CN210102980U - Aggregate conveying mechanism - Google Patents

Abstract

The utility model relates to an aggregate conveying mechanism, which comprises a first inclined belt, a quantitative funnel, a second inclined belt, two first funnels, a first belt, a first servo motor, a second belt, a third belt, a fourth belt and a controller, wherein aggregates are conveyed to the first belt through the quantitative funnel, the first inclined belt, the first funnel, the second inclined belt and the other first funnel, the first belt is rotatably arranged on the first servo motor, the second belt and the third belt are both positioned below the first belt, the second belt is positioned at a discharge port of the first belt, when the first servo motor drives the first belt to rotate for a certain angle, the third belt is positioned at the discharge port of the first belt, the third belt is parallel to the fourth belt, the fourth belt is positioned at the discharge port of the third belt, the quantitative funnel and the first servo motor are both electrically connected with the controller, the device achieves the purposes that the structure of the conveying device is simple and aggregates can be distributed into different cabins.

Description

Aggregate conveying mechanism

Technical Field

The utility model relates to a mix the earth field, concretely relates to aggregate transport mechanism.

Background

The aggregate is a granular loose material which plays a role of framework or filling in the concrete, the aggregate is used as a main raw material in the concrete, the aggregate storage device plays roles of framework and support in a building, and a high-tower aggregate bin is usually adopted for storage in the aggregate storage process, the traditional high-tower aggregate bin can only store a pile of aggregates in one room due to the limitation of a conveying mechanism, and as the aggregates are stored more, the requirement on the strength of the indoor wall beam is high, the situation that the bin collapses frequently occurs, and the storage in the mode wastes a large amount of space, later, people divide the bin into a plurality of small bins for storage, thus greatly reducing the wall beam pressure of the whole bin and fully utilizing the space of the bin, however, in this way, each small chamber must be equipped with a transfer mechanism, which makes the transfer device complicated, and a structure for solving the existing problems is urgently needed.

SUMMERY OF THE UTILITY MODEL

In order to solve the technical problem, an object of the present invention is to provide a conveying mechanism for aggregate, which is simple in structure and can distribute aggregate to different chambers.

In order to achieve the above object, the present invention provides an aggregate conveying mechanism, comprising a first inclined belt, a quantitative funnel for controlling aggregate flow, a second inclined belt, two first funnels, a first belt, a first servo motor, a support base, a support rod, a second belt, a third belt, a fourth belt and a controller, wherein a feed inlet of the first inclined belt is located at a discharge outlet of the quantitative funnel, the first funnel is arranged at a discharge outlet of the first inclined belt, the second inclined belt is arranged at a discharge outlet of the first funnel, the other first funnel is arranged at a discharge outlet of the second inclined belt, the first belt is arranged at a discharge outlet of the other first funnel, the first belt is rotatably arranged at an output end of the first servo motor, the first servo motor is fixedly arranged at an upper portion of the support base, the second belt with the third belt all is located the below of first belt, the second belt is located the discharge gate department of first belt works as first servo motor drive during the rotatory certain angle of first belt, the third belt is located the discharge gate department of first belt, the third belt with the fourth belt is parallel to each other, the fourth belt is located the discharge gate department of third belt, first oblique belt the oblique belt of second the first belt the second belt the third belt with the fourth belt all passes through the bracing piece is fixed to be set up subaerial, quantitative funnel with first servo motor all with controller electric connection.

Further, the quantitative funnel comprises a second funnel, a lubricating layer, a rotating plate, an elastic washer, a solid flow meter, a second rotating rod, a second servo motor and a supporting plate, wherein the lubricating layer is distributed on the inner surface of the second funnel, the rotating plate is arranged in the second funnel, the elastic washer is fixedly arranged on the upper portion of the rotating plate, the rotating plate is rotatably arranged on the output end of the second servo motor through the second rotating rod, the second servo motor is fixedly arranged on the outer surface of the second funnel through the supporting plate, the solid flow meter is fixedly arranged in the second funnel and located below the rotating plate, and the solid flow meter and the second servo motor are electrically connected with the controller.

Furthermore, a water spraying system and a smoke sensor are fixedly arranged on the outer surface of the second hopper respectively, and the water spraying system and the smoke sensor are electrically connected with the controller.

Further, all fixedly on the surface of first funnel with the second funnel be equipped with the camera.

Further, the inclination angles of the first inclined belt and the second inclined belt are both 15 degrees.

Further, first servo motor power is connected with first power shaft, first power shaft has first rotary rod through the coupling joint, first rotary rod fixed connection be in the lower part of first belt, second servo motor power is connected with second power shaft, the second rotary rod pass through the coupling joint with second power shaft interconnect.

Further, the belt of the first inclined belt and the belt of the second inclined belt are both provided with an anti-skid layer.

Compared with the prior art, the utility model, its beneficial effect is:

when aggregate on a truck needs to be unloaded to a high-tower aggregate bin, the aggregate firstly enters a quantitative funnel, the discharge flow rate of the aggregate is controlled through the action of the quantitative funnel, the aggregate can further enter a first inclined belt to be conveyed and is further transferred to a second inclined belt through the first funnel, the pressure of the first inclined belt can be reduced through graded conveying, the aggregate is further transferred to the first belt through the second inclined belt, at the moment, a controller controls a first servo motor to rotate, the aggregate can be shunted, the aggregate is conveyed from a third belt or a fourth belt, the aggregate can be distributed into different small bins, the defect that each small bin is provided with one conveying chain in the traditional mode is overcome, and the structure is simple;

the working principle of the quantitative funnel is as follows: when the aggregate passes through the solid flow meter, the flow velocity of the aggregate can be measured, a signal is transmitted to the controller, and then the second servo motor is controlled to rotate, because the second servo motor has the functions of forward rotation and reverse rotation, the rotating plate can be controlled to rotate forward and reverse, thereby controlling the opening of the second funnel, achieving the purpose of controlling the flow rate of the aggregate, arranging the elastic washer on the rotating plate firstly plays a role of reducing the impact force of the aggregate on the rotating plate, then, the second power shaft of the second servo motor can not easily rotate under the action of external force, therefore, when the rotating plate is at a certain fixed position, the flowing aggregate cannot drive the rotating plate to rotate, the elastic washer and the second servo motor play a self-locking role at the position, and the lubricating layer is arranged in the second hopper to protect the inner wall of the second hopper and prolong the service life of the second hopper;

the smoke sensor senses smoke generated by aggregate from the quantitative hopper, and then sends a signal to the controller to control the water spraying system to spray water, so that the aim of dust fall is fulfilled;

the condition of the conveying mechanism can be observed at any time by arranging the camera, so that the purpose of unmanned monitoring is realized;

the coupler is arranged to protect a first power shaft of the first servo motor and a second power shaft of the second servo motor, so that the service lives of the first servo motor and the second servo motor are prolonged;

the anti-slip layer is arranged to enable the aggregate to be on the first inclined belt and the second inclined belt, and backflow cannot occur.

The inclination angles of the first inclined belt and the second inclined belt are both 15 degrees, which is the critical condition that the aggregates flow back in the first inclined belt and the second inclined belt.

Drawings

FIG. 1 is a schematic diagram of a bone conveying mechanism according to the present invention;

FIG. 2 is a schematic view of a bone conveying mechanism according to the present invention;

fig. 3 is an enlarged view of fig. 2 a of the aggregate transfer mechanism of the present invention;

fig. 4 is a schematic view of a quantitative hopper of the aggregate conveying mechanism of the present invention.

In the figure: 1. a first inclined belt; 2. a quantitative funnel; 21. a second hopper; 211. a water injection system; 212. a smoke sensor; 213. a camera; 22. a lubricating layer; 23. a rotating plate; 24. an elastic washer; 25. a solids flow meter; 26. a second rotating rod; 27. a second servo motor; 271. a second power shaft; 28. a support plate; 3. a second inclined belt; 4. A first hopper; 5. a first belt; 6. a first servo motor; 61. a first power shaft; 62. a first rotating rod; 7. a supporting seat; 8. a support bar; 9. a second belt; 10. a third belt; 11. a fourth belt; 12. a coupling is provided.

Detailed Description

In order to explain the technical content, structural features, achieved objects and functions of the present invention in detail, the following embodiments are described in detail with reference to the accompanying drawings.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplicity of description, and do not indicate or imply that the device or element so referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore, should not be taken as limiting the scope of the invention.

Referring to fig. 1 in conjunction with fig. 2-4, the present invention provides an embodiment:

the utility model provides a to achieve the above-mentioned purpose, an aggregate conveying mechanism of the utility model comprises a first inclined belt 1, a quantitative funnel 2 for controlling the aggregate flow, a second inclined belt 3, two first funnels 4, a first belt 5, a first servo motor 6, a supporting seat 7, a supporting rod 8, a second belt 9, a third belt 10, a fourth belt 11 and a controller, wherein the feeding port of the first inclined belt 1 is positioned at the discharging port of the quantitative funnel 2, the first funnel 4 is arranged at the discharging port of the first inclined belt 1, the second inclined belt 3 is arranged at the discharging port of the first funnel 4, the other first funnel 4 is arranged at the discharging port of the second inclined belt 3, the first belt 5 is arranged at the discharging port of the other first funnel 4, the first belt 5 is rotatably arranged at the output end of the first servo motor 6, the first servo motor 6 is fixedly arranged at the upper part of the supporting seat 7, the second belt 9 and the third belt 10 are both positioned below the first belt 5, the second belt 9 is positioned at the discharge port of the first belt 5, when the first servo motor 6 drives the first belt 5 to rotate for a certain angle, the third belt 10 is located at the discharge port of the first belt 5, the third belt 10 and the fourth belt 11 are parallel to each other, the fourth belt 11 is located at a discharge port of the third belt 10, first oblique belt 1 the oblique belt of second 3 first belt 5 the second belt 9 the third belt 10 with fourth belt 11 all passes through bracing piece 8 is fixed to be set up subaerial, quantitative funnel 2 with first servo motor 6 all with controller electric connection.

Aggregate on the truck need be unloaded when high tower aggregate storehouse, the aggregate at first can enter into in the quantitative funnel 2, effect through quantitative funnel 2, the ejection of compact velocity of flow of control aggregate, the aggregate and then can enter into and convey on first oblique belt 1, through first funnel 4 and then transmit on the oblique belt 3 of second, adopt hierarchical conveying, can reduce the pressure of first oblique belt 1, through the oblique belt 3 of second and convey on first belt 5, the first servo motor 6 of controller control rotates this moment, can realize the reposition of redundant personnel of aggregate, or transport on the third belt 10, or transport on the fourth belt 11, so can realize, in distributing the different cabins to the aggregate, the drawback of every cabin of traditional form being equipped with a conveying chain has been broken, moreover, the steam generator is simple in structure.

Further, the quantitative hopper 2 comprises a second hopper 21, a lubricating layer 22, a rotating plate 23, an elastic washer 24, a solid flow meter 25, a second rotating rod 26, a second servo motor 27 and a supporting plate 28, the lubricating layer 22 is fully distributed on the inner surface of the second hopper 21, the rotating plate 23 is arranged in the second hopper 21, the elastic washer 24 is fixedly arranged on the upper part of the rotating plate 23, the rotating plate 23 is rotatably arranged on the output end of the second servo motor 27 through the second rotating rod 26, the second servo motor 27 is fixedly disposed on the outer surface of the second hopper 21 through the support plate 28, the solid flow meter 25 is fixedly disposed in the second hopper 21, and is located below the rotating plate 23, and the solid flow meter 25 and the second servo motor 27 are both electrically connected to the controller.

The working principle of the quantitative funnel 2 is as follows: when the aggregate passes through the solid flow meter 25, the flow velocity of the aggregate can be measured, a signal is transmitted to the controller, and then the second servo motor 27 is controlled to rotate, because the second servo motor 27 has the functions of forward rotation and reverse rotation, the rotation plate 23 can be controlled to rotate forward and reverse, so that the opening of the second hopper 21 is controlled, and the purpose of controlling the flow velocity of the aggregate is achieved, the elastic gasket 24 arranged on the rotation plate 23 firstly plays a role in reducing the impact force of the aggregate on the rotation plate 23, then, the second power shaft 271 of the second servo motor 27 cannot easily rotate under the action of external force, so that when the rotation plate 23 is at a certain fixed position, the flowing aggregate cannot drive the rotation plate 23 to rotate, here, the elastic gasket 24 and the second servo motor 27 play a self-locking role in the rotation plate 23, the lubricating layer 22 arranged in the second hopper 21 plays a role in protecting the inner wall of the second hopper, increasing the service life of the second hopper 21.

It is to be understood that the solids flow meter 25 is prior art and is not set forth herein in any greater detail.

Further, a water spraying system 211 and a smoke sensor 212 are respectively and fixedly arranged on the outer surface of the second hopper 21, and both the water spraying system 211 and the smoke sensor 212 are electrically connected with the controller.

The smoke sensor 212 senses smoke generated by the aggregates from the quantitative hopper 2, and then sends a signal to the controller to control the water spraying system 211 to spray water, so that the aim of dust fall is fulfilled;

it will be appreciated that the smoke sensor 212 and the water spray system 211 are both prior art and will not be described in great detail herein.

Further, cameras 213 are fixedly arranged on the outer surfaces of the first funnel 4 and the second funnel 21.

The camera 213 can be arranged to observe the condition of the conveying mechanism at any time, thereby realizing the purpose of unmanned monitoring.

Further, the inclination angles of the first inclined belt 1 and the second inclined belt 3 are both 15 °.

The inclination angles of the first inclined belt 1 and the second inclined belt 3 are both 15 degrees, which is the critical condition that the aggregates flow back in the first inclined belt 1 and the second inclined belt 3;

further, first servo motor 6 power is connected with first power shaft 61, first power shaft 61 is connected with first rotary rod 62 through shaft coupling 12, first rotary rod 62 fixed connection be in the lower part of first belt 5, second servo motor 27 power is connected with second power shaft 271, second rotary rod 26 through shaft coupling 12 with second power shaft 271 interconnect.

The coupler 12 is arranged to protect the first power shaft 61 of the first servo motor 6 and the second power shaft 271 of the second servo motor 27, so that the service lives of the first servo motor 6 and the second servo motor 27 are prolonged;

further, the belt of the first inclined belt 1 and the belt of the second inclined belt 3 are both provided with an anti-skid layer.

The anti-slip layer is arranged to enable the aggregates to be on the first inclined belt 1 and the second inclined belt 3, and backflow cannot occur.

Claims (7)

1. The utility model provides a aggregate transport mechanism which characterized in that: comprises a first inclined belt (1), a quantitative funnel (2) used for controlling the aggregate flow, a second inclined belt (3), two first funnels (4), a first belt (5), a first servo motor (6), a supporting seat (7), a supporting rod (8), a second belt (9), a third belt (10), a fourth belt (11) and a controller, wherein a feed inlet of the first inclined belt (1) is positioned at a discharge outlet of the quantitative funnel (2), the first funnel (4) is arranged at the discharge outlet of the first inclined belt (1), the second inclined belt (3) is arranged at the discharge outlet of the first funnel (4), another first funnel (4) is arranged at the discharge outlet of the second inclined belt (3), the first belt (5) is arranged at the discharge outlet of the other first funnel (4), and the first belt (5) is rotatably arranged at an output end of the first servo motor (6), the first servo motor (6) is fixedly arranged on the upper portion of the supporting seat (7), the second belt (9) and the third belt (10) are both located below the first belt (5), the second belt (9) is located at the discharge outlet of the first belt (5), when the first servo motor (6) drives the first belt (5) to rotate for a certain angle, the third belt (10) is located at the discharge outlet of the first belt (5), the third belt (10) is parallel to the fourth belt (11), the fourth belt (11) is located at the discharge outlet of the third belt (10), the first inclined belt (1), the second inclined belt (3), the first belt (5), the second belt (9), the third belt (10) and the fourth belt (11) are all fixedly arranged on the ground through the supporting rod (8), the quantitative funnel (2) and the first servo motor (6) are electrically connected with the controller.

2. A bone transport mechanism as claimed in claim 1, wherein: the quantitative hopper (2) comprises a second hopper (21), a lubricating layer (22), a rotating plate (23), an elastic gasket (24), a solid flow meter (25), a second rotating rod (26), a second servo motor (27) and a supporting plate (28), the lubricating layer (22) is fully distributed on the inner surface of the second hopper (21), the rotating plate (23) is arranged in the second hopper (21), the elastic gasket (24) is fixedly arranged on the upper portion of the rotating plate (23), the rotating plate (23) is rotatably arranged on the output end of the second servo motor (27) through the second rotating rod (26), the second servo motor (27) is fixedly arranged on the outer surface of the second hopper (21) through the supporting plate (28), and the solid flow meter (25) is fixedly arranged in the second hopper (21), and the solid flow meter (25) and the second servo motor (27) are both electrically connected with the controller.

3. A bone transport mechanism as claimed in claim 2, wherein: a water spraying system (211) and a smoke sensor (212) are respectively fixedly arranged on the outer surface of the second hopper (21), and the water spraying system (211) and the smoke sensor (212) are electrically connected with the controller.

4. A bone transport mechanism as claimed in claim 3, wherein: the outer surfaces of the first funnel (4) and the second funnel (21) are fixedly provided with cameras (213).

5. A bone transport mechanism as claimed in claim 1, wherein: the inclination angles of the first inclined belt (1) and the second inclined belt (3) are both 15 degrees.

6. A bone transport mechanism as claimed in claim 2, wherein: first servo motor (6) power is connected with first power shaft (61), first power shaft (61) is connected with first rotary rod (62) through shaft coupling (12), first rotary rod (62) fixed connection be in the lower part of first belt (5), second servo motor (27) power is connected with second power shaft (271), second rotary rod (26) through shaft coupling (12) with second power shaft (271) interconnect.

7. A bone transport mechanism as claimed in claim 1, wherein: the belt of the first inclined belt (1) and the belt of the second inclined belt (3) are both provided with an anti-skid layer.

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