CN220484386U - Device for conveying solid materials at large angle - Google Patents

Abstract

The utility model relates to the technical field of material conveying, in particular to a device for conveying solid materials at a large angle, which comprises a conveying frame body and a conveying belt rotatably arranged at the inner side of the conveying frame body, wherein a supporting component is arranged on the outer wall of the conveying frame body, a plurality of connecting plates are fixedly connected to an outer surface array of the conveying belt, T-shaped grooves are formed in the wall surfaces, far away from the conveying belt, of the connecting plates, two T-shaped blocks are sequentially and slidably attached to the inside of each T-shaped groove from front to back, and a limiting mechanism is arranged between each T-shaped block and each T-shaped groove, and the device has the beneficial effects that: through the mutually supporting of connecting plate, T type groove, T type piece, stop gear, first material shell and second material shell, the length of its bucket of this tilting bucket elevator can be according to the simple and easy regulation length of the volume of material transportation to need not to dismantle the bucket of changing corresponding length, brought the convenience, reduce the time of production stagnant.

Description

Device for conveying solid materials at large angle

Technical Field

The utility model relates to the technical field of material conveying, in particular to a device for conveying solid materials at a large angle.

Background

An inclined bucket elevator is a device for transporting solid material by means of one or more chains or belt conveyors with bucket receptacles which can be mounted on the chains or belt conveyors, which enable material transport over a large angular range and form a circulating transport system.

However, the length of the bucket of the existing inclined bucket elevator is fixed, which means that the amount of material lifted each time is fixed, if the amount of material delivery needs to be adjusted, the bucket with the corresponding length often needs to be detached and replaced on a conveyor belt on the inclined bucket elevator, and a plurality of bucket containers on the conveyor belt exist, which may cause inconvenience and production dead time. To this end we propose a device for transporting solid material at large angles.

Disclosure of Invention

The present utility model is directed to a device for transporting solid materials at a large angle, which solves the problems set forth in the background art.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides a device of large-angle transport solid material, includes the carriage body and rotates the conveyer belt that sets up in the carriage body inboard, be equipped with supporting component on the outer wall of carriage body, the surface array fixedly connected with polylith connecting plate of conveyer belt, polylith the T type groove has all been seted up to the wall that the conveyer belt was kept away from to the connecting plate, the inside in T type groove is from the past to the laminating of sliding in proper order has two T type pieces, two be equipped with stop gear between T type piece and the T type groove, and the tip of two T type pieces is fixedly connected with first material shell and second material shell respectively, first material shell and the equal laminating of second material shell are kept away from on the wall of conveyer belt at the connecting plate, the laminating of second material shell is in the inner wall of first material shell.

Preferably, the supporting component comprises a supporting frame, the supporting frame is fixedly connected to the outer wall of the conveying frame body, and the lower end of the supporting frame is fixedly connected with a bottom frame.

Preferably, the stop gear includes two sets of cambered surface grooves and two sleeves, two sets of cambered surface grooves are from the past to the symmetry setting is offered in T type inslot portion bottom, two the sleeve is fixed respectively to be alternates in the inner wall of two T type pieces, and the equal slip laminating of two telescopic interiors has the sphere round pin, two the sphere of sphere round pin respectively with one of them cambered surface groove sliding fit in two sets of cambered surface grooves, and two sphere round pins keep away from one end in cambered surface groove respectively with two telescopic inside top surfaces between all be equipped with the elastic component.

Preferably, the elastic piece comprises a spring, one end of the spring is fixedly connected with one end of the spherical pin, which is far away from the cambered surface groove, and the other end of the spring is fixedly connected between the inner top ends of the sleeves.

Preferably, the number of the cambered surface grooves in each group is at least five, and the five cambered surface grooves are distributed in a linear array.

Preferably, the first material shell and the T-shaped block on the first material shell and the second material shell and the T-shaped block on the second material shell are of an integrated structure.

Compared with the prior art, the utility model has the beneficial effects that: through the mutually supporting of connecting plate, T type groove, T type piece, stop gear, first material shell and second material shell, the length of its bucket of this tilting bucket elevator can be according to the simple and easy regulation length of the volume of material transportation to need not to dismantle the bucket of changing corresponding length, brought the convenience, reduce the time of production stagnant.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present utility model;

FIG. 2 is a partial view of the present utility model;

FIG. 3 is a schematic view of the structure at A in FIG. 2;

FIG. 4 is a cross-sectional view of the present utility model at a connection plate;

FIG. 5 is an illustration of a T-block, sleeve, web and T-slot of the present utility model;

fig. 6 is an illustration of a second material shell, a first material shell, a T-block and a spherical pin of the present utility model.

In the drawings, the list of components represented by the various numbers is as follows: 1. a conveyor belt; 2. a conveying frame body; 3. a second material shell; 4. a first material shell; 5. a chassis; 6. a support frame; 7. a T-shaped block; 8. a sleeve; 9. a connecting plate; 10. a cambered surface groove; 11. a T-shaped groove; 12. a spring; 13. a spherical pin.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1-6, a device for conveying solid materials at a large angle in the illustration comprises a conveying frame body 2 and a conveying belt 1 rotatably arranged on the inner side of the conveying frame body 2, wherein a supporting component is arranged on the outer wall of the conveying frame body 2, a plurality of connecting plates 9 are fixedly connected to an outer surface array of the conveying belt 1, T-shaped grooves 11 are formed in the wall surfaces of the plurality of connecting plates 9 away from the conveying belt 1, two T-shaped blocks 7 are sequentially and slidably attached to the inner surfaces of the T-shaped grooves 11 from front to back, a limiting mechanism is arranged between the two T-shaped blocks 7 and the T-shaped grooves 11, the end parts of the two T-shaped blocks 7 are fixedly connected with a first material shell 4 and a second material shell 3 respectively, the first material shell 4 and the second material shell 3 are attached to the wall surfaces of the connecting plates 9 away from the conveying belt 1, and the second material shell 3 is slidably attached to the inner wall of the first material shell 4.

Referring to fig. 1 and 2, the support assembly in the drawings includes a support frame 6, the support frame 6 is fixedly connected to the outer wall of the conveying frame 2, and the lower end of the support frame 6 is fixedly connected to a bottom frame 5; by providing the support frame 6 and the bottom frame 5, the carriage body 2 can be supported on the ground.

Referring to fig. 2-5, in the illustration, the limiting mechanism includes two sets of arc grooves 10 and two sleeves 8, the two sets of arc grooves 10 are symmetrically arranged from front to back and are arranged at the bottom ends inside the T-shaped grooves 11, the two sleeves 8 are respectively fixedly inserted into the inner walls of the two T-shaped blocks 7, the inner parts of the two sleeves 8 are respectively and slidably attached with spherical pins 13, the spherical surfaces of the two spherical pins 13 are respectively and slidably matched with one of the arc grooves 10 in the two sets of arc grooves 10, and elastic pieces are respectively arranged between one ends, far away from the arc grooves 10, of the two spherical pins 13 and the inner top surfaces of the two sleeves 8.

Referring to fig. 4, the elastic member includes a spring 12, one end of the spring 12 is fixedly connected to one end of the spherical pin 13 away from the arc slot 10, and the other end of the spring 12 is fixedly connected between the inner top ends of the sleeve 8.

Referring to fig. 3 and 4, in the drawings, the number of each set of cambered surface grooves 10 is at least five, and the five cambered surface grooves 10 are arranged in a linear array; the uniform cambered surface grooves 10 are distributed so that the first material shell 4 and the second material shell 3 can be orderly adjusted.

Referring to fig. 6, in the illustration, the first material shell 4 and the T-shaped block 7 on the first material shell 4 and the second material shell 3 and the T-shaped block 7 on the second material shell 3 are all integrally formed; the stability between the first material shell 4 and the T-shaped block 7 on the first material shell 4 is good, and the stability between the second material shell 3 and the T-shaped block 7 on the second material shell 3 is good.

Working principle: the first material shell 4 and the second material shell 3 form a bucket-shaped container of the inclined bucket elevator. If the length of the bucket container needs to be adjusted to adjust the conveying amount of materials, for example, when the required quantity of the materials to be conveyed is more, the first material shell 4 and the second material shell 3 can be held to slide away from each other on the connecting plate 9 on the conveying belt 1, the first material shell 4 and the second material shell 3 can drive the respective connected T-shaped blocks 7 to slide away from each other in the T-shaped groove 11, the spherical pins 13 in the two T-shaped blocks 7 can slide away from each other in the inner bottom end of the T-shaped groove 11, the spherical surfaces of the spherical pins 13 can be attached to the cambered surface grooves 10 on the inner wall of the T-shaped groove 11 in the process, the spherical pins 13 can slide upwards in the sleeve 8, the spherical pins 13 can squeeze the springs 12 connected with the sleeve 8 until the spherical pins 13 slide into the next cambered surface groove 10, under the acting force of the springs 12, the spherical surfaces of the spherical pins 13 can be automatically inserted into the cambered surface grooves 10, and the first material shell 4 and the second material shell 3 can keep certain fixed states and cannot slide, the first material shell 4 and the second material shell 3 can not slide away from each other, the first material shell 3 and the second material shell 3 can be detached from each other according to the required length of the first material shell 3, the two sets of the inner wall 3 and the first material shell 3 and the second material shell 3 can not be detached from each other, and the first material shell 3 has different lengths and the required length of the first material shell 3 can be changed, and the length of the material can be changed, and the different from the material can be set and the length and the material can be different, and the length can be different from the material container.

It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. The utility model provides a device of large-angle transport solid material, includes carriage body (2) and rotates conveyer belt (1) that sets up in carriage body (2) inboard, its characterized in that: be equipped with supporting component on the outer wall of carriage body (2), the surface array fixedly connected with polylith connecting plate (9) of conveyer belt (1), polylith T type groove (11) have all been seted up to the wall that conveyer belt (1) was kept away from to connecting plate (9), the inside of T type groove (11) is followed the laminating of sliding in proper order and is had two T type pieces (7), two be equipped with stop gear between T type piece (7) and T type groove (11), and the tip of two T type pieces (7) is first material shell (4) and second material shell (3) fixedly connected with respectively, first material shell (4) all laminate on the wall that conveyer belt (1) was kept away from to connecting plate (9) with second material shell (3), second material shell (3) sliding laminating is in the inner wall of first material shell (4).

2. A device for transporting solid materials at large angles as claimed in claim 1, wherein: the supporting component comprises a supporting frame (6), the supporting frame (6) is fixedly connected to the outer wall of the conveying frame body (2), and the lower end of the supporting frame (6) is fixedly connected with a bottom frame (5).

3. A device for transporting solid materials at large angles as claimed in claim 1, wherein: stop gear includes two sets of cambered surface groove (10) and two sleeve (8), two sets of cambered surface groove (10) are from the past to the symmetry setting and are offered in the inside bottom of T type groove (11), two sleeve (8) are fixed respectively to alternate in the inner wall of two T type pieces (7), and the inside of two sleeve (8) all slides the laminating and have spherical round pin (13), two the sphere of spherical round pin (13) respectively with one of them cambered surface groove (10) sliding fit in two sets of cambered surface groove (10), and the one end that cambered surface groove (10) were kept away from to two spherical round pins (13) respectively with all be equipped with the elastic component between the inside top surface of two sleeve (8).

4. A device for transporting solid materials at large angles as claimed in claim 3, wherein: the elastic piece comprises a spring (12), one end of the spring (12) is fixedly connected with one end of the spherical pin (13) far away from the cambered surface groove (10), and the other end of the spring (12) is fixedly connected between the inner top ends of the sleeves (8).

5. A device for transporting solid materials at large angles as claimed in claim 3, wherein: the number of the cambered surface grooves (10) in each group is at least five, and the five cambered surface grooves (10) are distributed in a linear array.

6. A device for transporting solid materials at large angles as claimed in claim 1, wherein: the T-shaped blocks (7) on the first material shell (4) and the second material shell (3) are of an integrated structure.