveyor comprises a frame (1), on which are mounted a drive roll (2) and a tension roll (3), on which is placed a belt (4), based on upper (5) and lower (6) roller bearings, a conveyor drive and a loading hopper (8). On the working surface of the belt (4) are made longitudinal ribs (9) in the form of a triangle in cross section. The lower transverse edge of the loading hopper (8) is made with a profile identical to the profile of the longitudinal ribs (9). In the zone of the loading hopper (8) are mounted horizontal cylindrical roller bearings, and at the outlet from the area of the loading hopper (8) in the central zone of the belt (4) are also mounted horizontal cylindrical roller bearings (11), and under the side faces of the belt (4) are mounted inclined cylindrical roller bearings (10). The drive roll (2) is made barrel-shaped, and on its side faces are fixed to the frame (1) guide trays (7).

Description

The invention relates to the machine building industry, in particular to belt conveyors, and can be used for transporting dry, semi-dry and wet friable materials and bulk loads at a large angle to the horizon.

A belt conveyor is known that includes a frame, at the ends of which two drums are installed: one driving and the other tensioning, a belt closed in a vertical plane that wraps these drums and that rests along its entire length on upper and lower support rollers fixed to the frame [1].

The disadvantages of the known conveyor are the small angle of inclination of the belt relative to the horizon (18…20° for a flat belt) and, as a result, the large length of the conveyor for lifting the load to a greater height, metal consumption and high cost.

As the closest solution, the belt conveyor with a large angle of inclination to the horizon is presented, which contains drive and tension drums, a load transport element, which includes two longitudinal belts located by overlapping, traction cables, belt support crossbars, flexible partition walls [2].

The disadvantages of this conveyor are the complicated construction of both the belt and the belt support and guiding elements, as well as the fact that not all the space between the transverse partitions is uniformly filled with material, and the low reliability due to the large number of elements that make up this conveyor.

The problem that the invention solves consists in reducing the consumption of materials for manufacturing due to the development of a shorter conveyor for transporting loads at the same height, reducing energy consumption.

The problem is solved by the fact that the belt conveyor contains a frame, on which a drive drum is mounted in the upper part and a tension drum in the lower part, on which a belt is placed, which rests on upper and lower support rollers, a conveyor drive mechanism and a loading hopper. On the working surface of the belt, longitudinal ribs triangular in section are made, made of porous rubber and covered with rubber. The lower transverse edge of the loading hopper is made with a profile identical to the profile of the longitudinal ribs. In the area of the loading hopper, horizontal cylindrical support rollers are mounted, and at the exit from the area of the loading hopper in the central area of the belt, horizontal cylindrical support rollers are also mounted, and under the sides of the belt, inclined cylindrical support rollers are mounted. The drive drum is made with a convex surface, and on its sides some guiding grooves are fixed to the frame.

The technical result consists in increasing the friction forces between the transported material and the rib surfaces, as well as the possibility of increasing the inclination angle of the conveyor without the load sliding backwards.

The invention is explained by the drawings in Fig. 1-7, which represent:

- fig.1, general view of the belt conveyor;

- fig.2, section of the ribbed strip;

- fig. 3, section of the belt and the hopper in the material loading area (view A-A in fig. 1);

- fig. 4, section of the belt loaded with material on rollers;

- fig.5, section of the belt on the drive drum;

- fig. 6, diagram of a conveyor section inclined to the horizon;

- fig.7, diagram of the action of forces on the piece of material located between the ribs, view B-B in fig. 6.

The symbols represent:

- in fig.1, ω - angular velocity of the drive drum;

- in fig. 2, p - the pitch of the ribs in the direction perpendicular to the belt axis;

γ - rib profile angle;

h- rib height;

- in fig.5, e - the arrow of the drive drum;

- in Fig. 6, α - the angle of inclination of the belt relative to the horizon; ν - the speed of movement of the belt; G - the gravitational force of the piece located between the ribs of the inclined belt.

The belt conveyor (Fig. 1) includes a frame 1, on which a drive drum 2 is mounted in the upper part, a tension drum 3 in the lower part, the belt 4, upper and lower support rollers 5 and 6, guide chutes 7, a drive mechanism (not shown) of the drum 2, and a funnel 8. On the working surface of the belt 4 (Fig. 2), longitudinal ribs 9 triangular in cross section are made, made of porous rubber and covered with rubber, characterized by the pitch p in the direction perpendicular to the belt axis, the profile angle y and the height h. The ribs are fixed to the belt by gluing or hot or cold vulcanization. The side walls of the funnel 8 enter the recess between the second and third ribs on the side parts of the belt (Fig. 3). In the area of the loading hopper 8, horizontal cylindrical support rollers are mounted, and at the exit from the area of the loading hopper 8 in the central area of the belt 4, horizontal cylindrical support rollers 11 are also mounted, and under the side parts of the belt 4, inclined cylindrical support rollers 10 are mounted. The drive drum 2 (Fig. 5) is made with a convex surface, and on its side parts, some directing chutes 7 are fixed to the frame 1.

The belt conveyor operates in the following way.

When the drum 2 rotates clockwise (Fig. 1), the belt 4 moves to the right and upwards due to the frictional forces between the belt and the drum surface. In the loading area, under the hopper 8, the material is poured onto the belt surface at a constant rate (the adjustment device is not shown). In order to prevent the material from accidentally falling out of the belt during loading, the side walls of the hopper 8 fit into the recesses between the second and third ribs on the sides of the belt, while the lower transverse edge of the loading hopper 8 is made with a profile identical to the profile of the longitudinal ribs 9.

When the belt leaves the hopper, due to the action of the gravity forces of the transported material and the belt, the latter deforms and rests on the horizontal cylindrical support rollers 11, forming a channel (Fig. 4), the longitudinal ribs 9 approach each other and, in this way, the pieces of material are additionally pressed against the side surfaces of the ribs, which increases the reliability of transporting the material in pieces on the belt with a large angle of inclination to the horizon, at the same time, the pieces fixed between the side surfaces of the ribs support the pieces of material located above.

The gravitational force G of the piece located between the ribs of the belt inclined at an angle α to the horizon (fig. 6) is decomposed into two components: one perpendicular to the direction of movement of the belt Gcosα and another parallel to the direction of movement Gsinα. The component Gcosα, which acts in the B-B plane (fig. 6), is decomposed, in turn,

into two forces (fig. 7):

which presses on the rib surfaces. The reactions of the rib surfaces on the piece are indicated by N/2 and are equal to

each with .

The total friction force F between the particle and the rib surfaces is parallel to the direction of belt movement and is

is determined by the relationship:

Compared to the belt without ribs, where the angle γ = 180° and F = fGcosα, the friction force between the piece of material and the surfaces of the ribs is 1/sin times higher. For example, for the rib apex angle γ = 40° the friction force between the piece of material and the belt is 2.92 times higher than for the belt with a flat surface.

When unloading, the belt passes over the drive drum 2 made with a convex surface with the arrow e. Due to the arrow, the reverse deformation of the belt occurs, the lateral surfaces of the ribs move away from each other, which leads to a decrease in the forces of their pressure on the pieces of material or even to the disappearance of these forces and the falling of the pieces under the action of their own gravity forces when the belt passes over the drum. The pieces, which may accidentally fall to the sides, are directed downwards by the directing chutes 7. After the belt passes over the drum 2, it rests on the lower rollers 6, then passes over the tension drum 3. All the elements of the conveyor are fixed on the frame 1.

1. Spivakovsky A.O., Dyachkov V.K. Transporting machines. Moscow, Машиностроение, 1983, c. 487

2. SU 988677 A1 1999.07.27

Claims (1)

Belt conveyor, comprising a frame (1), on which a drive drum (2) is mounted in the upper part and a tension drum (3) in the lower part, on which a belt (4) is placed, which rests on upper (5) and lower (6) support rollers, a conveyor drive mechanism and a loading hopper (8), characterized in that on the working surface of the belt (4) are made longitudinal ribs (9) triangular in section, made of porous rubber and covered with rubber, at the same time the lower transverse edge of the loading hopper (8) is made with a profile identical to the profile of the longitudinal ribs (9), in the area of the loading hopper (8) are mounted horizontal cylindrical support rollers, and at the exit from the area of the loading hopper (8) in the central area of the belt (4) are also mounted horizontal cylindrical support rollers (11), and under the side parts of the belt (4) inclined cylindrical support rollers (10) are mounted, while the drive drum (2) is made with a convex surface, and on its sides some guiding chutes (7) are fixed to the frame (1).