CN222552134U - A vibrating sand-falling machine - Google Patents

Abstract

A vibration sand-falling machine provided by an embodiment of the utility model relates to the technical field of sand-falling machines. The vibration sand-falling machine comprises a vibration component, a recovery box is provided on the lower side of the vibration component, a feed port opened on the upper side of the recovery box corresponds to a discharge port of the vibration component, discharge ports are opened on both sides of the recovery box, and an anti-accumulation component is slidably installed inside the recovery box, and the anti-accumulation component pushes the fallen sand in the recovery box to the outside of the two discharge ports through reciprocating movement. The utility model collects the fallen sand that falls from the inside of the outer shell due to vibration through the recovery box, and through the rotation of the screw rod, the connecting block moves with the hollow shell, and the hollow shell pushes the fallen sand entering the recovery box with the push plate, so that the fallen sand is discharged from the discharge ports on both sides of the recovery box, and the push of the push plate avoids the situation where the fallen sand cannot be discharged, and at the same time, the fallen sand is discharged to both sides of the outer shell, which is convenient for subsequent recycling.

Description

Vibration shakeout machine

Technical Field

The utility model relates to the technical field of shakeout machines, in particular to a vibration shakeout machine.

Background

The vibration shakeout machine is a device for vibrating the molding sand in a sand box through a vibrating motor and separating the molding sand from the sand box in a vibrating mode.

The Chinese patent application No. 202121602349.4 is a vibration shakeout machine, which comprises a frame, wherein a base is arranged at the top of the frame, a conical collecting piece is arranged in the base, a shakeout platform is arranged at the top of the base, a plurality of shakeout sieve holes are formed in the shakeout platform in a penetrating mode along the vertical direction, the shakeout sieve holes are communicated with the conical collecting piece, an output pipe is communicated with the output end of the conical collecting piece, a collecting box is arranged on the side wall, close to the output pipe, of the frame, a connecting rod is arranged on the side wall of the collecting box, and a connecting hole is formed in the frame in an inserting mode. The application has the effect of reducing pollution of the shakeout machine.

According to the technical scheme, in order to collect shakeout in the prior art, the collecting box is arranged at the bottom of the shakeout machine, although the collecting box can recycle the shakeout, the discharging hole of the collecting box is provided with the sealing structure, so that the shakeout is inconvenient to take out, meanwhile, the shakeout is inconvenient to completely discharge, a dead angle exists, the discharging holes of some existing shakeout machines are located under, the shakeout is discharged from the shakeout machine and falls on the ground below the shakeout machine, and the shakeout machine shields the shakeout, so that the shakeout is inconvenient to take out.

Disclosure of utility model

The utility model aims to provide a vibration shakeout machine, which can avoid the situations that shakeout is inconvenient to take out and dead angles exist in shakeout blanking during shakeout recovery.

The utility model provides a vibration shakeout machine, which comprises a vibration component, wherein a recovery box is arranged at the lower side of the vibration component, a feed inlet formed in the upper side of the recovery box corresponds to a discharge outlet of the vibration component, discharge outlets are formed in two sides of the recovery box, an anti-accumulation component is slidably arranged in the recovery box, and shakeout in the recovery box is pushed to the outer sides of the two discharge outlets through reciprocating movement by the anti-accumulation component.

In a specific embodiment, the anti-accumulation component comprises a connecting block, the upper end of the connecting block slides in a limiting groove formed in the upper side of the recovery box, the lower end of the connecting block is connected with one side of the hollow shell, and a pushing plate is movably arranged on the lower side of the hollow shell.

In a specific embodiment, the lower side of the hollow shell is rotatably provided with a rotating rod, and the rotating rod is fixedly connected with the upper side of the pushing plate.

In a specific embodiment, a first limit rod is arranged on one side of the hollow shell, and a second limit rod is arranged on the other side of the hollow shell.

In a specific embodiment, the inner walls of two sides of the hollow shell are provided with sliding grooves, a bearing plate is slidably arranged between the two sliding grooves, a plurality of anti-blocking rods are arranged on the upper side of the bearing plate, and the upper ends of the anti-blocking rods penetrate through the hollow shell and are slidably connected with the hollow shell.

In a specific embodiment, the lower side of the hollow shell is rotatably provided with a cam, and a rotating shaft of the cam is connected with an output shaft of the motor.

In a specific embodiment, the lower end of the chute is provided with a second elastic piece, and the upper end of the second elastic piece is connected with the bearing plate.

In a specific embodiment, the upper side of the recovery box is rotatably provided with a screw rod, the screw rod penetrates through the upper end of the connecting block and is in threaded connection with the connecting block, and one end of the screw rod is connected with an output shaft of the motor.

In a specific embodiment, the discharge openings on both sides of the recovery tank extend out of the housing.

In a specific embodiment, the vibration assembly comprises a supporting seat placed on the ground, an elastic piece I is arranged on the upper side of the supporting seat, the upper end of the elastic piece I is connected with the side wall of the shell, vibration motors are arranged on the side walls of the two sides of the shell, and a sieve plate is arranged in the shell.

Compared with the prior art, the vibration shakeout machine provided by the embodiment of the utility model has the advantages that:

1. according to the utility model, the shakeout falling off from the inner part of the shell due to vibration is collected through the recovery box, the connecting block moves along with the hollow shell through the rotation of the screw rod, the hollow shell pushes the shakeout entering the recovery box along with the pushing plate, the shakeout is discharged from the discharge ports on two sides of the recovery box, the situation that the shakeout cannot be removed is avoided through the pushing of the pushing plate, and meanwhile, the shakeout is discharged to two sides of the shell, so that the subsequent recovery is facilitated.

2. According to the utility model, the bearing plate is pushed by the rotation of the cam, so that the bearing plate moves up and down continuously with the anti-blocking rod, and the anti-blocking rod moves up and down in the discharge hole at the lower side of the shell in the moving process of the pushing plate, so that the effect of preventing shakeout from accumulating at the discharge hole of the shell is achieved.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present utility model, the drawings that are needed in the embodiments will be briefly described below, it being understood that the following drawings only illustrate some examples of the present utility model and therefore should not be considered as limiting the scope, and other related drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic diagram of the overall structure of an embodiment of the present utility model;

FIG. 2 is a side view of the overall structure of an embodiment of the present utility model;

FIG. 3 is a schematic view of a recycling bin according to an embodiment of the utility model;

FIG. 4 is a schematic cross-sectional view of a recycling bin structure according to an embodiment of the utility model;

FIG. 5 is a schematic cross-sectional view of an anti-accumulation assembly according to an embodiment of the utility model.

Icon:

1. a support base; 11, a first elastic part, 12, a shell, 13, a vibration motor, 14, a sieve plate, 2, a recovery box, 21, a discharge hole, 22, a feed inlet, 23, a limit groove, 3, a screw rod, 4, an anti-accumulation component, 41, a connecting block, 42, a hollow shell, 421, a rotating rod, 422, a first limit rod, 423, a second limit rod, 43, a sliding chute, 44, a second elastic part, 45, a bearing plate, 46, an anti-blocking rod, 47, a cam, 48 and a pushing plate.

Detailed Description

In order to collect the shakeout among the prior art, install the collecting box in the bottom of shakeout machine, although the collecting box can retrieve the shakeout, but there is seal structure in the discharge gate department of collecting box, consequently leads to the taking out of shakeout comparatively inconvenient while is inconvenient for the shakeout to be down completely, there is the unloading dead angle, and the bin outlet of current some shakeout machines is located under, the shakeout is followed the subaerial of shakeout machine discharge back whereabouts in the shakeout machine below, has the shakeout machine to shelter from the shakeout, is inconvenient for taking out the shakeout. Therefore, the study provides a vibration shakeout machine, when in use, the shakeout that drops because of the vibration inside the shell is collected through the recovery box, and through the rotation of lead screw, make the connecting block take the hollow shell to remove, the hollow shell is taking to push the knockout that pushes away the flitch to get into the recovery box, make the knockout discharge from the bin outlet of recovery box both sides, avoid the condition that the knockout can not get rid of through pushing away the promotion of flitch, simultaneously with the knockout discharge to the both sides of shell, make things convenient for follow-up recovery, thereby solve above-mentioned defect.

Some embodiments of the present utility model are described in detail below with reference to the accompanying drawings. The following embodiments and features of the embodiments may be combined with each other without conflict.

Referring to fig. 1 to 5, an embodiment of the present utility model provides a vibration shakeout machine, which includes a vibration assembly, and a recovery tank 2 is disposed at the lower side of the vibration assembly.

Specifically, vibration subassembly is including placing the supporting seat 1 on ground, and the upside of supporting seat 1 is equipped with elastic component one 11, and elastic component one 11 can preferentially adopt metal spring, and the upper end of elastic component one 11 links to each other with the lateral wall of shell 12, all installs vibrating motor 13 on the both sides lateral wall of shell 12, and the inside of shell 12 is equipped with sieve 14, places the material that will screen on sieve 14, starts vibrating motor 13, and vibrating motor 13 makes shell 12 and sieve 14 vibrate, makes the molding sand fall to the shell 12 bottom that is the toper structure.

Because feed inlet 22 that the collection box 2 upside was seted up corresponds with vibration assembly's discharge gate, the knockout gets into collection box 2 from shell 12 in, and bin outlet 21 has all been seted up to the both sides of collection box 2, and two bin outlets 21 carry out the reposition of redundant personnel with the knockout in the collection box 2 and discharge, and wherein, the bin outlet 21 of collection box 2 both sides extends shell 12, makes shell 12 not influence the recovery to the knockout.

As shown in fig. 4, an anti-accumulation assembly 4 is slidably mounted in the recovery tank 2, and the anti-accumulation assembly 4 pushes the shakeout in the recovery tank 2 to the outer sides of the two discharge ports 21 by reciprocating movement.

Specifically, prevent long-pending material subassembly 4 includes connecting block 41, the upper end of connecting block 41 slides in the spacing groove 23 that the collection box 2 upside was seted up, simultaneously rotate in the upside of collection box 2 and be equipped with lead screw 3, lead screw 3 runs through the upper end of connecting block 41 and with connecting block 41 threaded connection, the one end of lead screw 3 and the output shaft of motor, the starter motor makes lead screw 3 rotatory, the restriction of limiting groove 23 is passed through to connecting block 41, slide in spacing groove 23, because link to each other with one side of hollow shell 42 at the lower extreme of connecting block 41, the downside activity of hollow shell 42 is equipped with pushing plate 48, impel pushing plate 48 to promote the knockout in the collection box 2 when hollow shell 42 removes and discharge.

In order to push out the shakeout from the recovery box 2 to the maximum extent, a rotating rod 421 is rotatably arranged at the lower side of the hollow shell 42, the rotating rod 421 is fixedly connected with the upper side of the pushing plate 48, the pushing plate 48 is rotated by the rotating rod 421, and when the pushing plate 48 pushes out the shakeout, the pushing plate 48 is rotated by the resistance of the shakeout, so that the pushing plate 48 is inclined, and the pushing area is increased.

Further, a first limiting rod 422 is arranged on one side of the hollow shell 42, the first limiting rod 422 limits one side of the pushing plate 48, a second limiting rod 423 is arranged on the other side of the hollow shell 42, the second limiting rod 423 limits the other side of the pushing plate 48, the rotation angle of the pushing plate 48 is limited, and the pushing stability of the pushing plate 48 is improved.

As shown in fig. 5, the inner walls of two sides of the hollow shell 42 are provided with sliding grooves 43, a bearing plate 45 is slidably disposed between the two sliding grooves 43, a plurality of anti-blocking rods 46 are disposed on the upper side of the bearing plate 45, and when the bearing plate 45 slides upwards, the anti-blocking rods 46 are caused to penetrate through the hollow shell 42 and slidably connect with the hollow shell 42, and the size of the hollow shell 42 is adapted to the size of the discharge hole of the shell 12, so that the anti-blocking rods 46 can block the discharge hole of the shell 12.

In order to enable the anti-blocking rod 46 to move up and down in a reciprocating manner, a cam 47 is arranged on the lower side of the inside of the hollow shell 42 in a rotating manner, a rotating shaft of the cam 47 is connected with an output shaft of a motor, after the motor is started, the cam 47 is enabled to rotate, the cam 47 intermittently pushes the bearing plate 45, so that the anti-blocking rod 46 can move in a reciprocating manner, meanwhile, an elastic piece II 44 is arranged at the lower end of the sliding groove 43, the upper end of the elastic piece II 44 is connected with the bearing plate 45, the elastic piece II 44 preferably adopts a metal spring, and the bearing plate 45 can reset when pushed through the elastic effect of the metal spring.

In summary, the vibration shakeout machine of the embodiment of the utility model has the working principle that shakeout falling off due to vibration in the shell 12 is collected through the recovery box 2, the connecting block 41 is driven to move along with the hollow shell 42 by utilizing the rotation of the screw rod 3, the hollow shell 42 is driven to push shakeout entering into the recovery box 2 along with the pushing plate 48, the shakeout is discharged from the discharge ports 21 on two sides of the recovery box 2, the pushing plate 48 is inclined after being subjected to the resistance of shakeout, the scope of pushing the shakeout is increased, the bearing plate 45 is pushed by the rotation of the cam 47, the bearing plate 45 is driven to continuously move up and down along with the anti-blocking rod 46, and the anti-blocking rod 46 moves up and down in the discharge port on the lower side of the shell 12 in the moving process of the pushing plate 48.

The above is only a preferred embodiment of the present utility model, and is not intended to limit the present utility model, but various modifications and variations can be made to the present utility model by those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present utility model should be included in the protection scope of the present utility model.

Claims (10)

1. A vibrating sand-falling machine, comprising a vibrating assembly, characterized in that: a recovery box (2) is provided at the lower side of the vibrating assembly, a feed port (22) provided at the upper side of the recovery box (2) corresponds to a discharge port of the vibrating assembly, discharge ports (21) are provided at both sides of the recovery box (2), an anti-accumulation assembly (4) is slidably installed inside the recovery box (2), and the anti-accumulation assembly (4) pushes the sand in the recovery box (2) to the outside of the two discharge ports (21) through reciprocating movement. 2. The vibrating sand-falling machine according to claim 1 is characterized in that: the anti-accumulation component (4) includes a connecting block (41), the upper end of the connecting block (41) slides in a limiting groove (23) opened on the upper side of the recovery box (2), the lower end of the connecting block (41) is connected to one side of the hollow shell (42), and a push plate (48) is movably provided on the lower side of the hollow shell (42). 3. The vibrating sand-falling machine according to claim 2 is characterized in that a rotating rod (421) is rotatably provided on the lower side of the hollow shell (42), and the rotating rod (421) is fixedly connected to the upper side of the push plate (48). 4. The vibrating sand-falling machine according to claim 3, characterized in that a first limiting rod (422) is provided on one side of the hollow shell (42), and a second limiting rod (423) is provided on the other side of the hollow shell (42). 5. The vibrating sand-falling machine according to claim 4 is characterized in that: sliding grooves (43) are provided on the inner walls on both sides of the hollow shell (42), a bearing plate (45) is slidably provided between the two sliding grooves (43), and a plurality of anti-blocking rods (46) are provided on the upper side of the bearing plate (45), and the upper ends of the anti-blocking rods (46) penetrate the hollow shell (42) and are slidably connected to the hollow shell (42). 6. The vibrating sand-falling machine according to claim 5, characterized in that a cam (47) is rotatably provided on the lower side of the hollow shell (42), and the rotating shaft of the cam (47) is connected to the output shaft of the motor. 7. The vibrating sand-falling machine according to claim 6, characterized in that: a second elastic member (44) is provided at the lower end of the slide groove (43), and the upper end of the second elastic member (44) is connected to a bearing plate (45). 8. The vibrating sand-falling machine according to claim 2 is characterized in that a screw rod (3) is rotatably provided on the upper side of the recovery box (2), the screw rod (3) passes through the upper end of the connecting block (41) and is threadedly connected to the connecting block (41), and one end of the screw rod (3) is connected to the output shaft of the motor. 9. The vibrating sand-falling machine according to claim 8, characterized in that the discharge ports (21) on both sides of the recovery box (2) extend out of the housing (12). 10. The vibrating sand-falling machine according to claim 1 is characterized in that: the vibrating assembly comprises a support base (1) placed on the ground, an elastic member (11) is provided on the upper side of the support base (1), the upper end of the elastic member (11) is connected to the side wall of the outer shell (12), a vibrating motor (13) is installed on both side walls of the outer shell (12), and a screen plate (14) is provided inside the outer shell (12).