CN114160265A

CN114160265A - Soil mud screening mechanism for porcelain insulator production

Info

Publication number: CN114160265A
Application number: CN202111468620.4A
Authority: CN
Inventors: 刘云华; 王金云; 肖红安; 赖德龙
Original assignee: Pingxiang Xuhua Electric Porcelain Manufacturing Co ltd
Current assignee: Pingxiang Xuhua Electric Porcelain Manufacturing Co ltd
Priority date: 2021-12-03
Filing date: 2021-12-03
Publication date: 2022-03-11

Abstract

The invention relates to the technical field of insulator production, and discloses a soil and mud screening mechanism for producing a porcelain insulator, which solves the problem that clay and mud are adhered to each other to cause slow clay preparation speed; in the invention, in operation, the rotation of the arranged rotary drum drives the crushing rod to rotate, and the third bevel gear at one end of the crushing rod is meshed with the first bevel gear and the second bevel gear on the fixed rod, so that the crushing rod rotates automatically after rotating around the rotary drum, thereby crushing the soil at the top ends of the first filter plate and the second filter plate and improving the screening efficiency.

Description

Soil mud screening mechanism for porcelain insulator production

Technical Field

The invention belongs to the technical field of insulator production, and particularly relates to a soil and mud screening mechanism for producing porcelain insulators.

Background

The pollution flashover accident of the insulator for the electrified contact network can cause the oscillation of a plurality of traction power supply systems, so that the power grid is collapsed, and serious accidents such as large-area power failure, railway operation interruption, outage and the like are caused. With the rapid development of the construction of the electrified railway, the solution of the pollution flashover problem of the contact net insulator is increasingly important. Through rationally selecting for use porcelain insulator material, improve the insulator structure, can improve the whole level of antifouling sudden strain of a muscle of contact net, among all kinds of insulators, porcelain insulator uses most generally, and porcelain insulator spare is the insulator of making by electrical ceramics, and wherein electrical ceramics is baked by quartz, feldspar and clay as the raw materials and forms. The surface of the porcelain piece of the porcelain insulator is usually covered with porcelain glaze to improve the mechanical strength, prevent water infiltration and increase the surface smoothness. In the production process of the insulator, clay is required to be used as a raw material.

In the process of preparing the clay, the clay soil has large moisture content, so that the clay soil and the clay are adhered to each other, the separation effect is poor, the clay preparation speed is slow, and the production efficiency of the porcelain insulator is reduced.

Disclosure of Invention

Aiming at the situation, in order to overcome the defects of the prior art, the invention provides the soil and mud screening mechanism for producing the porcelain insulator, and the problem that clay preparation speed is low due to mutual adhesion of clay and soil is effectively solved.

In order to achieve the purpose, the invention provides the following technical scheme: the utility model provides a soil mud divides sieve mechanism for porcelain insulator production, includes the organism, the supporting leg is installed to angle such as the bottom of organism, and a bottom section of thick bamboo is installed to the bottom of organism, and the discharging pipe is installed to the bottom of a bottom section of thick bamboo, and the feed inlet is installed on the top of organism, and filter component is installed to the inner wall of organism, and the internally mounted of organism shakes and beats the subassembly, and the internally mounted of organism smashes the subassembly.

Preferably, the filter assembly includes the mounting groove of seting up on the organism inner wall, and the internally mounted of mounting groove has the fixed plate, and the top spring is installed to angle such as the top of fixed plate, and first filter is installed on the top of top spring, and first filtration hole has been seted up to angle such as the top of first filter, and the bottom spring is installed to angle such as the bottom of fixed plate, and the second filter is installed to the bottom of bottom spring, and the second filtration hole has been seted up to angle such as the bottom of second filter.

Preferably, the aperture of the first filtering hole is larger than that of the second filtering hole, and the outer wall of the first filtering plate is attached to the inner wall of the machine body.

Preferably, the subassembly of shaking includes the rotary trough that the equidistance was seted up on the fixed plate inner wall, and the inside grafting of rotary trough has the bull stick, and the bilateral symmetry of bull stick installs the horizontal pole, and the one end of horizontal pole is installed and is shaken the head, and the limiting plate is installed to the one end of bull stick, and the balancing weight is installed to the bottom of bull stick, and the inside rotation of fixed plate is connected with the swivel, and the push pedal is installed to the equidistance such as the inner wall of swivel, and the push pedal is leveled mutually with the top of balancing weight.

Preferably, the outer wall of the swivel is equiangularly provided with a tooth socket, one side of the fixed plate is provided with a communicating groove, one side of the tooth socket is connected with an output gear of the first motor through the communicating groove in a meshing manner, and the communicating groove is fixedly connected with the inner wall of the machine body.

Preferably, smash the subassembly including installing in the commentaries on classics board of feed inlet bottom, the connecting rod is installed to the angle such as the outside of changeing the board, the one end and the organism fixed connection of connecting rod, and fixed case is installed on the top of connecting rod, and the tip cone is installed on the top of fixed case, and driven unit is installed to the bottom of connecting rod.

Preferably, the driven unit is including rotating the ring gear of connecting on fixed incasement wall, and the rotary drum is installed to the bottom of ring gear, and one side meshing of ring gear is connected with the second motor, and the inner wall fixed connection of second motor and fixed case, the through-hole has been seted up to the outer wall equidistance and the symmetry of rotary drum, and the inside grafting of through-hole has the pole of smashing, and the outer wall equidistance of pole of smashing just waits the angle to install and smashes the awl, smashes the pole and is located first filter top and second filter top respectively.

Preferably, the outer wall of the rotating drum is provided with rotating plates at equal angles, the two sides of each rotating plate are symmetrically provided with impact blocks at equal intervals, and the rotating drum is internally provided with a driving unit.

Preferably, the driving unit comprises a fixing rod inserted into the rotary drum, the top end of the fixing rod is fixedly connected with the inner top wall of the fixing box, a first helical gear is installed at the bottom end of the fixing rod, a connecting rod is installed at the bottom end of the connecting rod, a bottom rod is installed at the bottom end of the connecting rod, a second helical gear is installed at the bottom end of the bottom rod, third helical gears are symmetrically meshed with the two sides of the first helical gear and the two sides of the second helical gear, and the third helical gears are fixed at one end of the smashing rod.

Compared with the prior art, the invention has the beneficial effects that:

1) in the work, the crushing rod is driven to rotate through the rotation of the arranged rotary drum, and the third bevel gear at one end of the crushing rod is meshed with the first bevel gear and the second bevel gear on the fixed rod, so that the crushing rod rotates automatically after rotating around the rotary drum, soil at the top ends of the first filter plate and the second filter plate is crushed, and the screening efficiency is improved;

2) in operation, the balance weight block is pushed to move through the arranged push plate, the rotating rod is rotatably connected with the rotating groove, so that the balance weight block drives the transverse rod to rotate after moving, the transverse rod is inclined, the vibrating heads on two sides move towards two sides, then the first filter plate and the second filter plate are knocked, the first filter plate and the second filter plate vibrate, then the screening speed is increased, the screening efficiency is increased, the aperture of the first filter hole is larger than that of the second filter hole, grading screening is performed, and the screening efficiency and the crushing efficiency are further increased;

3) in operation, the rotary drum through setting up drives the commentaries on classics board and rotates, and changes the both sides of board and install the striking piece, after the mud is poured into in feed inlet department, the in-process that falls is being fallen to the mud this moment for the striking piece is at the removal in-process, collides with the mud of whereabouts, thereby carries out the breakage in advance to mud, thereby improves crushing efficiency.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention.

In the drawings:

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic view of a fixing plate according to the present invention;

FIG. 3 is a schematic view of the internal structure of the fixing plate according to the present invention;

FIG. 4 is a schematic view of the breaking assembly of the present invention;

FIG. 5 is a schematic structural diagram of a driven unit according to the present invention;

fig. 6 is a schematic structural diagram of an active cell according to the present invention.

In the figure: 1. a body; 2. supporting legs; 3. a feed inlet; 4. a bottom cylinder; 5. a discharge pipe; 6. a filter assembly; 601. a fixing plate; 602. a top spring; 603. a first filter plate; 604. a first filtering hole; 605. a bottom spring; 606. a second filter plate; 607. a second filtering hole; 608. mounting grooves; 7. a rapping assembly; 701. rotating the groove; 702. a rotating rod; 703. a cross bar; 704. a limiting plate; 705. vibrating the head; 706. a balancing weight; 707. rotating the ring; 708. a tooth socket; 709. pushing the plate; 710. a communicating groove; 711. a first motor; 8. a breaking up assembly; 801. rotating the plate; 802. a connecting rod; 803. an active unit; 8031. fixing the rod; 8032. a first helical gear; 8033. a connecting rod; 8034. a bottom bar; 8035. a second helical gear; 8036. a third bevel gear; 804. a driven unit; 8041. a rotating drum; 8042. a toothed ring; 8043. a second motor; 8044. rotating the plate; 8045. an impact block; 8046. a through hole; 8047. breaking the stems; 8048. breaking the cone; 805. a fixed box; 806. and (4) carrying out tip cone.

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.

In the first embodiment, as shown in fig. 1-6, the invention comprises a machine body 1, supporting legs 2 are arranged at the bottom end of the machine body 1 at equal angles, a bottom barrel 4 is arranged at the bottom end of the machine body 1, a discharging pipe 5 is arranged at the bottom end of the bottom barrel 4, a feeding hole 3 is arranged at the top end of the machine body 1, a filtering component 6 is arranged on the inner wall of the machine body 1, a rapping component 7 is arranged inside the machine body 1, and a smashing component 8 is arranged inside the machine body 1.

In the second embodiment, on the basis of the first embodiment, the filter assembly 6 includes a mounting groove 608 formed on the inner wall of the machine body 1, a fixing plate 601 is mounted inside the mounting groove 608, a top spring 602 is mounted on the top end of the fixing plate 601 at an equal angle, a first filter plate 603 is mounted on the top end of the top spring 602, a first filter hole 604 is formed on the top end of the first filter plate 603 at an equal angle, a bottom spring 605 is mounted on the bottom end of the fixing plate 601 at an equal angle, a second filter plate 606 is mounted on the bottom end of the bottom spring 605, and a second filter hole 607 is formed on the bottom end of the second filter plate 606 at an equal angle. The aperture of the first filtering hole 604 is larger than that of the second filtering hole 607, and the outer wall of the first filtering plate 603 is attached to the inner wall of the housing 1.

In the third embodiment, on the basis of the second embodiment, the rapping assembly 7 comprises a rotary groove 701 formed in the inner wall of a fixed plate 601 at equal angles, a rotary rod 702 is inserted into the rotary groove 701, cross rods 703 are symmetrically arranged on two sides of the rotary rod 702, a vibrating head 705 is arranged at one end of each cross rod 703, a limiting plate 704 is arranged at one end of each rotary rod 702, a balancing weight 706 is arranged at the bottom end of each rotary rod 702, a rotary ring 707 is rotatably connected to the inner part of the fixed plate 601, a push plate 709 is arranged in the inner wall of the rotary ring 707 at equal angles, the push plate 709 is flush with the top end of the balancing weight 706, a tooth groove 708 is formed in the outer wall of the rotary ring 707 at equal angles, a communicating groove 710 is formed in one side of the fixed plate 601, an output gear of a first motor 711 is engaged with the communicating groove 710, and the communicating groove 710 is fixedly connected with the inner wall of the machine body 1;

open first motor 711, the output gear of first motor 711 drives swivel 707 and rotates, thereby make swivel 707 rotate the back, make push pedal 709 promote balancing weight 706 and remove, and bull stick 702 rotates with rotary trough 701 and is connected, thereby make balancing weight 706 remove after drive horizontal pole 703 and rotate, thereby make behind the slope of horizontal pole 703, make the rapping head 705 of both sides remove towards both sides, then strike first filter 603 and second filter 606, thereby make first filter 603 and second filter 606 produce vibrations, then improve screening speed, and then improve screening efficiency, and the aperture of first filtration hole 604 is greater than the aperture of second filtration hole 607, thereby carry out hierarchical screening, further improve screening efficiency and crushing efficiency.

In the fourth embodiment, on the basis of the third embodiment, the breaking assembly 8 includes a rotating plate 801 installed at the bottom end of the feeding port 3, a connecting rod 802 is installed at the outer side of the rotating plate 801 at an equal angle, one end of the connecting rod 802 is fixedly connected with the machine body 1, a fixing box 805 is installed at the top end of the connecting rod 802, a tip cone 806 is installed at the top end of the fixing box 805, a driven unit 804 is installed at the bottom end of the connecting rod 802, the driven unit 804 includes a toothed ring 8042 rotatably connected to the inner wall of the fixing box 805, a rotating drum 8041 is installed at the bottom end of the toothed ring 8042, a second motor 8043 is engaged and connected to one side of the toothed ring 8042, the second motor 8043 is fixedly connected to the inner wall of the fixing box 805, through holes 8046 are equidistantly and symmetrically formed in the outer wall of the rotating drum 8041, a breaking rod 8047 is inserted into the through holes 8046, breaking rods 8048 are equidistantly and angularly installed on the outer wall of the breaking rod 8047, and the breaking rods 8047 are respectively located above the first filter plate 603 and above the second filter plate 606. A rotating plate 8044 is arranged on the outer wall of the rotating drum 8041 at an equal angle, impact blocks 8045 are symmetrically arranged on two sides of the rotating plate 8044 at equal intervals, and a driving unit 803 is arranged in the rotating drum 8041;

the driving unit 803 comprises a fixed rod 8031 inserted into the drum 8041, the top end of the fixed rod 8031 is fixedly connected with the inner top wall of the fixed box 805, the bottom end of the fixed rod 8031 is provided with a first bevel gear 8032, the bottom end of the connecting rod 8033 is provided with a connecting rod 8033, the bottom end of the connecting rod 8033 is provided with a bottom rod 8034, the bottom end of the bottom rod 8034 is provided with a second bevel gear 8035, both sides of the first bevel gear 8032 and both sides of the second bevel gear 8035 are symmetrically engaged with third bevel gears 8036, and the third bevel gears 8036 are fixed at one end of the breaking rod 8047;

firstly, soil is poured into the machine body 1 from the feeding hole 3, then the second motor 8043 is started, so that the output gear of the second motor 8043 drives the toothed ring 8042 to rotate, so that the rotary drum 8041 rotates, the fixed rod 8031 is fixedly installed with the fixed box 805, so that the rotary drum 8041 rotates to drive the crushing rod 8047 to rotate, the third bevel gear 8036 at one end of the crushing rod 8047 is meshed and connected with the first bevel gear 8032 and the second bevel gear 8035 on the fixed rod 8031, so that after the crushing rod 8047 rotates around the rotary drum 8041, the crushing rod 8047 rotates automatically, so that the soil at the top ends of the first filter plate 603 and the second filter plate 606 is crushed, and the screening efficiency is improved;

after the rotating drum 8041 rotates, the rotating drum 8041 drives the rotating plate 8044 to rotate, the impact blocks 8045 are installed on two sides of the rotating plate 8044, and after soil is poured into the feeding hole 3, the soil collides with the falling soil in the moving process of the impact blocks 8045 in the falling process, so that the soil is pre-crushed, and the crushing efficiency is improved.

Claims

1. The utility model provides a soil mud divides sieve mechanism for porcelain insulator production, includes organism (1), its characterized in that: supporting legs (2) are installed to the bottom of organism (1) equidistance, and end section of thick bamboo (4) are installed to the bottom of organism (1), and discharging pipe (5) are installed to the bottom of end section of thick bamboo (4), and feed inlet (3) are installed on the top of organism (1), and filtering component (6) are installed to the inner wall of organism (1), and the internally mounted of organism (1) shakes and beats subassembly (7), and the internally mounted of organism (1) smashes subassembly (8).

2. The soil mud screening mechanism for porcelain insulator production according to claim 1, wherein the soil mud screening mechanism comprises: filter element (6) including offering mounting groove (608) on organism (1) inner wall, the internally mounted of mounting groove (608) has fixed plate (601), angle such as top of fixed plate (601) installs top spring (602), first filter (603) are installed on the top of top spring (602), first filtration hole (604) have been seted up to angle such as the top of first filter (603), angle such as the bottom of fixed plate (601) installs bottom spring (605), second filter (606) are installed to the bottom of bottom spring (605), second filtration hole (607) have been seted up to angle such as the bottom of second filter (606).

3. The soil mud screening mechanism for porcelain insulator production according to claim 2, wherein: the aperture of the first filtering hole (604) is larger than that of the second filtering hole (607), and the outer wall of the first filtering plate (603) is attached to the inner wall of the machine body (1).

4. The soil mud screening mechanism for porcelain insulator production according to claim 1, wherein the soil mud screening mechanism comprises: the rapping assembly (7) comprises a rotary groove (701) formed in the inner wall of a fixing plate (601) at an equal angle, a rotary rod (702) is inserted into the rotary groove (701), transverse rods (703) are symmetrically arranged on two sides of the rotary rod (702), a vibrating head (705) is arranged at one end of each transverse rod (703), a limiting plate (704) is arranged at one end of the rotary rod (702), a balancing weight (706) is arranged at the bottom end of the rotary rod (702), a rotary ring (707) is connected to the inner rotation of the fixing plate (601), a push plate (709) is arranged at an equal angle on the inner wall of the rotary ring (707), and the push plate (709) is level with the top end of the balancing weight (706).

5. The soil mud screening mechanism for porcelain insulator production according to claim 4, wherein: tooth spaces (708) are formed in the outer wall of the rotating ring (707) at equal angles, a communicating groove (710) is formed in one side of the fixing plate (601), an output gear of a first motor (711) is connected to one side of each tooth space (708) in a meshed mode through the communicating groove (710), and the communicating groove (710) is fixedly connected with the inner wall of the machine body (1).

6. The soil mud screening mechanism for porcelain insulator production according to claim 1, wherein the soil mud screening mechanism comprises: smash subassembly (8) including installing in commentaries on classics board (801) of feed inlet (3) bottom, the outside of changeing board (801) is waited the angle and is installed connecting rod (802), the one end and organism (1) fixed connection of connecting rod (802), and fixed case (805) are installed on the top of connecting rod (802), and apex cone (806) are installed on the top of fixed case (805), and driven unit (804) are installed to the bottom of connecting rod (802).

7. The soil mud screening mechanism for porcelain insulator production according to claim 6, wherein: driven unit (804) are including rotating ring gear (8042) of connecting on fixed case (805) inner wall, rotary drum (8041) are installed to the bottom of ring gear (8042), one side meshing of ring gear (8042) is connected with second motor (8043), the inner wall fixed connection of second motor (8043) and fixed case (805), through-hole (8046) have been seted up to the outer wall equidistance and the symmetry of rotary drum (8041), the inside grafting of through-hole (8046) has smashing pole (8047), smash the outer wall equidistance of pole (8047) and equal angle install and smash awl (8048), it is located first filter (603) top and second filter (606) top respectively to smash pole (8047).

8. The soil mud screening mechanism for porcelain insulator production according to claim 7, wherein: the outer wall of the rotating drum (8041) is provided with a rotating plate (8044) at an equal angle, the two sides of the rotating plate (8044) are symmetrically and equidistantly provided with impact blocks (8045), and the rotating drum (8041) is internally provided with a driving unit (803).

9. The soil mud screening mechanism for porcelain insulator production according to claim 8, wherein: the driving unit (803) comprises a fixing rod (8031) inserted into the rotary drum (8041), the top end of the fixing rod (8031) is fixedly connected with the inner top wall of the fixing box (805), a first helical gear (8032) is installed at the bottom end of the fixing rod (8031), a connecting rod (8033) is installed at the bottom end of the connecting rod (8033), a bottom rod (8034) is installed at the bottom end of the connecting rod (8033), a second helical gear (8035) is installed at the bottom end of the bottom rod (8034), the two sides of the first helical gear (8032) and the two sides of the second helical gear (8035) are symmetrically meshed with a third helical gear (8036), and the third helical gear (8036) is fixed at one end of a crushing rod (8047).