CN111038872A - Rotatory storage device of solid raw materials - Google Patents

Abstract

The invention discloses a solid raw material rotary storage device which comprises a component mounting base and a raw material storage shell. The invention can realize continuous active rotation by utilizing a driving motor, so that the raw material is in a motion state, thereby keeping the activity of the raw material, realizing the kinetic energy required by the raw material in the exporting process, improving the utilization rate of components, and simultaneously reducing the comprehensive cost.

Description

Rotatory storage device of solid raw materials

Technical Field

The invention relates to the field of storage, in particular to a rotary storage device for solid raw materials.

Background

At present, in the aspect of raw material storage, some active raw materials need continuous movement when being stored, but the existing storage device needs two driving devices to drive when rotating and when the raw materials are poured out, so the comprehensive cost is high, and the component utilization rate is low.

Disclosure of Invention

The present invention is directed to a rotary storage device for solid raw materials, which solves the above problems.

In order to achieve the purpose, the invention provides the following technical scheme: a solid raw material rotary storage device comprises a component mounting base and a raw material storage shell, wherein a driving motor mounting shell is mounted at a vertical plate part on one side of the component mounting base, a driving motor is mounted inside the driving motor mounting shell, a main component mounting space is arranged on one side of the component mounting base, a gear combined type rotary state differentiation mechanism is mounted inside the main component mounting space, a main rotary shaft and an auxiliary rotary shaft are mounted in the component mounting base through a main bearing, an auxiliary component mounting space is arranged at one end of the auxiliary rotary shaft, a gear combined radius gradually-increasing type rotary strength enhancement mechanism is mounted inside the auxiliary component mounting space, an assembled type component rotary butt joint mechanism is mounted at the center of the end part of the gear combined radius gradually-increasing type rotary strength enhancement mechanism and at the end part of the main rotary shaft, the other side of the component mounting base is provided with a limiting rotating shaft through a main bearing, the end part of the limiting rotating shaft is fixedly connected with the center of one end of a raw material storage shell through a main connecting plate, the center of the other end of the raw material storage shell is fixedly connected with the end part of the main rotating shaft through an assembled component rotating butt-joint mechanism, the center inside the raw material storage shell is provided with a raw material storage space, the raw material storage shell is provided with a raw material conveying space at one side of the raw material storage space, the raw material storage shell is provided with a raw material falling space communicated with the raw material storage space and the raw material conveying space, the raw material storage shell is provided with a valve at one end of the raw material conveying space, the raw material storage shell is provided with an internal rotating shaft at the center part of the raw material conveying space through the main bearing, the inner rotating shaft is fixedly connected with the center of the gear combination radius gradually-increasing type rotating force enhancing mechanism at one end, located outside, of the inner rotating shaft through another assembling type part rotating butt joint mechanism, and a plurality of stirring rod structures are installed inside the raw material storage space.

Further, the gear-combination type rotation state differentiation mechanism includes a housing for the gear-combination type rotation state differentiation mechanism, a gear installation space for the gear-combination type rotation state differentiation mechanism, a first rotation shaft for the gear-combination type rotation state differentiation mechanism, a second rotation shaft for the gear-combination type rotation state differentiation mechanism, a bearing for the gear-combination type rotation state differentiation mechanism, a main gear for the gear-combination type rotation state differentiation mechanism, a sub-gear for the gear-combination type rotation state differentiation mechanism, a third rotation shaft for the gear-combination type rotation state differentiation mechanism, and a third rotation shaft for the gear-combination type rotation state differentiation mechanism; and a gear installation space for the gear combined type rotating state differentiation mechanism is arranged at the center of the shell for the gear combined type rotating state differentiation mechanism. The gear combination type rotating state differentiation mechanism is characterized in that a first rotating shaft for a gear combination type rotating state differentiation mechanism is installed at the center of one side of a shell of the gear combination type rotating state differentiation mechanism through a bearing for the gear combination type rotating state differentiation mechanism, a second rotating shaft for a two-gear combination type rotating state differentiation mechanism is installed at one side of the shell of the gear combination type rotating state differentiation mechanism respectively, a main gear for the gear combination type rotating state differentiation mechanism is installed at the end part of the first rotating shaft, two auxiliary gears for the gear combination type rotating state differentiation mechanism are installed at the end part of the second rotating shaft for the gear combination type rotating state differentiation mechanism respectively, and the main gear for the gear combination type rotating state differentiation mechanism and the auxiliary gear for the gear combination type rotating state differentiation mechanism are installed at the end part of the third rotating shaft for the gear combination type rotating state differentiation mechanism and the third rotating shaft for the gear combination type rotating The rotating state differentiation mechanism is arranged inside the side surface of the housing.

Further, the gear combination type rotating state differentiation mechanism housing is installed inside the main component installation space.

Furthermore, the end of the third rotating shaft for the gear combination type rotating state differentiating mechanism and the end of the third rotating shaft for the gear combination type rotating state differentiating mechanism are fixedly connected with the ends of the main rotating shaft and the auxiliary rotating shaft respectively.

Further, the gear combination radius gradually-increasing type rotation strength reinforcing machine comprises a hollow shell for a gear combination radius gradually-increasing type rotation strength reinforcing mechanism, a hollow structure for a gear combination radius gradually-increasing type rotation strength reinforcing mechanism, a first rotating shaft for a gear combination radius gradually-increasing type rotation strength reinforcing mechanism, a bearing for a gear combination radius gradually-increasing type rotation strength reinforcing mechanism, and a second rotating shaft for a gear combination radius gradually-increasing type rotation strength reinforcing mechanism, a third rotating shaft for a gear combination radius gradually-increasing type rotating force enhancing mechanism, a first gear for the gear combination radius gradually-increasing type rotating force enhancing mechanism, a second gear for the gear combination radius gradually-increasing type rotating force enhancing mechanism, a third gear for the gear combination radius gradually-increasing type rotating force enhancing mechanism and a fourth gear for the gear combination radius gradually-increasing type rotating force enhancing mechanism; the hollow shell for the gear combination radius gradually-increasing type rotating force enhancing mechanism is internally provided with a hollow structure for the gear combination radius gradually-increasing type rotating force enhancing mechanism, the hollow shell for the gear combination radius gradually-increasing type rotating force enhancing mechanism is provided with a first rotating shaft for the gear combination radius gradually-increasing type rotating force enhancing mechanism through a bearing for the gear combination radius gradually-increasing type rotating force enhancing mechanism, the hollow shell for the gear combination radius gradually-increasing type rotating force enhancing mechanism is provided with a third rotating shaft for the gear combination radius gradually-increasing type rotating force enhancing mechanism through a bearing for the gear combination radius gradually-increasing type rotating force enhancing mechanism through a center of the top of the hollow shell for the gear combination radius gradually-increasing type rotating force enhancing mechanism, and the side surface of the hollow shell for the gear combination radius gradually-increasing type rotating force enhancing mechanism is provided with a gear combination radius gradually-increasing type rotating force enhancing mechanism through a bearing for the gear combination radius A second rotating shaft for the gear combination radius gradually-increasing type rotating force enhancing mechanism, a second gear for the gear combination radius gradually-increasing type rotating force enhancing mechanism and a third gear for the gear combination radius gradually-increasing type rotating force enhancing mechanism are mounted on a shaft body of the second rotating shaft for the gear combination radius gradually-increasing type rotating force enhancing mechanism, a first gear for the gear combination radius gradually-increasing type rotating force enhancing mechanism and a fourth gear for the gear combination radius gradually-increasing type rotating force enhancing mechanism are respectively mounted at the top end of the first rotating shaft for the gear combination radius gradually-increasing type rotating force enhancing mechanism and the bottom end of the third rotating shaft for the gear combination radius gradually-increasing type rotating force enhancing mechanism, and the first gear for the gear combination radius gradually-increasing type rotating force enhancing mechanism is meshed with a tooth structure between the second gears for the gear combination radius gradually-increasing type rotating force enhancing mechanism, the third gear for the gear combination radius gradually-increasing type rotating force enhancing mechanism is meshed with a tooth structure between the fourth gears for the gear combination radius gradually-increasing type rotating force enhancing mechanism.

Further, the structure radius of the first gear reference circle for the gear combination radius gradually-increasing type rotation strength enhancing mechanism is smaller than the structure radius of the second gear reference circle for the gear combination radius gradually-increasing type rotation strength enhancing mechanism, the structure radius of the second gear reference circle for the gear combination radius gradually-increasing type rotation strength enhancing mechanism is larger than the structure radius of the third gear reference circle for the gear combination radius gradually-increasing type rotation strength enhancing mechanism, and the structure radius of the third gear for the gear combination radius gradually-increasing type rotation strength enhancing mechanism is smaller than the structure radius of the fourth gear reference circle for the gear combination radius gradually-increasing type rotation strength enhancing mechanism.

Furthermore, the end part of the first rotating shaft for the gear combination radius gradually-increasing type rotating force enhancing mechanism and the end part of the third rotating shaft for the gear combination radius gradually-increasing type rotating force enhancing mechanism are respectively and fixedly connected with the end parts of the assembled component rotating butt-joint mechanism and the auxiliary rotating shaft.

Further, the assembly-type member rotary docking mechanism includes a first connecting plate for the assembly-type member rotary docking mechanism, a second connecting plate for the assembly-type member rotary docking mechanism, a first bolt hole for the assembly-type member rotary docking mechanism, a second bolt hole for the assembly-type member rotary docking mechanism, a first mounting block for the assembly-type member rotary docking mechanism, a second connecting block for the assembly-type member rotary docking mechanism, a first mounting groove structure for the assembly-type member rotary docking mechanism, a second mounting groove structure for the assembly-type member rotary docking mechanism, a first insertion shaft body for the assembly-type member rotary docking mechanism, a second insertion shaft body for the assembly-type member rotary docking mechanism, a shaft hole for the assembly-type member rotary docking mechanism, and a connecting shaft for the assembly-type member rotary docking mechanism; the center of one end face of the first connecting plate for the assembled component rotary butt joint mechanism and the second connecting plate for the assembled component rotary butt joint mechanism is respectively provided with a first mounting block for the assembled component rotary butt joint mechanism and a second connecting block for the assembled component rotary butt joint mechanism which are in an integrated structure with the first mounting block for the assembled component rotary butt joint mechanism and the second connecting block for the assembled component rotary butt joint mechanism, and the first mounting groove structure for the assembled component rotary butt joint mechanism and the second mounting groove structure for the assembled component rotary butt joint mechanism are respectively arranged in the first mounting block for the assembled component rotary butt joint mechanism and the second connecting block for the assembled component rotary butt joint mechanism, the center parts of the first mounting groove structure and the second mounting groove structure for the assembled component rotary butt-joint mechanism are respectively provided with a first insertion shaft body for the assembled component rotary butt-joint mechanism and a second insertion shaft body for the assembled component rotary butt-joint mechanism, the first insertion shaft body for the assembled component rotary butt-joint mechanism and the second insertion shaft body for the assembled component rotary butt-joint mechanism are arranged at the center parts of the first mounting groove structure and the second mounting groove structure, the shaft holes for the assembled component rotary butt-joint mechanism are arranged at the two ends of the connecting shaft for the assembled component rotary butt-joint mechanism.

Furthermore, the structure radius of the shaft hole for the rotary butting mechanism of the assembled components is in clearance fit with the structure radius of the shaft body of the first inserting shaft body for the rotary butting mechanism of the assembled components and the structure radius of the shaft body of the second inserting shaft body for the rotary butting mechanism of the assembled components.

Furthermore, the first connecting plate for the assembled component rotary butt-joint mechanism and the second connecting plate for the assembled component rotary butt-joint mechanism are respectively and fixedly connected with the main rotating shaft, the side surface of the raw material storage shell, the gear combination radius gradually-increasing type rotary force enhancing mechanism and the shaft body of the inner rotating shaft.

Compared with the prior art, the invention has the beneficial effects that: the invention can realize continuous active rotation by utilizing a driving motor, so that the raw material is in a motion state, thereby keeping the activity of the raw material, realizing the kinetic energy required by the raw material in the exporting process, improving the utilization rate of components, and simultaneously reducing the comprehensive cost.

Drawings

FIG. 1 is a schematic view of a solid raw material rotary storage device according to the present invention;

FIG. 2 is a schematic structural diagram of a gear assembly type rotating state differentiation mechanism in a solid raw material rotating storage device according to the present invention;

FIG. 3 is a schematic structural diagram of a mechanism for increasing the radius of a gear assembly of a rotary solid material storage device according to the present invention;

FIG. 4 is a schematic structural diagram of a rotatable docking mechanism for assembled components of a rotary solid material storage device according to the present invention;

in the figure: 1, a component mounting base 2, a driving motor mounting case 3, a driving motor 4, a main component mounting space 5, a gear-combination type rotation state differentiation mechanism 51, a gear-combination type rotation state differentiation mechanism case 52, a gear mounting space 53, a first rotation shaft 54 for a gear-combination type rotation state differentiation mechanism, a second rotation shaft 55 for a gear-combination type rotation state differentiation mechanism, a bearing 56 for a gear-combination type rotation state differentiation mechanism, a main gear 57 for a gear-combination type rotation state differentiation mechanism, a sub gear 58 for a gear-combination type rotation state differentiation mechanism, a third rotation shaft 59 for a gear-combination type rotation state differentiation mechanism, a third rotation shaft 6, a main bearing 7, a sub rotation shaft 8, a limit rotating shaft, 9, a gear combination radius gradually-increasing type rotating force enhancing mechanism, 91, a hollow shell for the gear combination radius gradually-increasing type rotating force enhancing mechanism, 92, a hollow structure for the gear combination radius gradually-increasing type rotating force enhancing mechanism, 93, a first rotating shaft for the gear combination radius gradually-increasing type rotating force enhancing mechanism, 94, a bearing for the gear combination radius gradually-increasing type rotating force enhancing mechanism, 96, a second rotating shaft for the gear combination radius gradually-increasing type rotating force enhancing mechanism, 97, a third rotating shaft for the gear combination radius gradually-increasing type rotating force enhancing mechanism, 98, a first gear for the gear combination radius gradually-increasing type rotating force enhancing mechanism, 99, a second gear for the gear combination radius gradually-increasing type rotating force enhancing mechanism, 910, and a third gear for the gear combination radius gradually-increasing type rotating force enhancing mechanism, 911, a fourth gear for a gear combination radius increasing type rotational force increasing mechanism, 10, a raw material storage case, 11, an assemblable member rotational docking mechanism, 111, an assemblable member rotational docking mechanism, a first connecting plate, 112, an assemblable member rotational docking mechanism, a second connecting plate, 113, an assemblable member rotational docking mechanism, a first bolt hole, 114, an assemblable member rotational docking mechanism, a second bolt hole, 115, an assemblable member rotational docking mechanism, a first mounting block, 116, an assemblable member rotational docking mechanism, a second connecting block, 117, an assemblable member rotational docking mechanism, a first mounting groove structure, 118, an assemblable member rotational docking mechanism, a second mounting groove structure, 119, an assemblable member rotational docking mechanism, a first insertion shaft body, 1110, an assemblable member rotational docking mechanism, a second insertion shaft body, 1111, axial holes for assembled component rotary butt-joint mechanism, 1112, connecting shafts for assembled component rotary butt-joint mechanism, 12, raw material storage space, 13, raw material falling space, 14, raw material conveying space, 15, valves, 16, stirring rod structure, 17, internal rotating shaft, 18 and helical blades.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1, an embodiment of the present invention: the vertical plate part of one side of the component mounting base 1 is provided with a driving motor mounting shell 2, a driving motor 3 is mounted inside the driving motor mounting shell 2, one side of the component mounting base 1 is provided with a main component mounting space 4, a gear combined type rotating state differentiation mechanism 5 is mounted inside the main component mounting space 4, the component mounting base 1 is provided with a main rotating shaft 6 and an auxiliary rotating shaft 7 through a main bearing 6 in the side, one end of the auxiliary rotating shaft 7 is provided with an auxiliary component mounting space 8, a gear combined radius gradually-increasing type rotating force enhancing mechanism 9 is mounted inside the auxiliary component mounting space 8, the center of the end part of the gear combined radius gradually-increasing type rotating force enhancing mechanism 9 and the end part of the main rotating shaft 6 are both provided with an assembled type component rotating butt joint mechanism 11, the other side of the component mounting base 1 is provided with a limit rotating shaft 8 through a main bearing 6, the end of the limit rotating shaft 8 is fixedly connected with the center of one end of a raw material storage shell 10 through a main connecting plate 9, the center of the other end of the raw material storage shell 10 is fixedly connected with the end of the main rotating shaft 6 through an assembled component rotary butt-joint mechanism 11, the center of the interior of the raw material storage shell 10 is provided with a raw material storage space 12, the raw material storage shell 10 is provided with a raw material conveying space 14 at one side of the raw material storage space 12, the interior of the raw material storage shell 10 is provided with a raw material falling space 13 communicating the raw material storage space 12 with the raw material conveying space 14, the raw material storage shell 10 is provided with a valve 15 at one end of the raw material conveying space 14, the raw material storage shell 10 is provided with an internal rotating shaft 17 through the main bearing 6, a helical blade 18 is arranged on the shaft body of the inner rotating shaft 17, one end of the inner rotating shaft 17 positioned outside is fixedly connected with the center of the gear combination radius gradually-increasing type rotating force enhancing mechanism 9 through another assembled component rotating butt joint mechanism 11, and a plurality of stirring rod structures 16 are arranged inside the raw material storage space 12.

Referring to fig. 2, the gear-combination type rotation state differentiation mechanism 5 includes a housing 51 for a gear-combination type rotation state differentiation mechanism, a gear installation space 52 for a gear-combination type rotation state differentiation mechanism, a first rotation shaft 53 for a gear-combination type rotation state differentiation mechanism, a second rotation shaft 54 for a gear-combination type rotation state differentiation mechanism, a bearing 55 for a gear-combination type rotation state differentiation mechanism, a main gear 56 for a gear-combination type rotation state differentiation mechanism, a sub-gear 57 for a gear-combination type rotation state differentiation mechanism, a third rotation shaft 58 for a gear-combination type rotation state differentiation mechanism, and a third rotation shaft 59 for a gear-combination type rotation state differentiation mechanism; a gear installation space 52 for the gear combination type rotation state differentiation mechanism is provided in the center of the gear combination type rotation state differentiation mechanism housing 51. A first rotating shaft 53 for a gear-combined type rotating state differentiation mechanism is installed at the center of one side of a housing 51 for the gear-combined type rotating state differentiation mechanism through a bearing 55 for the gear-combined type rotating state differentiation mechanism, a second rotating shaft 54 for a two-gear-combined type rotating state differentiation mechanism is installed at one side of the housing 51 for the gear-combined type rotating state differentiation mechanism, a main gear 56 for the gear-combined type rotating state differentiation mechanism is installed at the end part of the first rotating shaft 53 for the gear-combined type rotating state differentiation mechanism, sub-gears 57 for the gear-combined type rotating state differentiation mechanism are installed at the end parts of the second rotating shaft 54 for the two gear-combined type rotating state differentiation mechanisms, the main gear 56 for the gear-combined type rotating state differentiation mechanism and the sub-gear 57 for the gear-combined type rotating state differentiation mechanism are respectively installed through a third rotating shaft 58 for the gear-combined type rotating The three rotation shafts 59 are installed inside the side surface of the gear combination type rotation state differentiation mechanism housing 51; the gear combination type rotating state differentiation mechanism casing 51 is installed inside the main component installation space 4; the end parts of the third rotating shaft 58 for the gear combination type rotating state differentiating mechanism and the third rotating shaft 59 for the gear combination type rotating state differentiating mechanism are respectively and fixedly connected with the end parts of the main rotating shaft 6 and the auxiliary rotating shaft 7, and the main functions of the mechanism are as follows: by utilizing the gear, the conversion capability of the driving motor 3 can be realized, and the dual-purpose of one machine is realized.

Referring to fig. 3, the gear combination radius gradually-increasing type rotation strength enhancing mechanism 9 includes a hollow shell 91 for a gear combination radius gradually-increasing type rotation strength enhancing mechanism, a hollow structure 92 for a gear combination radius gradually-increasing type rotation strength enhancing mechanism, a first rotating shaft 93 for a gear combination radius gradually-increasing type rotation strength enhancing mechanism, a bearing 94 for a gear combination radius gradually-increasing type rotation strength enhancing mechanism, a second rotating shaft 95 for a gear combination radius gradually-increasing type rotation strength enhancing mechanism, a third rotating shaft 97 for a gear combination radius gradually-increasing type rotation strength enhancing mechanism, a first gear 98 for a gear combination radius gradually-increasing type rotation strength enhancing mechanism, a second gear 99 for a gear combination radius gradually-increasing type rotation strength enhancing mechanism, a third gear 910 for a gear combination radius gradually-increasing type rotation strength enhancing mechanism, and a fourth gear for a gear combination radius gradually-increasing type rotation strength enhancing mechanism 911; the hollow shell 91 for the gear combination radius gradually-increasing type rotating force enhancing mechanism is internally provided with a hollow structure 92 for the gear combination radius gradually-increasing type rotating force enhancing mechanism, the bottom center of the hollow shell 91 for the gear combination radius gradually-increasing type rotating force enhancing mechanism is provided with a first rotating shaft 93 for the gear combination radius gradually-increasing type rotating force enhancing mechanism through a bearing 94 for the gear combination radius gradually-increasing type rotating force enhancing mechanism, the top center of the hollow shell 91 for the gear combination radius gradually-increasing type rotating force enhancing mechanism is provided with a third rotating shaft 97 for the gear combination radius gradually-increasing type rotating force enhancing mechanism through a bearing 94 for the gear combination radius gradually-increasing type rotating force enhancing mechanism, the side surface of the hollow shell 91 for the gear combination radius gradually-increasing type rotating force enhancing mechanism is provided with a bearing 94 for the gear combination radius gradually-increasing type rotating force enhancing mechanism A second rotating shaft 95 for a gear combination radius gradually-increasing type rotating force enhancing mechanism, a second gear 99 for a gear combination radius gradually-increasing type rotating force enhancing mechanism and a third gear 910 for a gear combination radius gradually-increasing type rotating force enhancing mechanism are mounted on a shaft body of the second rotating shaft 95 for the gear combination radius gradually-increasing type rotating force enhancing mechanism, a first gear 98 for a gear combination radius gradually-increasing type rotating force enhancing mechanism and a fourth gear 911 for a gear combination radius gradually-increasing type rotating force enhancing mechanism are respectively mounted at the top end of the first rotating shaft 93 for the gear combination radius gradually-increasing type rotating force enhancing mechanism and the bottom end of the third rotating shaft 97 for the gear combination radius gradually-increasing type rotating force enhancing mechanism, and the first gear 98 for the gear combination radius gradually-increasing type rotating force enhancing mechanism and the second gear 99 for the gear combination radius gradually-increasing type rotating force enhancing mechanism The tooth structures of the gear combination radius gradually increasing type rotating force enhancing mechanism are engaged, and the tooth structures between the third gear 910 and the fourth gear 911 are engaged; the structure radius of the first gear 98 reference circle for the gear combination radius gradually-increasing type rotation strength enhancing mechanism is smaller than the structure radius of the second gear 99 reference circle for the gear combination radius gradually-increasing type rotation strength enhancing mechanism, the structure radius of the second gear 99 reference circle for the gear combination radius gradually-increasing type rotation strength enhancing mechanism is larger than the structure radius of the third gear 910 reference circle for the gear combination radius gradually-increasing type rotation strength enhancing mechanism, and the structure radius of the third gear 910 for the gear combination radius gradually-increasing type rotation strength enhancing mechanism is smaller than the structure radius of the fourth gear 911 reference circle for the gear combination radius gradually-increasing type rotation strength enhancing mechanism; the end part of the first rotating shaft 93 for the gear combination radius gradually-increasing type rotating force enhancing mechanism and the end part of the third rotating shaft 97 for the gear combination radius gradually-increasing type rotating force enhancing mechanism are respectively and fixedly connected with the end parts of the assembled component rotating butt-joint mechanism 11 and the auxiliary rotating shaft 7, and the main functions of the gear combination radius gradually-increasing type rotating force enhancing mechanism are as follows: the structural radius of the gear is utilized, so that the rotating speed and the rotating strength are changed.

Referring to fig. 4, the assembly-type member rotary docking mechanism 11 includes a first connecting plate 111 for assembly-type member rotary docking mechanism, a second connecting plate 112 for assembly-type member rotary docking mechanism, a first bolt hole 113 for assembly-type member rotary docking mechanism, a second bolt hole 114 for assembly-type member rotary docking mechanism, a first mounting block 116 for assembly-type member rotary docking mechanism, a second connecting plate 117 for assembly-type member rotary docking mechanism, the first mounting groove structure 118 for the assembled-component rotary docking mechanism, the second mounting groove structure 119 for the assembled-component rotary docking mechanism, the first insertion shaft body 1110 for the assembled-component rotary docking mechanism, the second insertion shaft body 1111 for the assembled-component rotary docking mechanism, the shaft hole 1112 for the assembled-component rotary docking mechanism, and the connecting shaft 1113 for the assembled-component rotary docking mechanism; a plurality of second connecting plates 112 for the assembly-type member rotary docking mechanisms and first bolt holes 113 for the assembly-type member rotary docking mechanisms are provided in the first connecting plate 111 for the assembly-type member rotary docking mechanism and the second connecting plate 112 for the assembly-type member rotary docking mechanism, respectively, a first mounting block 116 for the assembly-type member rotary docking mechanism and a second connecting block 117 for the assembly-type member rotary docking mechanism are provided at the center of one end face of the first connecting plate 111 for the assembly-type member rotary docking mechanism and the second connecting plate 112 for the assembly-type member rotary docking mechanism, respectively, of an integral structure therewith, a first mounting groove structure 118 for the assembly-type member rotary docking mechanism and a second mounting groove structure 119 for the assembly-type member rotary docking mechanism are provided in the first mounting block 116 for the assembly-type member rotary docking mechanism and the second connecting block 117 for the assembly-type member rotary docking mechanism, respectively, a first insertion shaft body 1110 for the assembled component rotary docking mechanism and a second insertion shaft body 1111 for the assembled component rotary docking mechanism are respectively installed at the central parts of the first installation groove structure 118 for the assembled component rotary docking mechanism and the second installation groove structure 119 for the assembled component rotary docking mechanism, the first insertion shaft body 1110 for the assembled component rotary docking mechanism and the second insertion shaft body 1111 for the assembled component rotary docking mechanism are installed at the center parts of the assembled component rotary docking mechanism, and a shaft hole 1112 for the assembled component rotary docking mechanism is installed at each of both ends of the connecting shaft 1113 for the assembled component rotary docking mechanism; the structural radius of the shaft hole 1112 for the assembled component rotary butting mechanism and the structural radius of the shaft body of the first inserting shaft body 1110 for the assembled component rotary butting mechanism and the second inserting shaft body 1111 for the assembled component rotary butting mechanism are in clearance fit; the first connecting plate 111 for the assembled component rotary docking mechanism and the second connecting plate 112 for the assembled component rotary docking mechanism are respectively and fixedly connected with the main rotating shaft 6, the side surface of the raw material storage shell 10, the gear combination radius gradually-increasing type rotating force enhancing mechanism 9 and the shaft body of the internal rotating shaft 17, and the main functions of the mechanism are as follows: when the assembling is needed, the connecting shaft 1113 for the assembled component rotary docking mechanism is sleeved inside the first inserting shaft body 1110 for the assembled component rotary docking mechanism and the second inserting shaft body 1111 for the assembled component rotary docking mechanism, and the assembling can be disassembled by reversing.

The specific use mode is as follows: during the operation of the invention, the position of the valve 15 is moved to the highest point, then the raw material to be stored is poured into the raw material storage space 12, then the valve 15 is closed, the assembled component rotary butt-joint mechanism 11 at the position of the internal rotating shaft 17 is disassembled, so that the device is in a rotating state when the driving motor 3 rotates, the internal raw material is constantly in a moving state, when the raw material needs to be discharged, the assembled component rotary butt-joint mechanism 11 at the position of the raw material storage shell 10 is disassembled, and the assembled component rotary butt-joint mechanism 11 at the other position is assembled, so that the internal rotating shaft 17 can rotate, the helical blade 18 is driven to rotate, and the raw material is poured out.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims (10)

1. A solid feedstock rotary storage device, includes part mounting base (1) and raw materials storage shell (10), its characterized in that: the vertical plate part on one side of the component mounting base (1) is provided with a driving motor mounting shell (2), a driving motor (3) is mounted inside the driving motor mounting shell (2), a main component mounting space (4) is arranged on one side of the component mounting base (1), a gear combined type rotating state differentiation mechanism (5) is mounted inside the main component mounting space (4), the component mounting base (1) is positioned in the side and is provided with a main rotating shaft (6) and an auxiliary rotating shaft (7) through a main bearing (6), one end of the auxiliary rotating shaft (7) is provided with an auxiliary component mounting space (8), a gear combined radius gradually-increasing type rotating force enhancement mechanism (9) is mounted inside the auxiliary component mounting space (8), and the center of the end part of the gear combined radius gradually-increasing type rotating force enhancement mechanism (9) and the end part of the main rotating shaft (6) are both provided with an assembled component rotating butt joint machine The device comprises a component (11), a limit rotating shaft (8) is arranged on the other side of the component mounting base (1) through a main bearing (6), the end part of the limit rotating shaft (8) is fixedly connected with the center of one end of a raw material storage shell (10) through a main connecting plate (9), the center of the other end of the raw material storage shell (10) is fixedly connected with the end part of the main rotating shaft (6) through an assembled component rotating and butting mechanism (11), a raw material storage space (12) is arranged at the center inside of the raw material storage shell (10), a raw material conveying space (14) is arranged on one side of the raw material storage space (12) of the raw material storage shell (10), a raw material which is communicated with the raw material storage space (12) and the raw material conveying space (14) falls into a space (13), and a valve (15) is arranged at one end of the raw material conveying space (14) of the raw material storage shell (10), the raw material storage shell (10) is provided with an inner rotating shaft (17) at the central part of the raw material conveying space (14) through a main bearing (6), a spiral blade (18) is arranged on the shaft body of the inner rotating shaft (17), one end of the inner rotating shaft (17) at the outside is fixedly connected with the center of a gear combination radius gradually-increasing type rotating force enhancing mechanism (9) through another assembled component rotating butt joint mechanism (11), and a plurality of stirring rod structures (16) are arranged inside the raw material storage space (12).

2. The rotary solid feedstock storage device as recited in claim 1, wherein: the gear combination type rotating state differentiation mechanism (5) comprises a housing (51) for the gear combination type rotating state differentiation mechanism, a gear installation space (52) for the gear combination type rotating state differentiation mechanism, a first rotating shaft (53) for the gear combination type rotating state differentiation mechanism, a second rotating shaft (54) for the gear combination type rotating state differentiation mechanism, a bearing (55) for the gear combination type rotating state differentiation mechanism, a main gear (56) for the gear combination type rotating state differentiation mechanism, a secondary gear (57) for the gear combination type rotating state differentiation mechanism, a third rotating shaft (58) for the gear combination type rotating state differentiation mechanism and a third rotating shaft (59) for the gear combination type rotating state differentiation mechanism; a gear installation space (52) for the gear combined type rotation state differentiation mechanism is arranged at the center of the shell (51) for the gear combined type rotation state differentiation mechanism. The gear combination type rotating state differentiation mechanism is characterized in that a first rotating shaft (53) for the gear combination type rotating state differentiation mechanism is installed at the center of one side of a shell (51) for the gear combination type rotating state differentiation mechanism through a bearing (55) for the gear combination type rotating state differentiation mechanism, a second rotating shaft (54) for the gear combination type rotating state differentiation mechanism is installed at one side of the shell (51) for the gear combination type rotating state differentiation mechanism respectively, a main gear (56) for the gear combination type rotating state differentiation mechanism is installed at the end part of the first rotating shaft (53) for the gear combination type rotating state differentiation mechanism, two auxiliary gears (57) for the gear combination type rotating state differentiation mechanism are installed at the end part of the second rotating shaft (54) for the gear combination type rotating state differentiation mechanism respectively, the main gear (56) for the gear combination type rotating state differentiation mechanism and the auxiliary gear (57) for the gear combination type rotating state differentiation mechanism are installed The third rotating shaft (58) and a third rotating shaft (59) for a gear combination type rotating state differentiation mechanism are installed inside the side surface of a housing (51) for a gear combination type rotating state differentiation mechanism.

3. The rotary solid feed storage device of claim 2, wherein: the gear combination type rotating state differentiation mechanism housing (51) is installed inside the main component installation space (4).

4. The rotary solid feed storage device of claim 2, wherein: the end parts of the third rotating shaft (58) for the gear combination type rotating state differentiation mechanism and the third rotating shaft (59) for the gear combination type rotating state differentiation mechanism are respectively fixedly connected with the end parts of the main rotating shaft (6) and the auxiliary rotating shaft (7).

5. The rotary solid feedstock storage device as recited in claim 1, wherein: the gear combination radius gradually-increasing type rotating force enhancing mechanism (9) comprises a hollow shell (91) for a gear combination radius gradually-increasing type rotating force enhancing mechanism, a hollow structure (92) for the gear combination radius gradually-increasing type rotating force enhancing mechanism, a first rotating shaft (93) for the gear combination radius gradually-increasing type rotating force enhancing mechanism, a bearing (94) for the gear combination radius gradually-increasing type rotating force enhancing mechanism, a second rotating shaft (95) for the gear combination radius gradually-increasing type rotating force enhancing mechanism, a third rotating shaft (97) for the gear combination radius gradually-increasing type rotating force enhancing mechanism, a first gear (98) for the gear combination radius gradually-increasing type rotating force enhancing mechanism, a second gear (99) for the gear combination radius gradually-increasing type rotating force enhancing mechanism, a third gear (910) for the gear combination radius gradually-increasing type rotating force enhancing mechanism and a gear combination radius gradually-increasing type rotating force enhancing mechanism A fourth gear (911) for the formula rotation force enhancing mechanism; the hollow shell (91) for the gear combination radius gradually-increasing type rotating force enhancing mechanism is internally provided with a hollow structure (92) for the gear combination radius gradually-increasing type rotating force enhancing mechanism, the bottom center of the hollow shell (91) for the gear combination radius gradually-increasing type rotating force enhancing mechanism is provided with a first rotating shaft (93) for the gear combination radius gradually-increasing type rotating force enhancing mechanism through a bearing (94) for the gear combination radius gradually-increasing type rotating force enhancing mechanism, the top center of the hollow shell (91) for the gear combination radius gradually-increasing type rotating force enhancing mechanism is provided with a third rotating shaft (97) for the gear combination radius gradually-increasing type rotating force enhancing mechanism through a bearing (94) for the gear combination radius gradually-increasing type rotating force enhancing mechanism, and the side surface of the hollow shell (91) for the gear combination radius gradually-increasing type rotating force enhancing mechanism is provided with a gradually-increasing type rotating force enhancing mechanism through a gear combination radius A second rotating shaft (95) for a gear combination radius gradually-increasing type rotating force enhancing mechanism is arranged on a bearing (94) for the increasing type rotating force enhancing mechanism, a second gear (99) for the gear combination radius gradually-increasing type rotating force enhancing mechanism and a third gear (910) for the gear combination radius gradually-increasing type rotating force enhancing mechanism are arranged on a shaft body of the second rotating shaft (95) for the gear combination radius gradually-increasing type rotating force enhancing mechanism, a first gear (98) for the gear combination radius gradually-increasing type rotating force enhancing mechanism and a fourth gear (911) for the gear combination radius gradually-increasing type rotating force enhancing mechanism are respectively arranged at the top end of the first rotating shaft (93) for the gear combination radius gradually-increasing type rotating force enhancing mechanism and the bottom end of the third rotating shaft (97) for the gear combination radius gradually-increasing type rotating force enhancing mechanism, and the gear combination radius gradually-increasing type rotating force enhancing mechanism is meshed with a tooth structure between the gear combination radius gradually-increasing type rotating force enhancing mechanism and a second gear (99), and the gear combination radius gradually-increasing type rotating force enhancing mechanism is meshed with a tooth structure between a third gear (910) and a fourth gear (911).

6. The rotary solid feed stock storage device of claim 5, wherein: the structure radius of a first gear (98) reference circle for the gear combination radius gradually-increasing type rotation strength enhancing mechanism is smaller than the structure radius of a second gear (99) reference circle for the gear combination radius gradually-increasing type rotation strength enhancing mechanism, the structure radius of the second gear (99) reference circle for the gear combination radius gradually-increasing type rotation strength enhancing mechanism is larger than the structure radius of a third gear (910) reference circle for the gear combination radius gradually-increasing type rotation strength enhancing mechanism, and the structure radius of the third gear (910) for the gear combination radius gradually-increasing type rotation strength enhancing mechanism is smaller than the structure radius of a fourth gear (911) reference circle for the gear combination radius gradually-increasing type rotation strength enhancing mechanism.

7. The rotary solid feed stock storage device of claim 5, wherein: the end part of a first rotating shaft (93) for the gear combination radius gradually-increasing type rotating force enhancing mechanism and the end part of a third rotating shaft (97) for the gear combination radius gradually-increasing type rotating force enhancing mechanism are fixedly connected with the end parts of the assembled component rotating butt joint mechanism (11) and the auxiliary rotating shaft (7) respectively.

8. The rotary solid feedstock storage device as recited in claim 1, wherein: the assembled component rotary butt-joint mechanism (11) comprises a first connecting plate (111) for the assembled component rotary butt-joint mechanism, a second connecting plate (112) for the assembled component rotary butt-joint mechanism, a first bolt hole (113) for the assembled component rotary butt-joint mechanism, a second bolt hole (114) for the assembled component rotary butt-joint mechanism, a first mounting block (116) for the assembled component rotary butt-joint mechanism, and a second connecting block (117) for the assembled component rotary butt-joint mechanism, a first mounting groove structure (118) for an assembled component rotary docking mechanism, a second mounting groove structure (119) for an assembled component rotary docking mechanism, a first insertion shaft body (1110) for an assembled component rotary docking mechanism, a second insertion shaft body (1111) for an assembled component rotary docking mechanism, a shaft hole (1112) for an assembled component rotary docking mechanism, and a connecting shaft (1113) for an assembled component rotary docking mechanism; the first connecting plate (111) for the assembled component rotary butt joint mechanism and the second connecting plate (112) for the assembled component rotary butt joint mechanism are respectively provided with a plurality of second connecting plates (112) for the assembled component rotary butt joint mechanism and first bolt holes (113) for the assembled component rotary butt joint mechanism, the first connecting plate (111) for the assembled component rotary butt joint mechanism and the second connecting plate (112) for the assembled component rotary butt joint mechanism are respectively provided with a first mounting block (116) for the assembled component rotary butt joint mechanism and a second connecting block (117) for the assembled component rotary butt joint mechanism which are integrally structured with the first mounting block (116) and the second connecting block (117) for the assembled component rotary butt joint mechanism, and the first mounting groove structure (118) and the second connecting block (117) for the assembled component rotary butt joint mechanism are respectively provided with a first mounting groove structure (118) for the assembled component rotary butt joint mechanism and a second connecting block (117) for the assembled component rotary butt joint mechanism And a second mounting groove structure (119) for a joint mechanism, wherein a first insertion shaft body (1110) for a rotary joint mechanism of the assemblable member and a second insertion shaft body (1111) for a rotary joint mechanism of the assemblable member are respectively mounted at the center of the first mounting groove structure (118) for a rotary joint mechanism of the assemblable member and the second mounting groove structure (119) for a rotary joint mechanism of the assemblable member, the first insertion shaft body (1110) for a rotary joint mechanism of the assemblable member and the second insertion shaft body (1111) for a rotary joint mechanism of the assemblable member are mounted at the center of the rotary joint mechanism of the assemblable member, and a shaft hole (1112) for a rotary joint mechanism of the assemblable member is provided at each of both ends of the connecting shaft (1113) for the rotary joint mechanism of the assemblable member.

9. The rotary solid feedstock storage device as recited in claim 8, wherein: the structure radius of the shaft hole (1112) for the assembled component rotary butt joint mechanism is in clearance fit with the structure radius of the shaft body of the first inserting shaft body (1110) for the assembled component rotary butt joint mechanism and the structure radius of the shaft body of the second inserting shaft body (1111) for the assembled component rotary butt joint mechanism.

10. The rotary solid feedstock storage device as recited in claim 8, wherein: the first connecting plate (111) and the second connecting plate (112) for the assembled component rotary butt-joint mechanism are respectively and fixedly connected with the main rotating shaft (6), the side surface of the raw material storage shell (10), the gear combination radius gradually increasing type rotating force enhancing mechanism (9) and the shaft body of the inner rotating shaft (17).

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