RU2318716C1 - Belt conveyer loading device - Google Patents

Abstract

FIELD: conveyer construction, particularly devices to load belt conveyers with material having small and medium particle dimensions and with sorted loads.

SUBSTANCE: device comprises inclined gutter secured to frame and inclined to horizontal line. The gutter has concave profile in cross-section. Front gutter edge is spaced over load-carrying belt section. Front gutter edge has curvilinear elliptical cut symmetric about longitudinal gutter axis and directed to side opposite to load-carrying conveyer belt movement direction. Maximal cut width and depth thereof may be calculated from the following correlations: B-b=g(sinβ-f cosβ)·t²+a, l=v·t·cosα, t=[(v·g^-1sinα)²-2g^-1h]0.5-g^-1v·sinα, here b is maximal cut width, m; B is gutter width, m; l is cut depth defined in horizontal plane, m; t is time of load movement along ballistic trajectory from cut edge to belt surface, s; v is load movement velocity at cut edge, m/s; a - maximal conveyed particle size, m; α is angle of gutter inclination at cut edge, deg.; β is average gutter side inclination angle at gutter edge, deg.; f is friction coefficient between load and gutter bottom; h is height of cut edge projection over belt surface relatively front gutter end, m; g is gravitational acceleration, m/s².

EFFECT: increased operational reliability and elimination of guiding sides.

2 cl, 4 dwg

Description

The invention relates to conveyor engineering, and in particular to devices for loading conveyor belts mainly small, medium and sorted loads.

A device is known for loading a conveyor belt for freight to be transported, containing a gutter of a curved shape, placed with a minimum clearance above the load-bearing branch of the conveyor belt (Polunin V.T., Gulenko G.N. Conveyors for mining enterprises. M., Nedra, 1978, p. 106-107, Fig. 3.3).

A disadvantage of the known device is the inability to center the flow of goods and the need, in connection with this, the use of guide rails with elastic aprons, which causes increased wear of the working lining of the tape, the aprons themselves and increases the complexity of servicing the loading device.

A device for loading a conveyor belt (prototype) is provided, comprising a gutter inclined to the horizon with a concave profile in cross section and with a front edge of the gutter with a minimum clearance above the load-carrying branch of the belt (Spivakovsky A.O., Dyachkov V.K. machines. M., Mechanical Engineering, 1968, p. 123-124, Fig. 77b).

The disadvantage of the prototype device is the insufficient centering of the cargo flow when it is fed to the conveyor belt with the possibility of spillage of the transported cargo through the sides of the load-bearing branch of the belt.

The technical result of the invention is to increase the reliability of the loading device due to the effective centering of the cargo flow on the load-bearing branch of the belt and eliminating the spillage of the transported cargo, the ability to perform the loading device without guide rails.

The technical result is achieved in that in a device for loading a conveyor belt comprising a gutter inclined to the horizon with a concave profile in cross section and with the front edge of the gutter placed with a gap above the load-carrying branch of the belt, according to the invention, the front edge of the gutter is made with a curved cut ellipsoidal shape, located symmetrically to the longitudinal axis of the trough and oriented in the direction opposite to the direction of movement of the load-bearing branch of the tape, while the maximum Irina cut and its depth in terms taken from the relations

Bb = g (sinβ-fcosβ) t ² + a, l = vtcosα,

t = [(vg ^-1 sinα) ² -2g ^-1 h] ^0.5 -g ^-1 vsinα,

where b is the maximum width of the cutout, m, B is the width of the trench, m, l is the depth of the cutout measured horizontally, t is the time the cargo moves along the ballistic trajectory from the edge of the cutout to the surface of the tape, v is the speed of movement of the cargo when it leaves the edge cut-out, m / s, а - maximum size of a piece of transported cargo, m, α - tilt angle of the trough at the edge of the cut, hail, β - average tilt angle of the sides of the trough at its edge, hail, f - coefficient of friction of the load on the bottom of the trough, h - excess of the cut edge above the surface of the tape relative to the front edge of the same Both, g - acceleration of gravity, m / s ^2. The gutter may have a curved shape in the longitudinal direction.

A device for loading a conveyor belt is shown in FIG. 1 — a longitudinal section, in FIG. 2 - a plan in FIG. 1, in FIG. 3 - a section A - A in FIG. 1, in FIG. 4 - a section B - B in FIG. .one.

A device for loading a conveyor belt comprises a gutter 1 mounted on a frame (not shown) with a concave profile in cross section and with a front edge of the gutter placed with a gap above the load-carrying branch of the belt 2. The front edge of the gutter 1 is made with an ellipsoidal curved cut 3, located symmetrically to the longitudinal axis 4 of the groove 1 and oriented in the direction opposite to the direction 5 of the movement of the load-bearing branch of the tape 2. Moreover, the maximum width of the cut 3 and its depth in plan are taken from relations

Bb = g (sinβ-fcosβ) t ² + a, l = vtcosα,

T = [(vg ^-1 sinα) ² -2g ^-1 h] ^0.5 -g ^-1 vsinα,

where b is the maximum width of the cutout, m, B is the width of the trough, m, l is the depth of the cut measured horizontally, m, t is the time the cargo moves along the ballistic trajectory from the edge of the cut to the surface of the tape, s, v is the speed of the cargo at its descent from the edge of the cut, m / s, and a is the maximum size of a piece of transported cargo, m, α is the angle of inclination of the gutter at the edge of the cut, deg, β is the average angle of inclination of the sides of the gutter at its edge, deg, f is the coefficient of friction the bottom of the gutter, h is the excess of the cut edge above the surface of the tape relative to the front edge and gutters, g - acceleration of gravity, m / s ² . Due to this, the edge of the groove 1 facing the load-carrying branch of the tape 2 has sections 6 and 7 of length l inclined to the longitudinal axis 4. The gutter 1 may have a curved shape in the longitudinal direction with a radius R of its downward deflection.

A device for loading a conveyor belt operates as follows. The cargo (not shown) to be transported by a belt conveyor is supplied in one way or another to the chute 1, at which it accelerates to a speed close to the speed of the load-carrying branch of the belt 2. In this case, first of all, to the load-carrying branch of the belt 2 through the farthest from the front edge of the chute 1, the part of the load located in the middle of the trench 1 is unloaded. The part of the load moving near the sides of the trough 1 in its sections 6 and 7 changes its direction of movement, sliding into the freed area from these sections towards axis 4. With setting chute 1 unload cargo from it reaches the load-carrying branch of the belt 2 is outside the front edge of the chute 1 in the course of the belt, not falling under the front edge of the gutter. This ensures constant centering of the cargo flow with the placement of the transported cargo in the Central part of the load-bearing branch of the belt 2 of the conveyor.

Distinctive features of the invention provide increased reliability of the loading device due to the effective centering of the cargo flow on the load-bearing branch of the belt and elimination of spillage of the transported cargo through the sides of the belt, as well as the possibility of making the loading device without guide rails.

Claims (2)

1. A device for loading a conveyor belt comprising a gutter inclined to the horizon with a concave profile in cross section and with a front edge of the gutter with a gap above the load-carrying branch of the belt, characterized in that the front edge of the gutter is made with an ellipsoidal curved cutout located symmetrically to the longitudinal axis of the trough and oriented in the direction opposite to the direction of movement of the load-bearing branch of the tape, while the maximum width of the cut and its depth in the plan are accepted and h ratios B-b = g (sinβ-fcosβ) t ² + a, l = vtcosα, t = [(vg ^-1 sinα) ² -2g ^-1 h] ^0.5 -g ^-1 vsinα, where b is the maximum width of the cutout, m; In - the width of the gutter, m; l is the depth of the cut, measured horizontally, m; t is the time of movement of the cargo along a ballistic trajectory from the edge of the cut to the surface of the tape, s; v is the speed of movement of the cargo when it leaves the edge of the cut, m / s; а - maximum size of a piece of transported cargo, m; α is the angle of inclination of the gutter at the edge of the cut, degrees; β is the average angle of inclination of the sides of the gutter at its edge, deg; f is the coefficient of friction of the load on the bottom of the gutter; h - excess of the cut edge above the surface of the tape relative to the front edge of the gutter, m; g - acceleration of gravity, m / s ² . 2. The device according to claim 1, characterized in that the gutter has a curved shape in the longitudinal direction.

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