CN112875138B

CN112875138B - Totally-enclosed intelligent feeding system

Info

Publication number: CN112875138B
Application number: CN202011632950.8A
Authority: CN
Inventors: 岳彩同
Original assignee: Xuzhou Shenke Measurement Control Electromechanical Equipment Co ltd
Current assignee: Xuzhou Shenke Measurement Control Electromechanical Equipment Co ltd
Priority date: 2020-12-31
Filing date: 2020-12-31
Publication date: 2024-05-24
Anticipated expiration: 2040-12-31
Also published as: CN112875138A

Abstract

The invention discloses a totally-enclosed intelligent feeding system, which comprises a conveying structure, a supporting structure, a rotating structure and a closed structure, wherein the conveying structure is matched with the supporting structure, the rotating structure is matched with the conveying structure and is arranged in the conveying structure, the closed structure is matched with the conveying structure, the closed structure comprises a water storage bin body and a rotating vehicle, the rotating vehicle is rotationally connected with the water storage bin body and is matched with the output end of the conveying structure, the rotating vehicle comprises a plurality of shaft rods, a plurality of feeding hoppers and a feeding frame, the plurality of shaft rods are arranged around the feeding frame in a one-to-one correspondence manner, and are arranged at the tail ends of the plurality of shaft rods, the feeding frame is rotationally connected with the plurality of shaft rods, and on the basis of the prior art, the structure of the feeding system is improved, and the automatic infiltration of the material surface is realized by utilizing the matching of the feeding frame and the shaft rods, so that the requirement of automatic production of the material without air on the surface is met.

Description

Totally-enclosed intelligent feeding system

Technical Field

The invention relates to the technical field of feeding systems, in particular to a totally-enclosed intelligent feeding system.

Background

Along with development of industrial automation, more and more industries pursue automation in production, but in the prior art, when the surface of a material is free of air, a feeding system is lack of a related feeding system, so that under the requirement of the surface of the material, the automatic production cannot be performed, and further, the production requirement of the industry cannot be met.

Disclosure of Invention

The invention provides a fully-closed intelligent feeding system, which aims to solve the problem that a feeding system cannot meet the production requirement of no air on the surface of a material in the prior art.

The utility model provides a totally enclosed intelligent feed system, includes conveying structure, bearing structure, rotating structure and enclosed construction, conveying structure with bearing structure cooperatees, and set up in bearing structure's upside, rotating structure with conveying structure cooperatees, and set up in conveying structure's inside, enclosed construction set up in conveying structure's periphery side, and with conveying structure cooperatees, enclosed construction includes water storage bin body and rotating cart, water storage bin body set up in the periphery side of rotating cart, the rotating cart with water storage bin body rotate and be connected, and with conveying structure's output cooperation, the rotating cart include a plurality of axostylus axostyle, a plurality of feed hopper and pay-off frame, a plurality of axostylus axostyle encircles the pay-off frame sets up, a plurality of feed hopper with a plurality of axostylus axostyle one-to-one, and set up in the end of axostylus axostyle, the pay-off frame then with a plurality of axostylus axostyle rotates and is connected.

The feeding hoppers comprise shoveling plates with sieve holes and rotating bottom plates, the rotating bottom plates are connected with the shoveling plates in a rotating mode, the rotating bottom plates are arranged on the lower sides of the shoveling plates, and the shoveling plates are fixedly connected with the shaft rods.

The conveying structure comprises a conveying crawler, a rotating shaft and a plurality of connecting rods, wherein the connecting rods are coiled on the periphery side of the rotating shaft and are fixedly connected with the conveying crawler, the conveying crawler is arranged on the upper side of the supporting structure, the conveying crawler comprises a fixing strip, a conveying belt and a plurality of rotors, the fixing strip is arranged on one side, close to the connecting rods, of the conveying belt, the conveying belt disc is arranged on the periphery side of the rotating shaft in a rotating mode, the rotating structure is coated, and the rotors are arranged on the central line of the conveying belt along the length extending direction of the conveying belt.

The fixing strip is composed of a plurality of small clamping blocks, each small clamping block comprises a fixing block provided with a conveying groove, a clamping port and a clamping connector, the clamping ports and the clamping connectors are respectively arranged on two sides of the fixing block, the small clamping blocks are sequentially connected end to end through the clamping ports and the clamping connectors to form the fixing strip, and the conveying grooves are formed in one side, close to the conveying crawler, of the fixing block and are matched with the conveying crawler.

The rotating structure comprises a first transmission cylinder, a second transmission cylinder and a support, wherein the first transmission cylinder is arranged on the upper side of the support and matched with the conveying crawler on the upper side of the conveying structure, the second transmission cylinder is matched with the conveying crawler on the lower side of the conveying structure and arranged on the lower side of the support, and the support is arranged on the upper side of the rotating shaft.

The first transmission cylinder and the second transmission cylinder are identical in structure and comprise a cylinder body, a plurality of protruding strips and two connecting bearings, wherein the two connecting bearings are respectively arranged on two sides of the cylinder body, are fixedly connected with the support, and the plurality of protruding strips are arranged on the outer peripheral side of the cylinder body and are matched with the rotor.

The beneficial effects of the invention are as follows: on the basis of the prior art, the structure of the feeding system is improved, and the matching of the feeding frame and the shaft rod is utilized, so that the automatic infiltration of the surface of the material is realized, and the requirement on the automatic production of the material without air on the surface is met.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described, it being obvious that the drawings in the following description are only some embodiments of the invention, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic diagram of the fully enclosed intelligent feed system of the present invention.

FIG. 2 is a schematic diagram of the axial structure of the conveying structure and the supporting structure of the fully enclosed intelligent feeding system of the present invention.

Fig. 3 is a schematic structural view of a conveyor track of the fully enclosed intelligent feed system of the present invention.

Fig. 4 is a schematic cross-sectional view of a block of the fully enclosed intelligent feed system of the present invention.

Fig. 5 is a schematic side view of the first transmission cylinder of the fully-enclosed intelligent feeding system of the present invention.

FIG. 6 is a schematic side elevational view of the strip of the fully enclosed intelligent feed system of the present invention.

10-Conveying structure, 20-supporting structure, 30-rotating structure, 40-closed structure, 11-conveying crawler, 12-rotating shaft, 13-connecting rod, 31-first transmission cylinder, 32-second transmission cylinder, 33-bracket, 41-water storage bin body, 42-rotating vehicle, 111-fixing strip, 112-conveying belt, 113-rotor, 121-base, 122-rotating rod, 123-rotating bearing, 311-cylinder, 312-protruding strip, 313-connecting bearing, 421-shaft lever, 422-hopper, 423-feeding frame, 1111-clamping small block, 1112-fixing block, 1113-clamping port, 1114-clamping head, 1115-conveying groove, 1121-strip, 1122-connecting head, 1123-hinge, 4221-shoveling plate, 4222-rotating bottom plate and 4223-sieve.

Detailed Description

Embodiments of the present invention are described in detail below, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to like or similar elements or elements having like or similar functions throughout. The embodiments described below by referring to the drawings are illustrative and intended to explain the present invention and should not be construed as limiting the invention.

In the description of the present invention, it should be understood that the terms "length," "width," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like indicate orientations or positional relationships based on the orientation or positional relationships shown in the drawings, merely to facilitate describing the present invention and simplify the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and therefore should not be construed as limiting the present invention. Furthermore, in the description of the present invention, the meaning of "a plurality" is two or more, unless explicitly defined otherwise.

Referring to fig. 1 to 6, the present invention provides a technical solution:

the utility model provides a totally enclosed intelligent feed system, includes conveying structure 10, bearing structure 20, rotating structure 30 and enclosed structure 40, conveying structure 10 with bearing structure 20 cooperatees, and set up in bearing structure 20's upside, rotating structure 30 with conveying structure 10 cooperatees, and set up in conveying structure 10's inside, enclosed structure 40 set up in conveying structure 10's periphery side, and with conveying structure 10 cooperatees, enclosed structure 40 includes water storage bin body 41 and rotating cart 42, water storage bin body 41 set up in rotating cart 42's periphery side, rotating cart 42 with water storage bin body 41 rotates to be connected, and with conveying structure 10's output cooperation, rotating cart 42 includes a plurality of axostylus axostyle 421, a plurality of hopper 422 and pay-off rack 423, a plurality of axostylus axostyle 421 encircles pay-off rack 423 sets up, a plurality of hopper 422 with a plurality of 421 corresponds, and sets up in a plurality of end that conveying structure 10 cooperatees, the water storage bin body 41 sets up in the periphery side of rotating cart 42, rotating cart 42 with a plurality of axostylus axostyle 423 rotates with axostyle 421 one-to-one.

In this embodiment, the conveying structure 10 is used for conveying materials, the supporting structure 20 is used for being matched with the conveying structure 10, the rotating structure 30 is used for being matched with the conveying structure 10, the sealing structure 40 is used for providing a sealing environment, the water storage bin 41 is filled with water, the rotating vehicle 42 is used for enabling the materials to be automatically transported, the shaft 421 is used for supporting the feeding hopper 422, and the feeding frame 423 is used for supporting a plurality of shaft rods 421 and driving the shaft rods 421 to rotate.

Further, the plurality of hoppers 422 includes a plate 4221 with a mesh 4223 and a bottom plate 4222, the bottom plate 4222 is rotatably connected to the plate 4221 and disposed below the plate 4221, and the plate 4221 is fixedly connected to the shaft 421.

In this embodiment, the shoveling plate 4221 is configured to cooperate with the shaft 421 to accommodate the material conveyed from the conveying structure 10, the rotating bottom plate 4222 and the shoveling plate 4221 may rotate relatively, so as to implement feeding of the material, and the mesh 4223 is configured to screen out water in the hopper 422.

Further, the conveying structure 10 includes a conveying track 11, a rotating shaft 12 and a plurality of connecting rods 13, a plurality of the connecting rods 13 are coiled on the outer circumference side of the rotating shaft 12 and are fixedly connected with the conveying track 11, the conveying track 11 is arranged on the upper side of the supporting structure 20, the conveying track 11 includes a fixing strip 111, a conveying belt 112 and a plurality of rotors 113, the fixing strip 111 is arranged on one side, close to the connecting rods 13, of the conveying belt 112, the conveying belt 112 is spirally arranged on the outer circumference side of the rotating shaft 12 and is coated with the rotating structure 30, and the rotors 113 are arranged on the central line of the conveying belt 112 along the length extending direction of the conveying belt 112.

In this embodiment, the conveying track 11 is configured to convey a material, the rotating shaft 12 is configured to cooperate with the connecting rod 13, so that a plurality of connecting rods 13 can be fixed on the rotating shaft 12, the connecting rod 13 is configured to cooperate with the conveying track 11 and limit a displacement path of the conveying track 11, the fixing strip 111 is configured to cooperate with the connecting rod 13, so that the connecting rod 13 can be engaged with the fixing strip 111, further, the conveying track 11 can move along the limitation of the connecting rod 13, and a plurality of rotors 113 are configured to increase a conveying speed of the material, and the rotors 113 are rotated on the supporting structure 20, so that the rotors 113 rotate themselves, so that the material moves relatively to the conveying track 11 on the basis of moving laterally above the conveying track 11, and thus, the speed of conveying the material is accelerated.

Further, the fixing strip 111 is composed of a plurality of small clamping blocks 1111, each small clamping block 1111 includes a fixing block 1112 provided with a conveying groove 1115, a clamping port 1113 and a clamping joint 1114, the clamping ports 1113 and the clamping joints 1114 are respectively arranged on two sides of the fixing block 1112, the small clamping blocks 1111 are sequentially connected end to end through the clamping ports 1113 and the clamping joints 1114 to form the fixing strip 111, and the conveying grooves 1115 are arranged on one side, close to the conveying crawler 11, of the fixing block 1112 and are matched with the conveying crawler 11.

In this embodiment, the plurality of small clamping blocks 1111 are mutually spliced to form a spiral structure, that is, the clamping port 1113 and the clamping joint 1114 are clamped to form a spiral structure, the fixing block 1112 is used as a carrier connected with the clamping port 1113 and the clamping joint 1114, and the fixing block 1112 is engaged with the connecting rod 13, so that the conveying track 11 forms a spiral structure.

Further, the rotating structure 30 includes a first transmission cylinder 31, a second transmission cylinder 32 and a bracket 33, where the first transmission cylinder 31 is disposed on an upper side of the bracket 33 and is matched with the conveying crawler 11 on an upper side of the conveying structure 10, the second transmission cylinder 32 is matched with the conveying crawler 11 on a lower side of the conveying structure 10 and is disposed on a lower side of the bracket 33, and the bracket 33 is disposed on an upper side of the rotating shaft 12.

In this embodiment, the first transmission cylinder 31 is configured to cooperate with the conveyor belt 11 to rotate, the first transmission cylinder 31 is externally connected with a motor, so as to provide power for rotation of the conveyor belt 11, and enable the material to be put into subsequent production on the outer side of the first transmission cylinder 31, the second transmission cylinder 32 is configured to enable the conveyor belt 11 to circulate, and promote stability of the conveyor belt 11 during rotation, and the bracket 33 is configured to limit positions of the first transmission cylinder 31 and the second transmission cylinder 32.

Further, the first transmission cylinder 31 and the second transmission cylinder 32 have the same structure, and each of the first transmission cylinder and the second transmission cylinder comprises a cylinder 311, a plurality of protruding strips 312, and two connecting bearings 313, wherein the two connecting bearings 313 are respectively disposed on two sides of the cylinder 311, are fixedly connected with the bracket 33, and the plurality of protruding strips are disposed on the outer periphery of the cylinder 311 and are matched with the rotor 113.

In this embodiment, the cylinder 311 is configured to rotate, the protruding strip 312 is configured to drive the conveyor belt 11 to rotate, and the two connecting bearings 313 are configured to allow the cylinder 311 to be connected to the bracket 33.

Further, the conveyor 112 includes a plurality of strips 1121 with rotating grooves, a plurality of connectors 1122, and a plurality of hinges 1123, wherein the connectors 1122 are disposed at one ends of the strips 1121 near the small clamping blocks 1111, the strips 1121 and the small clamping blocks 1111 are disposed in one-to-one correspondence with the connectors 1122, and adjacent strips 1121 are connected by the hinges 1123.

In this embodiment, the strips 1121 are connected to the fixing blocks 1112 through the connectors 1122, and the adjacent strips 1121 are connected through the hinges 1123, so that the conveyor belt 11 can be spirally arranged, and the strips 1121 are used to cooperate with the rotor 113, so that the rotor 113 can cooperate with the supporting structure 20, and the rotor 113 can rotate in the conveyor belt 11, that is, the conveying speed of the material placed on the upper side of the rotor 113 is improved.

Further, the rotating shaft 12 includes a rotating bearing 123, a rotating rod 122 and a base 121, the rotating bearing 123 is disposed on the upper side of the base 121, and the rotating rod 122 is disposed on the upper side of the rotating bearing 123 and is fixedly connected with a plurality of connecting rods 13.

In this embodiment, the rotating bearing 123 is configured to rotate the rotating shaft 12, the rotating rod 122 is configured to connect the connecting rod 13, and the base 121 is configured to support the rotating shaft 12, that is, when needed, the rotating rod 122 and the base 121 may rotate through the rotating bearing 123, so that when the feeding system is not applicable, the rotation of the conveying crawler 11 and the rotating shaft 12 can be utilized to complete the cleaning of the conveying crawler 11.

The above disclosure is only a preferred embodiment of the present invention, and it should be understood that the scope of the invention is not limited thereto, and those skilled in the art will appreciate that all or part of the procedures described above can be performed according to the equivalent changes of the claims, and still fall within the scope of the present invention.

Claims

1. The full-closed intelligent feeding system is characterized by comprising a conveying structure, a supporting structure, a rotating structure and a closed structure, wherein the conveying structure is matched with the supporting structure and arranged on the upper side of the supporting structure, the rotating structure is matched with the conveying structure and arranged in the conveying structure, the closed structure is arranged on the outer peripheral side of the conveying structure and matched with the conveying structure, the closed structure comprises a water storage bin body and a rotating vehicle, the water storage bin body is arranged on the outer peripheral side of the rotating vehicle, the rotating vehicle is in rotating connection with the water storage bin body and is matched with the output end of the conveying structure, the rotating vehicle comprises a plurality of shaft rods, a plurality of feeding hoppers and feeding frames, the shaft rods are arranged around the feeding frames, the feeding hoppers are in one-to-one correspondence with the shaft rods and are arranged at the tail ends of the shaft rods, and the feeding frames are in rotating connection with the shaft rods;

the feeding hoppers comprise shoveling plates with sieve holes and a rotating bottom plate, the rotating bottom plate is rotationally connected with the shoveling plates and arranged on the lower sides of the shoveling plates, and the shoveling plates are fixedly connected with the shaft rods;

The conveying structure comprises a conveying track, a rotating shaft and a plurality of connecting rods, wherein the connecting rods are coiled on the outer peripheral side of the rotating shaft and are fixedly connected with the conveying track, the conveying track is arranged on the upper side of the supporting structure, the conveying track comprises a fixing strip, a conveying belt and a plurality of rotors, the fixing strip is arranged on one side, close to the connecting rods, of the conveying belt, the conveying belt disc is arranged on the outer peripheral side of the rotating shaft in a rotating mode, the rotating structure is coated, and the rotors are arranged on the central line of the conveying belt along the length extending direction of the conveying belt; the rotating shaft comprises a rotating bearing, a rotating rod and a base, wherein the rotating bearing is arranged on the upper side of the base, and the rotating rod is arranged on the upper side of the rotating bearing and fixedly connected with a plurality of connecting rods;

the fixing strip consists of a plurality of clamping small blocks, each clamping small block comprises a fixing block provided with a conveying groove, a clamping port and a clamping joint, the clamping ports and the clamping joints are respectively arranged on two sides of the fixing block, the clamping small blocks are sequentially connected end to end through the clamping ports and the clamping joints to form the fixing strip, and the conveying grooves are arranged on one side, close to the conveying crawler, of the fixing block and are matched with the conveying crawler; the clamping small blocks are mutually spliced to form a spiral structure, and the fixing blocks are matched with the connecting rods to form the spiral structure of the conveying crawler belt;

The rotating structure comprises a first transmission cylinder, a second transmission cylinder and a bracket, wherein the first transmission cylinder is arranged on the upper side of the bracket and is matched with the conveying crawler on the upper side of the conveying structure, the second transmission cylinder is matched with the conveying crawler on the lower side of the conveying structure and is arranged on the lower side of the bracket, and the bracket is arranged on the upper side of the rotating shaft; the first transmission cylinder is used for matching with the conveying crawler belt to rotate, and is externally connected with a motor so as to provide rotating power for the conveying crawler belt;

The first transmission cylinder and the second transmission cylinder have the same structure and comprise a cylinder body, a plurality of protruding strips and two connecting bearings, wherein the two connecting bearings are respectively arranged on two sides of the cylinder body, are fixedly connected with the bracket, and the plurality of protruding strips are arranged on the peripheral side of the cylinder body and are matched with the rotor;

the conveying belt comprises a plurality of strips provided with rotating grooves, a plurality of connectors and a plurality of hinges, wherein the connectors are arranged at one ends of the strips, close to the clamping small blocks, the strips and the clamping small blocks are arranged in one-to-one correspondence through the connectors, and adjacent strips are connected through the hinges; the strap is connected with the fixed block through the connector.