CN112875138A - Totally enclosed intelligence feed system - Google Patents

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 inside 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 rotatably 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, the plurality of feeding hoppers are in one-to-one correspondence with the plurality of shaft rods and are arranged at the tail ends of the plurality of shaft rods, the feeding frame is rotatably connected with the plurality of shaft rods, the structure of the feeding system is improved on the basis of the prior art, the matching of the feeding frame and the shaft rods is utilized, thereby meeting the requirement of automatic production of materials without air on the surface.

Description

Totally enclosed intelligence feed system

Technical Field

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

Background

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

Disclosure of Invention

The invention provides a totally-enclosed intelligent feeding system, aiming at solving the problem that a feeding system cannot meet the production requirement of no air on the surface of a material in the prior art.

A totally-enclosed intelligent feeding system comprises a conveying structure, a supporting structure, a rotating structure and a closed structure, wherein the conveying structure is matched with the supporting structure and is arranged on the upper side of the supporting structure, the rotating structure is matched with the conveying structure and is arranged inside the conveying structure, the closed structure is arranged on the outer peripheral side of the conveying structure and is 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 rotatably 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, and the plurality of feeding hoppers are in one-to-one correspondence with the plurality of shaft rods, and the feeding frame is arranged at the tail ends of the shaft levers and is rotationally connected with the shaft levers.

The feeding hoppers comprise shoveling plates with sieve holes and rotating bottom plates, the rotating bottom plates are rotatably 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, 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 and 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 is arranged on the outer peripheral side of the rotating shaft in a spiral mode and covers the rotating structure, and the rotors are arranged on the center line of the conveying belt along the length extending direction of the conveying belt.

Wherein, the fixed strip comprises a plurality of joint fritter, and every joint fritter all is including fixed block, joint port and the joint that is equipped with the conveyer trough, the joint port with the joint set up respectively in the both sides of fixed block, a plurality of the joint fritter passes through the joint port with the joint end to end is in proper order in order to constitute the fixed strip, the conveyer trough set up in the fixed block is close to one side of conveyer belt track, and with the conveyer belt track agrees with mutually.

Wherein, revolution mechanic includes first driving drum, second driving drum and support, first driving drum set up in the upside of support, and with the transport structure upside carry the track to cooperate, the second driving drum then with the transport structure downside carry the track to cooperate, and set up in the downside of support, the support then set up in the upside of axis of rotation.

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

The invention has the beneficial effects that: on the basis of the prior art, the structure of a feeding system is improved, and the feeding frame and the shaft lever are matched, so that the automatic infiltration of the surface of the material is realized, and the requirement on the automatic production of the material with no air on the surface is met.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

Fig. 1 is a schematic structural diagram of a totally enclosed intelligent feeding system of the present invention.

Fig. 2 is a schematic axial structure diagram of the conveying structure and the supporting structure of the totally-enclosed intelligent feeding system.

Fig. 3 is a schematic structural diagram of a conveying track of the totally-enclosed intelligent feeding system.

Fig. 4 is a schematic cross-sectional view of a snap-in nub of the fully enclosed intelligent feeding system of the present invention.

Fig. 5 is a schematic side view of the first transmission drum of the totally enclosed intelligent feeding system of the present invention.

Fig. 6 is a schematic diagram of a side view of a strap of the totally enclosed intelligent feeding system of the present invention.

10-conveying structure, 20-supporting structure, 30-rotating structure, 40-closed structure, 11-conveying crawler belt, 12-rotating shaft, 13-connecting rod, 31-first driving cylinder, 32-second driving 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-barrel body, 312-protruding strip, 313-connecting bearing, 421-shaft lever, 422-hopper, 423-feeding rack, 1111-clamping small block, 1112-fixing block, 1113-clamping port, 1114-clamping joint, 1115-conveying groove, 1121-belt strip, 1122-connecting head, 1123-hinge, 4221-shovelling plate, 4222-rotating bottom plate and 4223-sieve mesh.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are illustrative and intended to be illustrative of the invention and are not to be construed as limiting the invention.

In the description of the present invention, it is to 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 orientations or positional relationships illustrated in the drawings, and are used merely for convenience in describing the present invention and for simplicity in description, and do not indicate or imply that the devices or elements referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, are not to be construed as limiting the present invention. Further, in the description of the present invention, "a plurality" means two or more unless specifically defined otherwise.

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

a totally enclosed intelligent feeding system comprises a conveying structure 10, a supporting structure 20, a rotating structure 30 and a sealing structure 40, wherein the conveying structure 10 is matched with the supporting structure 20 and is arranged on the upper side of the supporting structure 20, the rotating structure 30 is matched with the conveying structure 10 and is arranged inside the conveying structure 10, the sealing structure 40 is arranged on the outer peripheral side of the conveying structure 10 and is matched with the conveying structure 10, the sealing structure 40 comprises a water storage bin body 41 and a rotating vehicle 42, the water storage bin body 41 is arranged on the outer peripheral side of the rotating vehicle 42, the rotating vehicle 42 is rotatably connected with the water storage bin body 41 and is matched with the output end of the conveying structure 10, the rotating vehicle 42 comprises a plurality of shaft rods 421, a plurality of feeding hoppers 422 and a feeding frame 423, the plurality of shaft rods 421 are arranged around the feeding frame 423, the plurality of hoppers 422 are in one-to-one correspondence with the plurality of shaft rods 421 and are disposed at the ends of the plurality of shaft rods 421, and the feeding frame 423 is rotatably connected with the plurality of shaft rods 421.

In this embodiment, the conveying structure 10 is used for conveying materials, the supporting structure 20 is used for cooperating with the conveying structure 10, the rotating structure 30 is used for cooperating with the conveying structure 10, the sealing structure 40 is used for providing a sealed environment, the storage tank 41 is filled with water, the rotating vehicle 42 is used for realizing automatic transportation of materials, the shaft 421 is used for supporting the hopper 422, and the feeding frame 423 is used for supporting a plurality of the shafts 421 and driving the shafts 421 to rotate.

Further, the plurality of hoppers 422 comprise shoveling plates 4221 provided with screen holes 4223 and rotating bottom plates 4222, the rotating bottom plates 4222 are rotatably connected with the shoveling plates 4221 and arranged on the lower side of the shoveling plates 4221, and the shoveling plates 4221 are fixedly connected with the shaft 421.

In this embodiment, the shoveling plate 4221 is used to cooperate with the shaft 421 to contain the material conveyed from the conveying structure 10, the rotating bottom plate 4222 and the shoveling plate 4221 can rotate relatively to each other, so that the material can be thrown in, and the sieve holes 4223 are used to sieve out the 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, wherein a plurality of the connecting rods 13 are wound on the outer periphery of the rotating shaft 12 and are fixedly connected to the conveying track 11, the conveying track 11 is disposed 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 disposed on one side of the conveying belt 112 close to the connecting rods 13, the conveying belt 112 is wound on the outer periphery of the rotating shaft 12 and covers the rotating structure 30, and the plurality of the rotors 113 are disposed on the center line of the conveying belt 112 along the length extending direction of the conveying belt 112.

In this embodiment, the conveying tracks 11 are used for conveying materials, the rotating shaft 12 is used for matching with the connecting rods 13, so that the connecting rods 13 can be fixed on the rotating shaft 12, the connecting rods 13 are used for matching with the conveying tracks 11 and limiting the displacement path of the conveying tracks 11, the fixing bars 111 are used for matching with the connecting rods 13, so that the connecting rods 13 can be matched with the fixing bars 111, so that the conveying tracks 11 can move along the limitation of the connecting rods 13, the rotors 113 are used for increasing the conveying speed of the materials, the rotors 113 rotate on the supporting structure 20 by utilizing the rotation of the rotors 113, so that the materials can rotate on the supporting structure 20, and then the materials and the conveying tracks 11 can move relatively on the basis of the movement of the upper sides of the conveying tracks 11, namely, the acceleration of the material conveying speed is realized.

Further, the fixed strip 111 comprises a plurality of joint fritter 1111, and every joint fritter 1111 all includes fixed block 1112, joint port 1113 and joint 1114 that is equipped with conveyer trough 1115, joint port 1113 with joint 1114 set up respectively in the both sides of fixed block 1112, a plurality of joint fritter 1111 passes through joint port 1113 with joint 1114 end to end in proper order is in order to constitute fixed strip 111, conveyer trough 1115 set up in fixed block 1112 is close to one side of conveyer track 11, and with conveyer track 11 agrees with mutually.

In this embodiment, the clamping small blocks 1111 are spliced with each other to form a spiral structure, that is, the clamping port 1113 and the clamping head 1114 are clamped to form a spiral structure, the fixing block 1112 is used as a carrier for connecting the clamping port 1113 and the clamping head 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, the first transmission cylinder 31 is disposed on the upper side of the bracket 33 and is matched with the conveying track 11 on the upper side of the conveying structure 10, the second transmission cylinder 32 is matched with the conveying track 11 on the lower side of the conveying structure 10 and is disposed on the lower side of the bracket 33, and the bracket 33 is disposed on the upper side of the rotating shaft 12.

In this embodiment, the first driving drum 31 is configured to rotate in cooperation with the conveying track 11, the first driving drum 31 is externally connected to a motor, so as to provide rotational power to the conveying track 11 and enable materials to be put into subsequent production at the outer side of the first driving drum 31, the second driving drum 32 is configured to enable the conveying track 11 to circulate and improve the stability of the conveying track 11 during rotation, and the bracket 33 is configured to limit the positions of the first driving drum 31 and the second driving drum 32.

Further, the first transmission cylinder 31 and the second transmission cylinder 32 have the same structure, and each of the first transmission cylinder 31 and the second transmission cylinder 32 includes a cylinder body 311, a plurality of protruding strips 312, and two connection bearings 313, the two connection bearings 313 are respectively disposed on two sides of the cylinder body 311, and are both fixedly connected to the bracket 33, and the plurality of protrusions are disposed on the outer peripheral side of the cylinder body 311, and are matched with the rotor 113.

In this embodiment, the cylinder 311 is used for rotating, the protruding strips 312 are used for driving the transportation crawler 11 to rotate, and the two connection bearings 313 are used for connecting the cylinder 311 with the bracket 33.

Further, the conveyer belt 112 includes a plurality of belt strips 1121, a plurality of connecting heads 1122 and a plurality of hinges 1123, the plurality of connecting heads 1122 are disposed at one ends of the plurality of belt strips 1121, which are close to the clamping connection small blocks 1111, the plurality of belt strips 1121 and the plurality of clamping connection small blocks 1111 are disposed through the connecting heads 1122 in a one-to-one correspondence manner, and the adjacent belt strips 1121 are connected through the plurality of hinges 1123.

In this embodiment, the belt strips 1121 are connected to the fixing blocks 1112 through the connecting heads 1122, and the adjacent belt strips 1121 are connected through the hinges 1123, so that the conveying track 11 can be spirally arranged, and the belt strips 1121 are configured to be engaged with the rotor 113, so that the rotor 113 can be engaged with the supporting structure 20, and further the rotor 113 can rotate in the conveying track 11, that is, the conveying speed of the material placed on the upper side of the rotor 113 is increased.

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

In this embodiment, the rotating bearing 123 is used for allowing the rotating shaft 12 to rotate, the rotating rod 122 is used for allowing the connecting rod 13 to connect, the base 121 is used for supporting the rotating shaft 12, that is, when necessary, the rotating rod 122 and the base 121 are rotated through the rotating bearing 123, so that the conveying crawler 11 and the rotating shaft 12 can be utilized to complete the cleaning of the conveying crawler 11 when the feeding system is not applicable.

While the invention has been described with reference to a preferred embodiment, it will be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

Claims (6)

1. A totally-enclosed 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 inside 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 rotatably connected with the water storage bin body and 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 plurality of shaft rods are arranged around the feeding frames, and the plurality of feeding hoppers are in one-to-one correspondence with the plurality of shaft rods, and the feeding frame is arranged at the tail ends of the shaft levers and is rotationally connected with the shaft levers.

2. The totally enclosed intelligent feeding system of claim 1, wherein the plurality of hoppers comprise a shoveling plate provided with screen holes and a rotating bottom plate, the rotating bottom plate is rotatably connected with the shoveling plate and arranged at the lower side of the shoveling plate, and the shoveling plate is fixedly connected with the shaft rod.

3. The fully enclosed intelligent feeding system of claim 1, wherein the conveying structure comprises a conveying track, a rotating shaft, and a plurality of connecting rods, the connecting rods are wound around the outer periphery 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 of the conveying belt close to the connecting rods, the conveying belt is wound around the outer periphery of the rotating shaft and covers the rotating structure, and the rotors are arranged on the center line of the conveying belt along the length extension direction of the conveying belt.

4. The totally enclosed intelligent feeding system of claim 2, wherein the fixing strip is composed of a plurality of clamping small blocks, each clamping small block comprises a fixing block with a conveying groove, a clamping port and a clamping joint, the clamping port and the clamping joint are respectively arranged on two sides of the fixing block, the clamping small blocks are sequentially connected end to end through the clamping port and the clamping joint to form the fixing strip, and the conveying groove is arranged on one side, close to the conveying crawler, of the fixing block and is matched with the conveying crawler.

5. The totally enclosed intelligent feeding system of claim 3, wherein the rotating structure comprises a first driving cylinder, a second driving cylinder and a support, the first driving cylinder is disposed on the upper side of the support and is matched with the conveying track on the upper side of the conveying structure, the second driving cylinder is matched with the conveying track on the lower side of the conveying structure and is disposed on the lower side of the support, and the support is disposed on the upper side of the rotating shaft.

6. The totally enclosed intelligent feeding system of claim 5, wherein the first transmission cylinder and the second transmission cylinder are identical in structure and each include a cylinder body, a plurality of protrusions and two connecting bearings, the two connecting bearings are respectively disposed on two sides of the cylinder body and are both fixedly connected with the bracket, and the plurality of protrusions are disposed on the outer peripheral side of the cylinder body and are matched with the rotor.

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