CN211392623U - Flow-controllable distributing trough - Google Patents

Abstract

A flow-controllable material distributing groove comprises an inclined groove main body, wherein a plurality of blanking ports are formed in the bottom surface of the groove main body; a rotary material baffle plate is rotatably connected behind the blanking port; a gap is reserved between the rotating material baffle plate and the bottom surface of the trough main body; the width of the fixed striker plate is consistent with that of the corresponding blanking port, and the height of the fixed striker plate is consistent with that of the inner cavity of the trough main body; one side of the blanking port, which is close to the center line of the main body of the material groove, is connected with a movable material baffle plate which can be detachably moved; the movable striker plate is formed by connecting two plate bodies which are vertical to each other, and the height of the two plate bodies is consistent with that of the corresponding fixed baffle plate; the first plate body is parallel to the fixed baffle plate and is attached to the fixed baffle plate, the second plate body is parallel to the side wall of the trough main body, and the length of the second plate body is consistent with that of the corresponding blanking port; the side walls of the first plate body, the fixed material baffle plate, the second plate body and the trough main body are surrounded at the periphery of the corresponding blanking port; the moving direction of the movable material baffle is the width direction of the corresponding blanking port.

Description

Flow-controllable distributing trough

Technical Field

The utility model belongs to the technical field of grain machinery, specifically a controllable branch silo of flow.

Background

In the prior art, grains freely fall into a granary from a chute in an inclined state. The grain in the granary is accumulated to be in a small mountain shape, and the peak position is the parabolic end point of the grain falling from the free falling body of the material notch, so that the unevenness of materials in the granary can be caused, and the problem of material grading is even brought. The grain classification is that the classification phenomenon can occur according to the characteristics of grain particles in the process that the grain slides from a peak to a mountain foot. Taking rice as an example, the relatively broken particles are distributed at the bottom of the cone and are close to the side wall of the granary, and the relatively complete particles are mostly concentrated at the position far away from the side wall of the granary. When getting the material, bring inhomogeneous problem easily.

Disclosure of Invention

In order to solve the technical problem, the utility model provides a flow-controllable material distributing groove, which comprises an inclined groove main body, wherein a plurality of material discharging openings are arranged on the bottom surface of the groove main body; taking the material sliding direction as the front;

the adjacent blanking ports are respectively positioned on different sides of the center line of the main body of the material groove;

a rotating material baffle plate is rotatably connected behind any one blanking port, the rotating axis of the rotating material baffle plate is vertical to the central line of the main body of the trough, and the rotating track of the rotating material baffle plate is behind the corresponding blanking port; a gap is reserved between the rotating striker plate and the bottom surface of the trough main body in a state that the rotating striker plate is vertical to the horizontal plane;

a fixed material baffle is connected in front of any blanking port, the width of the fixed material baffle is consistent with that of the corresponding blanking port, and the height of the fixed material baffle is consistent with that of the inner cavity of the trough main body;

one side of any blanking port, which is close to the center line of the main body of the trough, is connected with a movable striker plate which can be detachably moved; the movable striker plate is formed by connecting two plate bodies which are vertical to each other, and the height of the two plate bodies is consistent with that of the corresponding fixed baffle plate; the first plate body is parallel to the fixed baffle plate and is attached to the fixed baffle plate, the second plate body is parallel to the side wall of the trough main body, and the length of the second plate body is consistent with that of the corresponding blanking port; the side walls of the first plate body, the fixed material baffle plate, the second plate body and the trough main body are surrounded at the periphery of the corresponding blanking port; the moving direction of the movable material baffle is the width direction of the corresponding blanking port.

This divide the silo to make the blanking of each placement comparatively even through the blanking mouth that distributes the setting. The material distributing groove can be used for a traditional square granary or a silo (a plurality of material distributing grooves are symmetrically formed around the central axis of the silo).

The rotating baffle can push materials in the direction corresponding to the incoming material of the blanking port flat, here, the rotating shaft of the rotating baffle can be located at the top of the inner cavity of the main body of the trough, and the rotating baffle depends on the self gravity to droop, so that the material feeding device can be better suitable for materials with different flow rates. The baffle can be prevented from being clamped by the materials through the gap between the rotating material baffle and the bottom surface of the trough main body.

According to the material type, adjust the activity striker plate (can be by waist type hole cooperation bolted connection structure connection first plate body and fixed striker plate), and then adjust the volume that the lateral wall of first plate body, fixed striker plate, second plate body and silo main part encloses into the cavity, adjust the flow of corresponding blanking mouth. The two plate bodies can be obtained by bending one steel plate.

Furthermore, a final blanking port is formed at the foremost end of the trough main body, and the width of the final blanking port is consistent with that of the bottom surface of the trough main body. The materials which fail to fall through the other blanking ports finally fall completely through the final blanking port.

A plurality of baffles are connected below the bottom surface of the trough main body, and one baffle is connected in front of each blanking port. Under the structure, the material can be prevented from forming a parabola forward, and the material can directly fall after leaving the blanking port. When the materials in the bin are higher and higher, the material dropping point of the material flow in the parabolic state is more and more backward, and the dropping point is not convenient to control.

This divide silo can form a plurality of blanking points, and the flow control of every blanking point is controllable, has avoided the material to pile up inhomogeneous problem.

Drawings

FIG. 1 is a schematic structural diagram of the material distributing groove;

FIG. 2 is a top view schematic of FIG. 1;

FIG. 3 is a schematic view of a blanking port from a top view;

FIG. 4 is a partial view of the structure of a blanking port;

in the figure: silo main part 1, blanking mouth 2, silo main part central line 3, rotate striker plate 4, final blanking mouth 5, baffle 6, fixed striker plate 7, activity striker plate 8, rotate the clearance 8 between the bottom surface of striker plate and silo main part, first plate body 9, second plate body 10. The direction of the unidirectional arrow is the material flow direction, and the direction of the bidirectional arrow is the rotation direction of the rotating striker plate.

Detailed Description

The present disclosure is further described with reference to the following embodiments in conjunction with the accompanying drawings:

as shown in fig. 1 to 4, a flow-controllable material separating groove comprises an inclined groove main body, wherein a plurality of material discharging openings are formed in the bottom surface of the groove main body; taking the material sliding direction as the front;

the adjacent blanking ports are respectively positioned on different sides of the center line of the main body of the material groove;

a rotating material baffle plate is rotatably connected behind any one blanking port, the rotating axis of the rotating material baffle plate is vertical to the central line of the main body of the trough, and the rotating track of the rotating material baffle plate is behind the corresponding blanking port; a gap is reserved between the rotating striker plate and the bottom surface of the trough main body in a state that the rotating striker plate is vertical to the horizontal plane;

a fixed material baffle is connected in front of any blanking port, the width of the fixed material baffle is consistent with that of the corresponding blanking port, and the height of the fixed material baffle is consistent with that of the inner cavity of the trough main body;

one side of any blanking port, which is close to the center line of the main body of the trough, is connected with a movable striker plate which can be detachably moved; the movable striker plate is formed by connecting two plate bodies which are vertical to each other, and the height of the two plate bodies is consistent with that of the corresponding fixed baffle plate; the first plate body is parallel to the fixed baffle plate and is attached to the fixed baffle plate, the second plate body is parallel to the side wall of the trough main body, and the length of the second plate body is consistent with that of the corresponding blanking port; the side walls of the first plate body, the fixed material baffle plate, the second plate body and the trough main body are surrounded at the periphery of the corresponding blanking port; the moving direction of the movable material baffle is the width direction of the corresponding blanking port.

In this example, the final material-dropping opening is formed at the foremost end of the trough main body, and the width of the final material-dropping opening is the same as the width of the bottom surface of the trough main body. A plurality of baffles are connected below the bottom surface of the trough main body, and one baffle is connected in front of each blanking port.

Claims (3)

1. A flow-controllable material distributing groove comprises an inclined groove main body and is characterized in that a plurality of blanking ports are formed in the bottom surface of the groove main body; taking the material sliding direction as the front;

the adjacent blanking ports are respectively positioned on different sides of the center line of the main body of the material groove;

a rotating material baffle plate is rotatably connected behind any one blanking port, the rotating axis of the rotating material baffle plate is vertical to the central line of the main body of the trough, and the rotating track of the rotating material baffle plate is behind the corresponding blanking port; a gap is reserved between the rotating striker plate and the bottom surface of the trough main body in a state that the rotating striker plate is vertical to the horizontal plane;

a fixed material baffle is connected in front of any blanking port, the width of the fixed material baffle is consistent with that of the corresponding blanking port, and the height of the fixed material baffle is consistent with that of the inner cavity of the trough main body;

one side of any blanking port, which is close to the center line of the main body of the trough, is connected with a movable striker plate which can be detachably moved; the movable striker plate is formed by connecting two plate bodies which are vertical to each other, and the height of the two plate bodies is consistent with that of the corresponding fixed baffle plate; the first plate body is parallel to the fixed baffle plate and is attached to the fixed baffle plate, the second plate body is parallel to the side wall of the trough main body, and the length of the second plate body is consistent with that of the corresponding blanking port; the side walls of the first plate body, the fixed material baffle plate, the second plate body and the trough main body are surrounded at the periphery of the corresponding blanking port; the moving direction of the movable material baffle is the width direction of the corresponding blanking port.

2. The trough of claim 1 wherein the trough body has a final blanking opening at the forward-most end, the final blanking opening having a width corresponding to the width of the bottom of the trough body.

3. The trough of claim 1 wherein a plurality of baffles are attached below the bottom of the trough body, one baffle being attached in front of each blanking opening.

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