CN112060438A

CN112060438A - Quantitative pouring system for high-molecular wear-resistant wheel

Info

Publication number: CN112060438A
Application number: CN202010683949.1A
Authority: CN
Inventors: 赵崇明; 王岩岩; 李凯; 孙艺; 杨欢
Original assignee: Maanshan Jiute New Material Technology Co ltd
Current assignee: Maanshan Jiute New Material Technology Co ltd
Priority date: 2020-07-16
Filing date: 2020-07-16
Publication date: 2020-12-11

Abstract

The invention relates to the technical field of wear-resistant wheels, and discloses a quantitative pouring system for a high-molecular wear-resistant wheel, which comprises a bottom plate, wherein a driving motor is fixedly connected to the side wall of the upper side of the bottom plate, an output shaft of the driving motor is fixedly connected with a threaded rod, two movable plates are sleeved on the rod wall of the threaded rod in a threaded manner, threaded holes are formed in the side walls of the left sides of the two movable plates, the threaded rod penetrates through the movable plates through the threaded holes, the side walls of the upper sides of the two movable plates are fixedly connected with a same transverse plate, a pouring box is arranged on the side wall of the upper side of the transverse plate, a rotating plate is fixedly connected to the outer wall. The automatic pouring device can automatically pour, effectively improves the safety of pouring operation, has lower labor intensity and improves the pouring efficiency.

Description

Quantitative pouring system for high-molecular wear-resistant wheel

Technical Field

The invention relates to the technical field of wear-resistant wheels, in particular to a quantitative pouring system for a high-molecular wear-resistant wheel.

Background

The macromolecule abrasion-resistant wheel is an abrasion-resistant wheel made of macromolecule materials, and a pouring system is needed to pour raw materials into a mould in the production and processing processes, and then the raw materials are waited for cooling and forming.

The existing pouring system needs manual pouring when in use, and is dangerous to operate due to the fact that the temperature of raw materials is high, serious safety accidents can be caused by operation mistakes, the labor intensity of manual pouring is high, and the pouring efficiency is low.

Disclosure of Invention

The invention aims to solve the problems that manual operation is dangerous and low in efficiency in the prior art, and provides a quantitative pouring system for a high-molecular wear-resistant wheel.

In order to achieve the purpose, the invention adopts the following technical scheme:

a quantitative pouring system for a high-molecular wear-resistant wheel comprises a bottom plate, wherein a driving motor is fixedly connected to the side wall of the upper side of the bottom plate, a threaded rod is fixedly connected to the output shaft of the driving motor, two movable plates are sleeved on the threaded sleeve of the rod wall of the threaded rod, threaded holes are formed in the two side walls of the left side of each movable plate, the threaded rod penetrates through the movable plates through the threaded holes, the two side walls of the upper sides of the movable plates are fixedly connected with a transverse plate, a pouring box is arranged on the side wall of the upper side of the transverse plate, a rotating plate is fixedly connected to the outer wall of the right side of the pouring box, a fixed shaft is fixedly connected to the side wall of the upper side of the transverse plate, a through hole is formed in the, the side wall fixedly connected with motor of L template upside, the outer fixed cover of output shaft of motor is equipped with the stranded conductor wheel, the lateral wall fixedly connected with fixed pulley on L template right side, it is equipped with same root steel cable to wind between fixed pulley and the stranded conductor wheel, the lateral wall fixedly connected with pull ring of pouring box upside, the one end and the pull ring fixed connection of steel cable.

Preferably, the lateral wall of diaphragm upside has seted up the mounting groove, the first magnetite of fixedly connected with in the mounting groove of telling, the left outer wall fixedly connected with second magnetite of pouring box, the polarity of the relative one side of first magnetite and second magnetite is opposite.

Preferably, the lateral wall fixedly connected with backup pad of bottom plate upside, the dead eye has been seted up to the lateral wall on backup pad right side, the pore wall of dead eye passes through the bearing and is connected with the threaded rod rotation, the lateral wall fixedly connected with gag lever post on backup pad right side, two spacing hole has all been seted up to the left lateral wall of movable plate, the gag lever post runs through the movable plate through spacing hole.

Preferably, two equal fixedly connected with two mounting panels of lateral wall of movable plate downside, two fixedly connected with pivot between the mounting panel, movable sleeve is equipped with the gyro wheel outside the pivot.

Preferably, the side wall of the right side of the pouring box is fixedly connected with a pouring nozzle.

Preferably, the lateral wall fixedly connected with fixed plate on diaphragm right side, the lateral wall fixedly connected with supporting shoe of fixed plate upside.

Preferably, the bent part of the L-shaped plate is fixedly connected with a reinforcing rod.

Preferably, the right end of the limiting rod is fixedly connected with a baffle.

Preferably, the side wall of the upper side of the bottom plate is fixedly connected with a bearing seat, the side wall of the right side of the bearing seat is provided with a rotating hole, and the rotating hole is rotatably connected with the rod wall of the threaded rod through a ball bearing.

Compared with the prior art, the invention provides a quantitative pouring system for a high-molecular wear-resistant wheel, which has the following beneficial effects:

the quantitative pouring system for the high-molecular wear-resistant wheel comprises a bottom plate, a driving motor, a threaded rod, a movable plate, threaded holes, transverse plates, a pouring box, a rotating plate, a fixed shaft, a graduated scale, an L-shaped plate, a motor, a wire twisting wheel, a fixed pulley, a steel rope and a pull ring, wherein the graduated scale is arranged to guide quantitative raw materials into the pouring box, the driving motor is controlled to rotate, the driving motor drives the threaded rod to rotate, the two movable plates are driven to move rightwards through the threaded fit between the threaded rod and the threaded holes, the two movable plates drive the transverse plates to move, the transverse plates drive the pouring box to move rightwards, when the pouring box reaches a pouring position, the motor is controlled to rotate, the motor drives the wire twisting wheel to rotate, the wire twisting wheel winds the steel rope, pulls the pouring box to rotate around a fixed axis of the fixed, the pouring system can automatically pour, effectively improves the safety of pouring operation, has lower labor intensity and improves the pouring efficiency.

The parts which are not involved in the device are the same as or can be realized by adopting the prior art, the automatic pouring device can automatically pour, effectively improves the safety of pouring operation, has lower labor intensity and improves the pouring efficiency.

Drawings

FIG. 1 is a schematic structural diagram of a quantitative pouring system for a high molecular wear-resistant wheel according to the present invention;

FIG. 2 is a schematic structural view of portion A of FIG. 1;

FIG. 3 is a schematic structural diagram of portion B of FIG. 1;

fig. 4 is a schematic structural view of a portion B in fig. 1.

In the figure: the device comprises a base plate 1, a driving motor 2, a threaded rod 3, a movable plate 4, a threaded hole 5, a transverse plate 6, a pouring box 7, a rotating plate 8, a fixed shaft 9, a graduated scale 10, an L-shaped plate 11, a motor 12, a twisted wire wheel 13, a fixed pulley 14, a steel rope 15, a pull ring 16, a mounting groove 17, a first magnet 18, a second magnet 19, a support plate 20, a bearing hole 21, a limiting rod 22, a limiting hole 23, a mounting plate 24, a rotating shaft 25, a roller 26, a pouring nozzle 27, a fixing plate 28, a support block 29, a reinforcing rod 30, a baffle 31, a bearing seat 32 and a rotating hole 33.

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.

In the description of the present invention, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are merely for convenience in describing the present invention and simplifying the description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention.

Referring to fig. 1-4, a quantitative pouring system for a high-molecular wear-resistant wheel comprises a bottom plate 1, a driving motor 2 is fixedly connected to the side wall of the upper side of the bottom plate 1, a threaded rod 3 is fixedly connected to the output shaft of the driving motor 2, two movable plates 4 are respectively and threadedly sleeved on the rod wall of the threaded rod 3, threaded holes 5 are respectively formed in the left side walls of the two movable plates 4, the threaded rod 3 penetrates through the movable plates 4 through the threaded holes 5, the same transverse plate 6 is fixedly connected to the upper side walls of the two movable plates 4, a pouring box 7 is arranged on the upper side wall of the transverse plate 6, a rotating plate 8 is fixedly connected to the outer wall of the right side of the pouring box 7, a fixed shaft 9 is fixedly connected to the side wall of the upper side of the transverse plate 6, a through hole is formed in the, a motor 12 is fixedly connected to the side wall of the upper side of an L-shaped plate 11, a wire twisting wheel 13 is fixedly sleeved outside an output shaft of the motor 12, a fixed pulley 14 is fixedly connected to the side wall of the right side of the L-shaped plate 11, a same steel rope 15 is wound between the fixed pulley 14 and the wire twisting wheel 13, a pull ring 16 is fixedly connected to the side wall of the upper side of a pouring box 7, one end of the steel rope 15 is fixedly connected with the pull ring 16, quantitative raw materials are guided into the pouring box 7 through a scale 10, a driving motor 2 is controlled to rotate, the driving motor 2 drives a threaded rod 3 to rotate, two moving plates 4 are moved rightwards through threaded fit between the threaded rod 3 and a threaded hole 5, the two moving plates 4 drive a transverse plate 6 to move, the transverse plate 6 drives the pouring box 7 to move rightwards, when the pouring box 7 reaches a pouring position, the, the steel rope 15 pulls the pouring box 7, so that the pouring box 7 rotates by fixing the axis of the fixing shaft 9, the pouring box 7 is inclined, raw materials in the pouring box 7 are poured out for pouring, the pouring system can pour automatically, the pouring operation safety is effectively improved, the labor intensity is low, and the pouring efficiency is improved.

Mounting groove 17 has been seted up to the lateral wall of diaphragm 6 upside, and the first magnetite 18 of fixedly connected with in the mounting groove 17 of telling, the left outer wall fixedly connected with second magnetite 19 of pouring box 7, the polarity of the relative one side of first magnetite 18 and second magnetite 19 is opposite, and first magnetite 18 and second magnetite 19 mutually support, can end pouring box 7 fix, rock when avoiding pouring box 7 to remove.

Lateral wall fixedly connected with backup pad 20 of 1 upside of bottom plate, dead eye 21 has been seted up to the lateral wall on backup pad 20 right side, and the pore wall of dead eye 21 passes through the bearing and is connected with 3 rotations of threaded rod, and lateral wall fixedly connected with gag lever post 22 on backup pad 20 right side, spacing hole 23 has all been seted up to the left lateral wall of two movable plates 4, and gag lever post 22 runs through movable plate 4 through spacing hole 23, and gag lever post 22 can carry on spacingly to movable plate 4, avoids movable plate 4 to follow 3 rotations of threaded rod.

Two mounting panels 24 of the equal fixedly connected with of lateral wall of two movable plate 4 downside, fixedly connected with pivot 25 between two mounting panels 24, the movable sleeve is equipped with gyro wheel 26 outside pivot 25, and gyro wheel 26 can support movable plate 4, reduces the pressure that threaded rod 3 bore.

The side wall fixedly connected with pouring nozzle 27 on pouring box 7 right side, pouring nozzle 27 can improve the smooth degree that raw materials flow out in pouring box 7.

Lateral wall fixedly connected with fixed plate 28 on diaphragm 6 right side, the lateral wall fixedly connected with supporting shoe 29 of fixed plate 28 upside, supporting shoe 29 can carry out spacing support to pouring box 7, avoids pouring box 7 excessively to rotate.

The bent part of the L-shaped plate 11 is fixedly connected with a reinforcing rod 30, and the reinforcing rod 30 can improve the structural strength of the L-shaped plate 11.

The right end of the limiting rod 22 is fixedly connected with a baffle 31, and the baffle 31 can prevent the moving plate 4 from being separated from the limiting rod 22.

The lateral wall fixedly connected with bearing frame 32 of bottom plate 1 upside, the lateral wall on bearing frame 32 right side has seted up changes hole 33, changes hole 33 and is connected through the pole wall rotation of ball bearing with threaded rod 3, and stability when bearing frame 32 can improve threaded rod 3 and rotate.

In the invention, a certain amount of raw materials are led into the pouring box 7 through the arranged graduated scale 10, the driving motor 2 is controlled to rotate, the driving motor 2 drives the threaded rod 3 to rotate, the two moving plates 4 move rightwards through the thread fit between the threaded rod 3 and the threaded hole 5, the two moving plates 4 drive the transverse plate 6 to move, the transverse plate 6 drives the pouring box 7 to move rightwards, when the pouring box 7 reaches the pouring position, the motor 12 is controlled to rotate, the motor 12 drives the wire twisting wheel 13 to rotate, the wire twisting wheel 13 winds the steel rope 15, the steel rope 15 pulls the pouring box 7, so that the pouring box 7 rotates by fixing the axis of the fixed shaft 9, thereby make pouring box 7 slope, make the raw materials in pouring box 7 pour out and pour, this gating system can pour into a mould automatically, the effectual security that improves the pouring operation, and intensity of labour is lower, has improved pouring efficiency.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.

Claims

1. The quantitative pouring system for the wear-resistant macromolecule wheels comprises a bottom plate (1) and is characterized in that a driving motor (2) is fixedly connected to the side wall of the upper side of the bottom plate (1), a threaded rod (3) is fixedly connected to an output shaft of the driving motor (2), two movable plates (4) are sleeved on a rod wall thread of the threaded rod (3), threaded holes (5) are formed in the left side wall of each movable plate (4), the threaded rod (3) penetrates through the movable plates (4) through the threaded holes (5), the side walls of the upper sides of the two movable plates (4) are fixedly connected with a transverse plate (6), a pouring box (7) is arranged on the side wall of the upper side of the transverse plate (6), a rotating plate (8) is fixedly connected to the outer wall of the right side of the pouring box (7), and a, the through-hole has been seted up to the lateral wall of rotor plate (8) front side, rotor plate (8) are run through the through-hole to fixed axle (9), pouring box (7) left inner wall fixedly connected with scale (10), lateral wall fixedly connected with L template (11) of diaphragm (6) upside, lateral wall fixedly connected with motor (12) of L template (11) upside, the outer fixed cover of output shaft of motor (12) is equipped with capstan wheel (13), lateral wall fixedly connected with fixed pulley (14) on L template (11) right side, around being equipped with same root steel cable (15) between fixed pulley (14) and capstan wheel (13), the lateral wall fixedly connected with pull ring (16) of pouring box (7) upside, the one end and pull ring (16) fixed connection of steel cable (15).

2. The quantitative pouring system for the high-molecular wear-resistant wheel according to claim 1, wherein an installation groove (17) is formed in the side wall of the upper side of the transverse plate (6), a first magnet (18) is fixedly connected in the installation groove (17), a second magnet (19) is fixedly connected to the outer wall of the left side of the pouring box (7), and the polarities of the opposite sides of the first magnet (18) and the second magnet (19) are opposite.

3. The quantitative pouring system for the wear-resistant polymer wheels, according to claim 1, is characterized in that a supporting plate (20) is fixedly connected to a side wall of an upper side of the bottom plate (1), a bearing hole (21) is formed in a side wall of a right side of the supporting plate (20), a hole wall of the bearing hole (21) is rotatably connected with the threaded rod (3) through a bearing, a limiting rod (22) is fixedly connected to a side wall of a right side of the supporting plate (20), limiting holes (23) are formed in side walls of left sides of the two movable plates (4), and the limiting rod (22) penetrates through the movable plates (4) through the limiting holes (23).

4. The quantitative pouring system for the wear-resistant polymer wheels according to claim 1, wherein two mounting plates (24) are fixedly connected to the side walls of the lower sides of the two moving plates (4), a rotating shaft (25) is fixedly connected between the two mounting plates (24), and a roller (26) is movably sleeved outside the rotating shaft (25).

5. The quantitative pouring system for the high-molecular wear-resistant wheel according to claim 1, wherein a pouring nozzle (27) is fixedly connected to the side wall of the right side of the pouring box (7).

6. The quantitative pouring system for the wear-resistant polymer wheels, according to claim 1, is characterized in that a fixing plate (28) is fixedly connected to the side wall of the right side of the transverse plate (6), and a supporting block (29) is fixedly connected to the side wall of the upper side of the fixing plate (28).

7. The quantitative pouring system for the high-molecular wear-resistant wheel according to claim 1, wherein a reinforcing rod (30) is fixedly connected to the bent part of the L-shaped plate (11).

8. The quantitative pouring system for the high-molecular wear-resistant wheel according to claim 3, wherein a baffle (31) is fixedly connected to the right end of the limiting rod (22).

9. The quantitative pouring system for the high-molecular wear-resistant wheel according to claim 1, wherein a bearing seat (32) is fixedly connected to the side wall of the upper side of the bottom plate (1), a rotating hole (33) is formed in the side wall of the right side of the bearing seat (32), and the rotating hole (33) is rotatably connected with the rod wall of the threaded rod (3) through a ball bearing.