CN211664273U - Galvanized part collecting hopper convenient to divide material - Google Patents

Abstract

The utility model relates to a zinc-plated part is collected and is fought convenient to divide material, establish the frame under the hopper including the hopper and the mount of collecting zinc-plated part, hopper one side opening forms the material collection mouth, be separated into the district of gathering materials and waste material district along its width direction on the hopper, the waste material mouth in intercommunication waste material district is seted up to the hopper lateral wall, the hopper is kept away from opening one side and is installed the screen hopper and drive screen hopper along the drive assembly that hopper width direction removed, the bottom of screen hopper is by keeping away from material collection mouth one side to being close to the slope of a side of gathering materials downwards, drive assembly includes along hopper width direction setting and threaded connection in the screw group of screen hopper and be used for driving the motor group of screen hopper motion, screw group both ends rotate respectively and connect in the hopper lateral. The utility model discloses have the effect of being convenient for divide the material.

Description

Galvanized part collecting hopper convenient to divide material

Technical Field

The utility model relates to a collect the mechanism, especially relate to a galvanized component is collected and is fought convenient to divide material.

Background

Galvanization refers to a surface treatment technology for plating a layer of zinc on the surface of metal, alloy or other materials to play the roles of beauty, rust prevention and the like. The general flow of the galvanization comprises the steps of washing, pickling, washing, drying and preheating, hot galvanizing, cooling, passivating, rinsing, drying and inspecting.

Chinese patent publication No. CN209651441U discloses a collection mechanism of galvanized component, including the support and set up the collection fill on the support, it includes the collecting board to collect the fill, collecting board edge department is provided with the turn-ups, turn-ups one department is provided with the delivery outlet, the one end that the collecting board is close to the delivery outlet is connected with the support rotation, the one end that the delivery outlet was kept away from to the support is connected with actuating mechanism, actuating mechanism drive is collected and is fought around rotating with the leg joint. The galvanized part is emptyd in the collecting vat after the stoving dehydration finishes, to the galvanized part that needs detect the galvanizing condition, then spreads out the galvanized part in collecting the fill, detects.

The above prior art solutions have the following drawbacks: in the galvanizing process, fine particles are generated on the surfaces of a few workpieces, and workers need to carefully check the fine particles to separate the fine particles during inspection, so that the inspection efficiency is low.

SUMMERY OF THE UTILITY MODEL

To the not enough that prior art exists, one of the purposes of the utility model is to provide a zinc-plated part collection fill convenient to divide material.

The above utility model discloses an above-mentioned utility model purpose can realize through following technical scheme: the utility model provides a zinc-plated part is collected and is fought convenient to divide material, establishes the frame under the hopper including the hopper and the mount of collecting zinc-plated part, hopper one side opening forms the material collection mouth, be separated into aggregate region and waste material district along its width direction on the hopper, the waste material mouth in intercommunication waste material district is seted up to the hopper lateral wall, the hopper is kept away from opening one side and is installed the screen hopper and drive the screen hopper along the drive assembly that hopper width direction removed, the bottom that the screen hopper was fought is by keeping away from aggregate mouth one side to being close to aggregate mouth lopsidedness downwards, drive assembly includes that the lead screw group who sets up and threaded connection in the screen hopper along hopper width direction and be used for driving the motor group of screen hopper motion, lead screw group both ends rotate respectively.

Through adopting above-mentioned technical scheme, during the feeding, the galvanized component is poured into the upwards one side of sieve fill slope earlier, and tiny powder in the galvanized component is at first separated to the waste material mouth by the sieve fill then discharges. The friction between the galvanized part with fine particles on the surface and the sieve bucket is large, the galvanized part with smooth surface firstly slides to the bottom of the side of the sieve bucket which inclines downwards, and most of the galvanized part with particles on the surface is left on the side which inclines upwards, so that the galvanized part is easily separated out, and the inspection efficiency is improved.

The present invention may be further configured in a preferred embodiment as: the side wall of the sieve hopper is abutted to the side wall of the hopper far away from the material collecting port, and the sieve hopper is connected to the hopper in a sliding manner.

By adopting the technical scheme, when the position of the sieve hopper is adjusted, the click group controls the screw rod group to synchronously rotate, and the sieve hopper is easy to incline or shake due to the consistent rotating direction of the screw rod group. When the sieve was fought butt hopper lateral wall, the sieve was fought and only can be followed lead screw length direction and removed, and other displacements are all spacing, have improved stability.

The present invention may be further configured in a preferred embodiment as: the screw rod group comprises two reciprocating screw rods arranged at intervals.

Through adopting above-mentioned technical scheme, after using reciprocal lead screw, for ordinary lead screw, the pivot of motor assembly tip only needs to last unidirectional rotation can reach the mesh of sieve fill motion. The motor unit is less worn by the multifilament bar.

The present invention may be further configured in a preferred embodiment as: the sieve fill includes the bucket body and follows vertical direction sliding connection in the door plant of bucket body.

Through adopting above-mentioned technical scheme, set up mobilizable door plant on bucket body one side, the galvanized component inspection back that finishes, removes the door plant to the open mode. Because the door plant is installed in the downward one side of sieve fill slope, in the galvanized component falls to the district that gathers materials from this end, is collected from the mouth that gathers materials again, has improved separation efficiency.

The present invention may be further configured in a preferred embodiment as: the side wall of one side of the hopper body, which is close to the material collecting opening, is rotatably connected with a rocker, one end of the rocker, which is far away from the connecting hopper body, is rotatably connected with a crank which drives the door plate to move only along the vertical direction, and one end of the crank, which is far away from the rocker, is rotatably connected to the side wall of the door plate.

Through adopting above-mentioned technical scheme, when exerting the power of circumference to the rocker, the rocker rotates the door plant that drives crank tip and slides along vertical direction, reaches the purpose that the control door plant opened and shut, and easy operation is very convenient.

The present invention may be further configured in a preferred embodiment as: : the position of the crank connecting rocker is fixedly connected with a force application rod.

Through adopting above-mentioned technical scheme, set up the application of force pole at crank and rocker hookup location, can drive the rocker rotation to the application of force pole application of force, provide very big convenience for the user.

The present invention may be further configured in a preferred embodiment as: the door plant both sides all rotate and are connected with the pulley, the mounting groove has been seted up to bucket body butt door plant one side, the pulley inlays to be established in the mounting groove and follows vertical direction sliding connection in mounting groove.

Through adopting above-mentioned technical scheme, door plant is along vertical direction sliding connection in the bucket body, behind the installation pulley, is roll connection between door plant and the bucket body. Compared with a sliding connection, the friction force of the rolling connection is smaller, and the loss between the door plate and the bucket body is smaller.

The present invention may be further configured in a preferred embodiment as: collecting baskets are arranged below the material collecting port and the waste material port.

Through adopting above-mentioned technical scheme, set up collection basket at the mouth that gathers materials and waste material mouth lower extreme, the galvanized component is collected in two collection baskets respectively after being separated, provides very big facility for the operator.

To sum up, the utility model discloses a following at least one useful technological effect:

1. most galvanized parts with particles on the surfaces are left on the side which inclines upwards, so that the galvanized parts are easily separated, and the inspection efficiency is improved.

2. A movable door plate is arranged on one side of the hopper body, so that the separation efficiency is improved.

3. The rocker and the crank are arranged, the purpose of controlling the opening and closing of the door panel is achieved, and the operation is simple and very convenient.

Drawings

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

FIG. 2 is a schematic view of the connection between the screen bucket and the lead screw set;

FIG. 3 is a schematic view of the construction of the sieve hopper;

fig. 4 is an enlarged view of fig. 3 at a.

In the figure, 10, the hopper; 11. a frame; 12. a material collection area; 13. a waste zone; 14. a material collecting port; 15. a waste material port; 16. a collection basket; 20. a drive assembly; 21. a screw rod group; 23. a motor unit; 24. an insert block; 25. a thread groove; 30. a screen bucket; 301. a door panel; 302. a bucket body; 32. mounting grooves; 321. a first groove; 322. a second groove; 33. a pulley; 34. screening holes; 40. a first mounting seat; 41. 4, a rocker; 42. a crank; 43. a second mounting seat; 44. a force application rod.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

Referring to fig. 1, for the utility model discloses a zinc-plated part collection hopper convenient to divide material, establish frame 11 under hopper 10 including hopper 10 and mount. Hopper 10 open end is separated into collecting box 12 and waste material district 13 along its width direction, and collecting port 14 and waste material mouth 15 have been seted up respectively to hopper 10 at collecting box 12 and waste material district 13 one side lateral wall, and collecting port 14 and waste material mouth 15 all communicate the outside perisporium, and collecting basket 16 has been placed to collecting port 14 and waste material mouth 15 lower extreme. The hopper 10 is far away from the opening one side and is installed screen bucket 30 and drive screen bucket 30 along the drive assembly 20 of hopper 10 width direction removal, and a plurality of sieve meshes 34 have evenly been seted up to screen bucket 30 lower extreme, and screen bucket 30 bottom is by keeping away from the slope of collecting material mouth 14 one side to being close to collecting material mouth 14 one side downwards.

When feeding, the galvanized component is poured from the side of the sieve hopper 30 which is inclined upwards, and at the moment, the sieve hopper 30 is positioned in the waste material area 13. The galvanized part is subjected to gravity and falls to the lower end of the sieve hopper 30 in an inclined mode, and in the process, fine powder in the galvanized part is firstly separated to the waste material opening 15 by the sieve hopper 30 and then discharged. The driving assembly 20 drives the sieve bucket 30 to move into the material collecting area 12, friction between the galvanized part with fine particles on the surface and the sieve bucket 30 is large, the galvanized part with the smooth surface slides to the bottom of the inclined downward side of the sieve bucket 30 in the moving process, and most of the galvanized part with particles on the surface is left on the inclined upward side and is separated out easily. Good quality galvanized parts are collected from the collection basket 16 at the discharge opening 14.

Specifically, referring to fig. 2 and 3, the driving assembly 20 includes a wire rod set 21 disposed along the width direction of the hopper 10 and a motor set 23 for driving the movement of the sieve hopper 30. The screw group 21 includes two reciprocating screws spaced along the length direction of the screen bucket 30, and two ends of the two reciprocating screws are rotatably connected to the side wall of the hopper 10 through bearings, respectively. The two reciprocating screw rods penetrate through the screen bucket 30, the screen bucket 30 is abutted against one side of the reciprocating screw rods and provided with the embedded block 24, the embedded block 24 is embedded in the thread groove 25 of the reciprocating screw rods, and the embedded block 24 is connected to the inner wall of the thread groove 25 in a rolling mode.

The motor group 23 comprises two motors, the motors are fixedly connected to the outer side wall of the hopper 10, and rotating shafts at the end parts of the motors are fixedly connected to the screw rods. The side wall of the sieve bucket 30 is abutted against the inner wall of the hopper 10, and the sieve bucket 30 is connected to the inner wall of the hopper 10 in a sliding manner along the width direction of the hopper 10.

In the separation process, the motor unit 23 is started at the same time, the rotating shaft at the end part of the motor drives the reciprocating screw rod to rotate, the embedded block 24 rolls in the thread groove 25, and the sieve hopper 30 is driven to move towards one side of the material collecting area 12. When the sieve bucket 30 moves to the end of the reciprocating screw rod, the sieve bucket starts to move reversely until returning to the waste material area 13.

Specifically, referring to fig. 3 and 4, the sieve bucket 30 includes a bucket body 302 and a door plate 301 slidably connected to the bucket body 302 in a vertical direction. Door plant 301 both sides all rotate and are connected with pulley 33, and pulley 33 evenly is equipped with a plurality ofly along door plant 301 direction of height, and bucket body 302 butt door plant 301 one side has seted up mounting groove 32 along its direction of height. The mounting groove 32 comprises a first groove 321 communicated with the end faces of the upper end and the lower end of the bucket body 302 and a second groove 322 arranged on the inner wall of the first groove 321, and two sides of the door panel 301 are embedded in the first groove 321 and are connected with the first groove 321 in a sliding mode along the vertical direction. Each pulley 33 is embedded in the second groove 322 and is connected to the inner wall of the second groove 322 in a rolling manner.

Referring to fig. 1 and 3, the bucket body 302 is provided with a door panel 301, the outer side wall of which is fixedly provided with a first mounting seat 40, the side wall of the first mounting seat 40 is rotatably connected with a rocker 41, one end of the rocker 41 far away from and connected with the first mounting seat 40 is rotatably connected with a crank 42, the side wall of the door panel 301 far away from one side of the screw rod group 21 is fixedly connected with a second mounting seat 43, and one end of the crank 42 far away from the rocker 41 is rotatably connected with the second mounting seat 43. The crank 42 is connected with the rocker 41 and is fixedly connected with an applying rod 44, and the applying rod 44 and the crank 42 are in the same straight line.

After the galvanized parts with problems in the screening hopper 30 are screened out, the force is applied to the force application rod 44 to drive the rocker 41 and the crank 42 to rotate, the door plate 301 is lifted upwards, the pulley 33 slides in the second groove 322, the door plate 301 is in an open state, and the galvanized parts fall into the material collection area 12 from the open end to be collected.

The implementation principle of the embodiment is as follows: when feeding, the galvanized component is poured from the side of the sieve hopper 30 which is inclined upwards, and at the moment, the sieve hopper 30 is positioned in the waste material area 13. The galvanized part is subjected to gravity and falls to the lower end of the sieve hopper 30 in an inclined mode, and in the process, fine powder in the galvanized part is firstly separated to the waste material opening 15 by the sieve hopper 30 and then discharged.

In the separation process, the motor unit 23 is started at the same time, the rotating shaft at the end part of the motor drives the reciprocating screw rod to rotate, the embedded block 24 rolls in the thread groove 25, and the sieve hopper 30 is driven to move towards one side of the material collecting area 12. The friction between the galvanized part with fine particles on the surface and the sieve hopper 30 is large, the galvanized part with smooth surface slides to the bottom of the inclined downward side of the sieve hopper 30 in the moving process, and most of the galvanized part with particles on the surface is left on the inclined upward side and is easy to separate.

After the galvanized parts with problems in the screening hopper 30 are screened out, the force is applied to the force application rod 44 to drive the rocker 41 and the crank 42 to rotate, the door plate 301 is lifted upwards, the pulley 33 slides in the second groove 322, the door plate 301 is in an open state, and the galvanized parts fall into the material collection area 12 from the open end to be collected.

The embodiment of this specific implementation mode is the preferred embodiment of the present invention, not limit according to this the utility model discloses a protection scope, so: all equivalent changes made according to the structure, shape and principle of the utility model are covered within the protection scope of the utility model.

Claims (8)

1. The utility model provides a hopper is collected to galvanized component convenient to divide material, establishes frame (11) under hopper (10) including hopper (10) and the mount of collecting galvanized component, hopper (10) one side opening forms material collection mouth (14), its characterized in that: divide into collection material district (12) and waste material district (13) along its width direction on hopper (10), waste material mouth (15) of intercommunication waste material district (13) are seted up to hopper (10) lateral wall, hopper (10) are kept away from opening one side and are installed screen hopper (30) and drive screen hopper (30) along drive assembly (20) that hopper (10) width direction removed, the bottom of screen hopper (30) is by keeping away from collection material mouth (14) one side to being close to collection material mouth (14) one side slope downwards, drive assembly (20) include along hopper (10) width direction setting and threaded connection in wire rod group (21) of screen hopper (30) and be used for driving motor group (23) of screen hopper (30) motion, wire rod group (21) both ends rotate respectively and connect in hopper (10) lateral wall.

2. The galvanized workpiece collecting hopper convenient for material distribution according to claim 1, characterized in that: the side wall of the sieve hopper (30) is abutted to the side wall of the hopper (10) far away from the material collecting port (14), and the sieve hopper (30) is connected to the hopper (10) in a sliding mode.

3. The galvanized workpiece collecting hopper convenient for material distribution according to claim 1, characterized in that: the screw rod group (21) comprises two reciprocating screw rods which are arranged at intervals.

4. The galvanized workpiece collecting hopper convenient for material distribution according to claim 1, characterized in that: the sieve bucket (30) comprises a bucket body (302) and a door plate (301) connected to the bucket body (302) in a sliding mode in the vertical direction.

5. The galvanized workpiece collecting hopper convenient to divide materials according to claim 4, characterized in that: the side wall of the hopper body (302) close to the material collecting port (14) is rotatably connected with a rocker (41), one end of the rocker (41) far away from the connecting hopper body (302) is rotatably connected with a crank (42) which drives the door plate (301) to move only along the vertical direction, and one end of the crank (42) far away from the rocker (41) is rotatably connected with the side wall of the door plate (301).

6. The galvanized workpiece collecting hopper convenient to divide materials according to claim 5, characterized in that: the crank (42) is connected with the rocker (41) and is fixedly connected with a force application rod (44).

7. The galvanized workpiece collecting hopper convenient to divide materials according to claim 4, characterized in that: door plant (301) both sides all rotate and are connected with pulley (33), mounting groove (32) have been seted up to bucket body (302) butt door plant (301) one side, pulley (33) inlay and establish in mounting groove (32) and follow vertical direction sliding connection in mounting groove (32).

8. The galvanized workpiece collecting hopper convenient for material distribution according to claim 1, characterized in that: and collecting baskets (16) are arranged below the material collecting port (14) and the waste material port (15).

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