CN220536633U - Cover tile type chute for transferring belt conveyor - Google Patents

Abstract

The utility model discloses a cover tile type chute for transferring a belt conveyor, which comprises a guide section which is obliquely arranged, wherein the upper end of the guide section is connected with a feeding part corresponding to an upstream belt conveyor, the lower end of the guide section is connected with a discharging part corresponding to a downstream belt conveyor, the guide section comprises two side plates which are oppositely arranged left and right, the upper edges of the two side plates are fixedly connected with a top plate together, a plurality of lining plate components are rotatably arranged between the two side plates, and the lining plate components are sequentially arranged along the guide direction and form a bottom plate together; and an angle regulator is respectively arranged between each lining plate component and each side plate. The utility model can realize local or whole inclination adjustment, reduce the influence of design space, is beneficial to realizing normal transfer charging, and has compact structure and convenient maintenance.

Description

Cover tile type chute for transferring belt conveyor

Technical Field

The utility model relates to the technical field of bulk material conveying, in particular to a cover tile type chute for transferring a belt conveyor.

Background

In a conveying system, the transfer of materials on a front belt conveyor and a rear belt conveyor is usually realized through a charging chute, and whether the chute is reasonably designed directly influences the normal operation of the conveying system and the service life of a conveying belt. The inclination angle of the chute is usually 5-10 degrees larger than the static accumulation angle of the material to be transferred, and the inclination angle of the chute needs to be properly increased for the material with relatively large viscosity or the working condition site of the previous working procedure for increasing the water content of the material in order to ensure that the material smoothly passes through the chute without being blocked. Therefore, in practical application, the chute inclination angles of many projects reach more than 50 degrees.

However, the height difference between the front belt conveyor and the rear belt conveyor is often determined according to the field environment or the existing field, and cannot be changed at will, so that if the given height difference between the front belt conveyor and the rear belt conveyor is small, the large inclination angle design of the chute is difficult to realize in space. In order to transfer charging normally, the chute is designed to be the maximum inclination angle which can be realized according to a given space, and then the sectional area of the chute is properly enlarged so as not to be blocked, so that a series of problems such as material cost increase, labor cost increase and the like can be caused. In addition, the existing chute is of a closed design, the side wall of the chute is of a thick steel plate and abrasion-resistant lining plate structure, the whole chute is of a wall thickness and slender pipeline type structure, and the chute is inconvenient to maintain when conditions occur on site.

Disclosure of Invention

The utility model aims to solve the technical problem of providing the cover tile type chute for the transfer of the belt conveyor, which can realize local or whole inclination adjustment, reduce the influence of design space, is beneficial to realizing normal transfer feeding, and has the advantages of compact structure and convenient maintenance.

In order to solve the technical problems, the technical scheme of the utility model is as follows: the upper end of the guide section is connected with a feeding part corresponding to an upstream belt conveyor, the lower end of the guide section is connected with a discharging part corresponding to a downstream belt conveyor, the guide section comprises two side plates which are oppositely arranged left and right, the upper edges of the two side plates are fixedly connected with a top plate together, a plurality of lining plate assemblies are rotatably arranged between the two side plates, and the lining plate assemblies are sequentially arranged along the guide direction and form a bottom plate together; and an angle regulator is respectively arranged between each lining plate component and each side plate.

As the preferable technical scheme, the lining board component comprises a lining board carrier, a wear-resistant lining board is fixedly arranged on the inner side of the lining board carrier, and a lining board shaft is fixedly arranged on the lining board carrier.

As an optimal technical scheme, the angle regulator comprises regulating connecting shafts which are respectively inserted through the two side plates, and the regulating connecting shafts are connected with the corresponding ends of the lining plate shaft in a jaw manner; the outer ends of the side plates, which are positioned at the corresponding adjusting connecting shafts, are respectively provided with a clamping structure.

As a preferred embodiment, the clamping structure comprises a quick clamp.

As a preferable technical scheme, the width of the lining plate shaft is smaller than the distance between the two side plates.

As an optimized technical scheme, bottom supporting plates are fixedly connected to the lower edges of the two side plates respectively, and a maintenance operation port is arranged between the two bottom supporting plates; the bottom support plate is fixedly provided with a bottom support part supported at the position of the lining plate shaft.

Due to the adoption of the technical scheme, the cover tile chute for transferring the belt conveyor comprises the obliquely arranged guide section, wherein the upper end of the guide section is connected with a feeding part corresponding to the upstream belt conveyor, the lower end of the guide section is connected with a discharging part corresponding to the downstream belt conveyor, the guide section comprises two side plates which are oppositely arranged left and right, the upper edges of the two side plates are fixedly connected with a top plate together, a plurality of lining plate assemblies are rotatably arranged between the two side plates, and the lining plate assemblies are sequentially arranged along the guide direction and form a bottom plate together; and an angle regulator is respectively arranged between each lining plate component and each side plate. According to the utility model, the bottom plate of the diversion section is replaced by a plurality of lining plate components which are rotatably arranged, before the diversion section is used, the angle regulator is utilized to respectively regulate the pitching angle of each lining plate component according to the design angle required by material transfer, the plurality of lining plate components with the regulated angles can form the bottom plate shape with different diversion paths, thus achieving the purposes of realizing the required transfer dip angle and the like, and the normal transfer charging can be easily realized without increasing the chute sectional area. And because each lining plate component can be independently adjusted, the base plate can realize local or whole inclination adjustment during use, the influence of design space is reduced, meanwhile, the utility model has compact structure, internal maintenance can be realized by removing one or a plurality of lining plate components, and the maintenance is also convenient.

Drawings

The following drawings are only for purposes of illustration and explanation of the present utility model and are not intended to limit the scope of the utility model. Wherein:

FIG. 1 is a schematic view of a flow guiding section according to an embodiment of the present utility model;

FIG. 2 is an enlarged schematic view of the A-A structure of FIG. 1;

FIG. 3 is a schematic illustration of the removal of a liner plate assembly according to an embodiment of the present utility model;

FIG. 4 is a schematic view showing a state in which a plurality of lining plate assemblies are integrally adjusted to have a large inclination angle according to an embodiment of the present utility model;

FIG. 5 is a schematic view illustrating a state in which the local liner plate assembly is adjusted to have a large inclination angle according to an embodiment of the present utility model;

FIG. 6 is a schematic illustration of a partial liner assembly of an embodiment of the present utility model adjusted to cushion material impact;

fig. 7 is a schematic overall structure of an embodiment of the present utility model.

In the figure: 1-a feeding part; 2-a discharging part; 3-a diversion section; 31-side plates; 32-top plate; 4-a liner plate assembly; 41-a liner carrier; 42-wear-resistant lining board; 43-a backing plate shaft; 5-a bottom support plate; 51-maintenance operation port; 52-a shoe portion; 6-an angle adjuster; 61-adjusting the connecting shaft; 62-clamping structure.

Detailed Description

The utility model is further illustrated in the following, in conjunction with the accompanying drawings and examples. In the following detailed description, exemplary embodiments of the utility model are described by way of illustration only. It is needless to say that the person skilled in the art realizes that the described embodiments may be modified in various different ways without departing from the spirit and scope of the utility model. Accordingly, the drawings and description are to be regarded as illustrative in nature and not as restrictive in scope.

As shown in fig. 1 to 7 together, the cover tile chute for transferring the belt conveyor comprises a diversion section 3 which is obliquely arranged, wherein the upper end of the diversion section 3 is connected with a feeding part 1 corresponding to an upstream belt conveyor, the lower end of the diversion section 3 is connected with a discharging part 2 corresponding to a downstream belt conveyor, materials output by the upstream belt conveyor reach the diversion section 3 through the feeding part 1, and finally reach the downstream belt conveyor through the diversion function of the diversion section 3 through the discharging part 2, so that the material transfer is realized. The foregoing is readily understood by those skilled in the art based on the prior art chute technology and is not described in detail herein.

The diversion section 3 comprises two side plates 31 which are oppositely arranged left and right, the top edges of the side plates 31 are fixedly connected with a top plate 32, a plurality of lining plate components 4 are rotatably arranged between the side plates 31, and a plurality of lining plate components 4 are sequentially arranged along the diversion direction and form a bottom plate together. In this embodiment, the bottom plate of the upper chute guide section 3 is replaced by a plurality of lining plate assemblies 4 which are arranged in sequence. An angle adjuster 6 is disposed between each lining board assembly 4 and the side board 31.

When the angle regulator is used for installing and debugging before use, according to the conditions of materials, such as design angles required by material transfer, the angle regulator 6 is utilized to respectively regulate the pitching angles of the lining plate components 4, and a plurality of lining plate components 4 with well regulated angles can form the shape of a bottom plate with different diversion paths, and partial angle regulation is practically exemplified as follows.

As shown in fig. 4, when the height difference given by the upstream and downstream belt conveyors is smaller, that is, when the design space is smaller, the whole diversion section 3 is still designed according to the maximum achievable inclination angle, then each lining plate assembly 4 is adjusted in a manner that the inclination angles of the diversion directions are sequentially increased, the bottom plate finally forms an approximately arc diversion shape, and the inclination angle larger than the inclination angle of the diversion section 3 can be realized at the middle lower part, so that the required transfer inclination angle of the materials can be realized, and the normal transfer charging can be realized.

As shown in fig. 5, in the above-mentioned case, the inclination angle of a local lining board assembly 4 may be adjusted, and the inclination angle of the lining board assembly 4 is adjusted to be greater than the inclination angle of the diversion section 3, so that the local part of the bottom board realizes the required transfer inclination angle of the material, and under the smooth diversion guidance of the local material, the subsequent lining board assembly 4 is easy to form normal transfer charging by means of the diversion inertia of the material. Of course, in actual use, the certain lining plate component 4 can be adjusted to have a large inclination angle after a few intervals, so that continuous and smooth material transfer is realized.

As shown in fig. 6, under the condition that the material can generate obvious falling impact force, the inclination angle of one or more lining plate assemblies 4 at the lower part can be reduced, so that the falling material is buffered, the impact of the falling material on the downstream belt conveyor is slowed down, and the impact damage of the downstream belt conveyor can be reduced while the smooth transfer and feeding are realized.

Through the adjustment of each welt subassembly 4 angle, chute sectional area need not to increase and just realizes normally reloading the reinforced easily. And because each lining plate component 4 can be independently adjusted, the base plate can realize local or whole inclination adjustment during use, and the adjustment is flexible, thereby not only reducing the influence of design space, but also being easy to adapt to different material conditions for adaptive use.

The lining board assembly 4 in this embodiment includes a lining board carrier 41, where the lining board carrier 41 may have a plate-type or frame structure; the inner side of the lining board carrier 41 is fixedly provided with a wear-resistant lining board 42, and the inner side of the lining board carrier corresponds to the inner side and the outer side of the chute; the lining board carrier 41 is fixedly provided with a lining board shaft 43.

The angle adjuster 6 includes adjusting connecting shafts 61 respectively penetrating through the two side plates 31, the adjusting connecting shafts 61 are connected with the corresponding ends of the lining plate shaft 43 by means of a jaw connection, so that the adjusting connecting shafts 61 and the lining plate shaft 43 form relative fixation in the rotation direction, and therefore, the lining plate assembly 4 can achieve angle fixation as long as the adjusting connecting shafts 61 are locked by rotation.

The outer ends of the side plates 31, which are positioned at the corresponding adjusting connecting shafts 61, are respectively provided with a clamping structure 62, in this embodiment, the whole adjusting connecting shafts 61 and the lining plate shaft 43 are axially clamped and fixed through the clamping structures 62, and the whole shaft is axially locked through clamping and fixing, namely, the angle fixing of the lining plate assembly 4 is realized; and the clamping action of the clamping structure 62 is released, so that the angle adjustment of the lining plate assembly 4 can be performed. Preferably, the clamping structure 62 includes a quick clamp to quickly effect clamping and unclamping of the clamping structure 62; the quick clamp is a well-known common technology, and the structural principle of the quick clamp is not described in detail herein.

In addition, the jaw connection of the adjusting connection shaft 61 and the lining plate shaft 43 also makes the two adjusting connection shafts 61 be easily pulled out and disassembled directly when the clamping structure 62 is released, and the lining plate assembly 4 is easily disassembled after the two adjusting connection shafts 61 are pulled out and disassembled. Preferably, the width of the lining shaft 43 is smaller than the distance between the two side plates 31, so that the lining assembly 4 is not easily blocked and is conveniently detached from the bottom of the guide section 3.

In this embodiment, the bottom support plates 5 are fixedly connected to the lower edges of the two side plates 31, and the bottom support plate 52 supported by the liner plate shaft 43 is fixedly arranged on the bottom support plates 5, so that the liner plate assembly 4 has better bearing capacity on material impact without affecting the inclination adjustment of the liner plate assembly 4 through the above-mentioned bottom support effect, the deformation of the liner plate assembly 4 is reduced, and the service life is prolonged. A maintenance operation port 51 is arranged between the two bottom support plates 5, and when the two bottom support plates 5 cover part of the area of the bottom surface of the flow guide section 3, the left maintenance operation port 51 can still realize the entry and exit of the lining plate assembly 4, and the inside maintenance of the chute is convenient.

The foregoing has shown and described the basic principles, main features and advantages of the present utility model. It will be understood by those skilled in the art that the present utility model is not limited to the embodiments described above, and that the above embodiments and descriptions are merely illustrative of the principles of the present utility model, and various changes and modifications may be made without departing from the spirit and scope of the utility model, which is defined in the appended claims. The scope of the utility model is defined by the appended claims and equivalents thereof.

Claims (6)

1. The utility model provides a belt conveyor is cover tile formula chute for transshipment, includes the water conservancy diversion section that the slope set up, the upper end of water conservancy diversion section is connected with the feeding portion that corresponds with the belt conveyor of upper reaches, the lower extreme of water conservancy diversion section is connected with the discharging portion that corresponds with the belt conveyor of low reaches, its characterized in that: the flow guide section comprises two side plates which are oppositely arranged left and right, the upper edges of the two side plates are fixedly connected with a top plate together, a plurality of lining plate components are rotatably arranged between the two side plates, and the lining plate components are sequentially arranged along the flow guide direction and form a bottom plate together; and an angle regulator is respectively arranged between each lining plate component and each side plate.

2. A cover tile chute for a belt conveyor transfer as in claim 1 wherein: the lining board assembly comprises a lining board carrier, a wear-resistant lining board is fixedly arranged on the inner side of the lining board carrier, and a lining board shaft is fixedly arranged on the lining board carrier.

3. A cover tile chute for a belt conveyor transfer as in claim 2 wherein: the angle regulator comprises regulating connecting shafts which are respectively inserted into the two side plates in a penetrating way, and the regulating connecting shafts are connected with the corresponding ends of the lining plate shaft in a jaw connection way; the outer ends of the side plates, which are positioned at the corresponding adjusting connecting shafts, are respectively provided with a clamping structure.

4. A cover tile chute for a belt conveyor transfer as in claim 3 wherein: the clamping structure comprises a quick clamp.

5. A cover tile chute for a belt conveyor transfer as in claim 2 wherein: the width of the lining plate shaft is smaller than the distance between the two side plates.

6. A cover tile chute for a belt conveyor transfer as in claim 2 wherein: the lower edges of the two side plates are fixedly connected with bottom supporting plates respectively, and a maintenance operation port is arranged between the two bottom supporting plates; the bottom support plate is fixedly provided with a bottom support part supported at the position of the lining plate shaft.