CN114940360A - Vibration disc shunting device and shunting method thereof - Google Patents

Abstract

The invention relates to the field of automatic feeding, in particular to a vibration disc shunting device and a shunting method thereof. Its device is including the circle vibration dish that shakes of placing the material, removable reposition of redundant personnel track directly shakes the mechanism, the feed mechanism of separation material, the counter weight directly shakes the mounting panel, the circle shakes the vibration dish and is equipped with at least one discharge gate, the reposition of redundant personnel track directly shakes the mechanism, feed mechanism all connects on the counter weight directly shakes the mounting panel, the reposition of redundant personnel track directly shakes the mechanism and adjusts the reposition of redundant personnel feed inlet butt joint circle vibration dish that highly makes the reposition of redundant personnel track directly shake the mechanism on the counter weight directly shakes the mounting panel, the material is shunted to a plurality of reposition of redundant personnel discharge gates in the reposition of redundant personnel track directly shakes the mechanism on, feed mechanism is equipped with a plurality of branch silos and divides silo and branch discharge gate butt joint one by one. The shunting mechanism is modularized, the disc body of the circular vibration disc does not need to be manufactured again, the model changing cost is reduced, and the time required by model changing is saved.

Description

Vibration disc shunting device and shunting method thereof

Technical Field

The invention relates to the field of automatic feeding, in particular to a vibration disc shunting device and a shunting method thereof.

Background

The vibration dish material that present automation line used says that quantity is most to be decided by the quantity of the material way welding sheet metal component of vibration dish, in case quantity is confirmed just can't change, and automation equipment manufacture factory often faces the requirement that the customer improves production efficiency once more on the basis of original agreement, just so need change the vibration dish, if need change, just need make the disk body again, or increase transition mechanism and reach the requirement, but can corresponding incremental cost and equipment space, probably can't replace under the condition that does not have space allowance. In order to reduce the cost, save the space and flexibly meet the requirements of customers.

Disclosure of Invention

The invention provides a vibration disc shunting device and a shunting method thereof, aiming at solving the problems of reducing cost, saving space and flexibly meeting the material feeding requirements of different production efficiencies.

The invention provides a vibration disc shunting device which comprises a circular vibration disc, a replaceable shunting track direct vibration mechanism, a material distributing mechanism and a counterweight direct vibration mounting plate, wherein materials are placed on the circular vibration disc, the shunting track direct vibration mechanism and the material distributing mechanism are connected onto the counterweight direct vibration mounting plate, the height of the shunting track direct vibration mechanism on the counterweight direct vibration mounting plate is adjusted to enable a shunting feed port of the shunting track direct vibration mechanism to be in butt joint with a guide rail discharge port of the circular vibration disc, the materials are shunted to a plurality of shunting discharge ports in the shunting track direct vibration mechanism, the material distributing mechanism is provided with a plurality of distributing grooves, and the distributing grooves are in one-to-one butt joint with the shunting discharge ports.

As a further improvement of the present invention, the shunting rail direct vibration mechanism includes a shunting rail plate, a rail cover, and a counterweight direct vibration device, wherein at least one group of one-to-many rail assemblies is disposed inside the shunting rail plate, the one-to-many rail assembly includes a feeding main rail and a plurality of discharging branch rails, one feeding main rail is communicated with the plurality of discharging branch rails, the counterweight direct vibration device is connected to the lower end of the shunting rail plate, the rail cover is provided with a rail slot position matched with the one-to-many rail assembly, and the rail cover is connected to and covers above the shunting rail plate.

As a further improvement of the invention, the vibration disc shunting device comprises a height adjusting screw rod, and two ends of the height adjusting screw rod are respectively connected with the counterweight direct vibration mounting plate and the counterweight direct vibration device.

As a further improvement of the invention, the vibrating disk shunting device comprises a starved feed sensor at the shunting feed inlet.

As a further improvement of the invention, the material distribution mechanism comprises a material pushing block, a sliding table cylinder, a cylinder fixing frame and a cylinder height adjusting block, wherein the cylinder fixing frame is connected to the counterweight direct vibration mounting plate, the cylinder height adjusting block is respectively connected with the cylinder fixing frame and the sliding table cylinder, the material pushing block is connected to the sliding table cylinder, a material distribution groove is arranged on the material pushing block, the material distribution groove is in butt joint with a material distribution outlet when the sliding table cylinder is closed, and the material pushing block deviates from the material distribution outlet to send out materials when the sliding table cylinder is driven.

As a further improvement of the invention, the vibration disc shunting device comprises material in-place sensors, and each material distributing groove is provided with one material in-place sensor.

As a further improvement of the invention, the material distribution mechanism further comprises a limiting column, a buffer and a limiting slide block, the material pushing block is connected to the sliding table cylinder through the limiting slide block, the cylinder fixing frame is provided with a buffer fixing frame in an extending manner towards the moving direction of the material pushing block, the limiting column and the buffer are both connected to the buffer fixing frame, and the limiting slide block is in contact with the limiting column and the buffer when the sliding table cylinder drives the material pushing block to a specified position.

The invention also provides a vibration disc shunting method of the vibration disc shunting device, which comprises the following steps of:

s1, selecting a shunting track direct vibration mechanism with a corresponding specification according to actual production takt time, fixing the shunting track direct vibration mechanism on a workbench, and adjusting a circular vibration disc and a height adjusting screw rod to enable a guide rail discharge port of the circular vibration disc to be in butt joint with a shunting feed port of the shunting track direct vibration mechanism; the height adjusting block of the adjusting cylinder enables the material distributing groove of the material pushing block to be in butt joint with the material distributing outlet of the direct vibration mechanism of the distributing track;

s2, enabling the material of the circular vibration disk to flow into a feeding main rail of a shunt rail plate in a shunt rail direct vibration mechanism, and enabling the material to flow out of a plurality of discharging branch rails into a material distributing groove of a material pushing block through shunting;

s3, after the material in-place sensor senses that the material in the material distribution groove is in place, the sliding table cylinder drives the material push block to distribute the material, and the material push block is driven by the sliding table cylinder to return to feed when the material is taken away;

s4, repeating the steps S2-S3 until the material lack sensor does not sense the material, and sending a signal to alarm to remind feeding.

As a further improvement of the present invention, the shunt rail direct vibration mechanism with the corresponding specification in step S1 includes one shunt rail plate with one specification of one-to-two, one-to-four, one-to-six, and one-to-eight.

The beneficial effects of the invention are: the split-flow mechanism is modularized, if the production efficiency is improved, only the one-to-many magnet cover track and the magnet cover push block are required to be replaced by the required magnet cover track, the matched magnet cover push block and the magnet cover plate, a disc body of the circular vibration disc does not need to be manufactured again, the cost of model changing is reduced, the time required by model changing is saved, and the split-flow mechanism has certain advantages in automatic production upgrading and reconstruction.

Drawings

FIG. 1 is an overall structural view of a vibration disk dividing apparatus of the present invention;

FIG. 2 is a side view of the construction of a vibratory pan diverter assembly of the present invention;

fig. 3 is an exploded view of the structure of a vibrating disk shunt device of the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below with reference to the accompanying drawings and embodiments.

As shown in fig. 1 to 3, the vibration disk dividing device of the present invention includes a circular vibration disk 1 for placing a material, a replaceable dividing rail direct vibration mechanism 2, a material separating mechanism 3 for separating the material, and a counterweight direct vibration mounting plate 4, wherein the circular vibration disk 1 is provided with at least one guide rail discharge port 11, the dividing rail direct vibration mechanism 2 and the material separating mechanism 3 are both connected to the counterweight direct vibration mounting plate 4, the height of the dividing rail direct vibration mechanism 2 on the counterweight direct vibration mounting plate 4 is adjusted to enable the dividing rail discharge port of the dividing rail direct vibration mechanism 2 to be in butt joint with the guide rail discharge port 11 of the circular vibration disk 1, the material is divided to a plurality of dividing discharge ports in the dividing rail direct vibration mechanism 2, the material separating mechanism 3 is provided with a plurality of material dividing grooves 31, and the material dividing grooves 31 are in one-to-one butt joint with the dividing discharge ports.

The circular vibration disk 1 comprises a material barrel 12 for placing materials and a vibration rail 13 protruding out of the outer wall of the material barrel 12, a discharge chute 14 is formed in the wall of the material barrel 12, the material barrel 12 is communicated with the vibration rail 13 through the discharge chute 14, and at least one guide rail discharge port 11 is formed in the communication of the vibration rail 13. The circular vibration disk 1 is generally provided with a guide rail discharge port 11, and can also be butted with a plurality of guide rail discharge ports 11 on a vibration track 13 according to the production requirement, and the discharge end of the circular vibration disk 1 is firstly subjected to one-level material distribution.

The guide rail discharge port 11 of the circular vibration disk 1 can be one, or two guide rail discharge ports 11 as shown in fig. 1, even more guide rail discharge ports 11 can be provided according to the specification of the circular vibration disk 1, the shunt feed port of the shunt track direct vibration mechanism 2 selects the shunt feed port specification corresponding to the guide rail discharge ports 11 of the circular vibration disk 1 in quantity, the shunt track direct vibration mechanism 2 adopts a quick-change shunt mechanism of one-to-two, one-to-four, one-to-six or one-to-eight, the material of the circular vibration disk 1 is shunted into more branches, thereby achieving the effect of material division and improving the production efficiency. The material distributing mechanism 3 uniformly moves the separated materials, so that the mechanical arm can grab the materials to carry out the next procedure conveniently.

As shown in fig. 3, the shunt rail direct vibration mechanism 2 includes a shunt rail plate 21, a rail cover 22, and a counterweight direct vibration device 23, at least one group of one-to-many rail components is disposed inside the shunt rail plate 21, the one-to-many rail components include a feeding main rail 24 and a plurality of discharging branch rails 25, the feeding main rail 24 is communicated with the plurality of discharging branch rails 25, the counterweight direct vibration device 23 is connected to the lower end of the shunt rail plate 21, the rail cover 22 is provided with a rail slot 26 matched with the one-to-many rail components, and the rail cover 22 is connected to and covers the shunt rail plate 21. Weighted rectilinear vibrator 23 is preferably a 120 weighted rectilinear vibrator.

The shunting track board 21 can select the track shape of different specifications for use according to the production demand, has a plurality of feeding main tracks 24 to dock guide rail discharge gate 11 that the circle shakes vibration dish 1 promptly, shunts the material to more ejection of compact branch tracks 25 again, realizes multiple branch material form, satisfies different production beats. The track cover 22 also selects different types of shapes according to different specifications of the shunt track plate 21 to adapt to the position relationship between the main feeding track 24 and the branch discharging track 25 in the shunt track plate 21, the track cover 22 can prevent materials from being shaken out of the shunt track plate 21 when the materials move in a vibrating manner, and the track cover 22 and the shunt track plate 21 can be matched to form a three-dimensional feeding and discharging track. The counterweight vibrator 23 provides a stable vibration frequency to the shunt track plate 21, so that the material in the one-to-many track assembly gradually moves from the shunt feed inlet to the shunt discharge outlet of the shunt track plate 21 in a vibration state.

The vibration disc shunting device comprises a height adjusting screw rod 5, and two ends of the height adjusting screw rod 5 are respectively connected with a counterweight direct vibration mounting plate 4 and a counterweight direct vibration device 23. And the height of the shunt track plate 21 can be adjusted by screwing the height adjusting screw 5, so that the shunt track plate is suitable for the guide rail discharge port 11 of different circular vibration discs 1, and the shunt track plate 21 can be ensured to be butted with the circular vibration discs.

This vibration dish diverging device is including lacking material sensor 6, lacks material sensor 6 and is splitting feed inlet department. The material shortage sensor 6 monitors whether materials enter the shunt track plate 21 in real time, and if the materials do not enter the shunt track plate, an alarm is given to remind people of feeding materials manually.

The material distribution mechanism 3 comprises a material pushing block 32, a sliding table cylinder 33, a cylinder fixing frame 34 and a cylinder height adjusting block 35, the cylinder fixing frame 34 is connected to the counterweight direct vibration mounting plate 4, the cylinder height adjusting block 35 is respectively connected with the cylinder fixing frame 34 and the sliding table cylinder 33, the material pushing block 32 is connected to the sliding table cylinder 33, a material distribution groove 31 is formed in the material pushing block 32, the material distribution groove 31 is in butt joint with a material distribution outlet when the sliding table cylinder 33 is closed, and the material pushing block 32 deviates from the material distribution outlet to send out materials when the sliding table cylinder 33 is driven. The sliding table cylinder 33 can move transversely relative to the cylinder fixing frame 34 so as to drive the material pushing block 32 to perform feeding, and the height of the sliding table cylinder 33 relative to the cylinder fixing frame 34 can be adjusted through the cylinder height adjusting block 35, so that the material distributing groove 31 of the material pushing block 32 is in butt joint with the discharge hole of the material distributing track plate 21, and normal moving feeding of materials is guaranteed.

The vibration disc shunting device comprises material in-place sensors 7, and each material distributing groove 31 is provided with one material in-place sensor 7. The material in-place sensor 7 monitors whether all the material distributing grooves 31 are filled with materials in place, and when all the materials are detected to be in place, the sliding table air cylinder 33 drives the material pushing block 32 to convey the materials away.

The material distributing mechanism 3 further comprises a limiting column 36, a buffer 37 and a limiting slide block 38, the material pushing block 32 is connected to the sliding table cylinder 33 through the limiting slide block 38, a buffer fixing frame 39 extends from the cylinder fixing frame 34 to the moving direction of the material pushing block 32, the limiting column 36 and the buffer 37 are both connected to the buffer fixing frame 39, and the limiting slide block 38 is in contact with the limiting column 36 and the buffer 37 when the sliding table cylinder 33 drives the material pushing block 32 to a specified position. The stop post 36 is preferably a stop bolt and the bumper 37 is preferably a hydraulic bumper. When the material pushing block 32 is driven by the sliding cylinder 33 to perform the transverse moving feeding for a certain distance, the limiting slide block 38 firstly contacts with the buffer 37 to slowly reduce the speed, and finally contacts with the limiting post 36, the buffer 37 can prevent the limiting slide block 38 from directly colliding with the limiting post 36 to cause the material to fall, and the limiting post 36 can position the final position of the limiting slide block 38 to match with the material taking position of the mechanical arm, so that the mechanical arm can smoothly take the material.

The flow dividing method of the vibration disc flow dividing device comprises the following steps:

s1, selecting a shunting track direct vibration mechanism 2 with a corresponding specification according to actual production takt time, fixing the shunting track direct vibration mechanism 2 on a workbench, and adjusting a circular vibration disc 1 and a height adjusting screw 5 to enable a guide rail discharge port 11 of the circular vibration disc 1 to be in butt joint with a shunting feed port of the shunting track direct vibration mechanism 2; the height adjusting block 35 of the adjusting cylinder enables the material distributing groove 31 of the material pushing block 32 to be in butt joint with the material distributing outlet of the direct vibration mechanism 2 of the distributing track; the shunt track direct vibration mechanism 2 corresponding to the specification comprises a shunt track plate 21 with the specification of one-to-two, one-to-four, one-to-six and one-to-eight;

s2, the material of the circular vibration disk 1 flows into the feeding main rail 24 of the shunt rail plate 21 of the shunt rail direct vibration mechanism 2 and flows out of the multiple discharging branch rails 25 into the distributing groove 31 of the material pushing block 32 through shunting;

s3, after the material in-place sensor 7 senses that the material at the position of the material distributing groove 31 is in place, the sliding table cylinder 3 drives the material pushing block 32 to distribute the material, and the material taking sliding table cylinder 33 drives the material pushing block 32 to return to feed;

s4, repeatedly executing the steps S2-S3 until the material shortage sensor 6 cannot sense the material, and sending a signal to alarm to remind feeding.

Specifically, like the vibration dish diverging device of fig. 1 and fig. 3, this device can be used for magnet lid material loading, fixes many quick change diverging mechanism of one minute on the workstation through the bolt, then adjusts one minute two circles vibration dish 1 and height adjusting screw 5 and makes the guide rail discharge gate and the reposition of redundant personnel track directly shake the reposition of redundant personnel feed inlet butt joint of mechanism 2. Two one minute circle vibration dish 1 materials flow in two become four magnet lid tracks, then flow in the material ejector pad 32 of magnet lid, and the material sensor 7 that targets in place senses four positions materials and targets in place, and slip table cylinder 5 drives magnet lid material ejector pad 32 branch material, treats that the material takes away, and slip table cylinder 33 drives magnet lid material ejector pad 32 and returns the feeding. If the material shortage sensor 6 cannot sense the material, a signal is sent to alarm to remind feeding.

The invention is suitable for an automatic production line adopting the automatic feeding of the vibrating disc, can determine that a quick-change shunting mechanism with one to two, one to four, one to six or one to eight is adopted according to the actual production takt time, and can be replaced by the required quick-change shunting mechanism only by removing the fixing screw, thereby avoiding the scrapping of the whole vibrating disc feeding mechanism caused by the change of customer requirements, having certain adjustment flexibility and avoiding the scrapping of the whole mechanism.

The foregoing is a more detailed description of the invention in connection with specific preferred embodiments and it is not intended that the invention be limited to these specific details. For those skilled in the art to which the invention pertains, several simple deductions or substitutions can be made without departing from the spirit of the invention, and all shall be considered as belonging to the protection scope of the invention.

Claims (9)

1. The utility model provides a vibration dish diverging device, its characterized in that directly shakes vibration dish, removable reposition of redundant personnel track including the circle of placing the material and directly shakes feed mechanism, the counter weight of mechanism, separation material and directly shakes the mounting panel, the circle shakes the vibration dish and is equipped with at least one guide rail discharge gate, reposition of redundant personnel track directly shakes mechanism, feed mechanism and all connects on the counter weight directly shakes the mounting panel, reposition of redundant personnel track directly shakes the mechanism and adjusts the high messenger that directly shakes on the mounting panel at the counter weight shunt feed inlet butt joint circle of mechanism that shakes vibration dish guide rail discharge gate, the material is shunted to a plurality of reposition of redundant personnel discharge gates in reposition of redundant personnel track directly shakes the mechanism, feed mechanism is equipped with a plurality of minutes silo just divide silo and reposition of redundant personnel discharge gate butt joint one by one.

2. The vibration plate shunting device according to claim 1, wherein the shunting rail direct vibration mechanism comprises a shunting rail plate, a rail cover, and a counterweight direct vibration device, at least one group of one-to-many rail components is arranged inside the shunting rail plate, the one-to-many rail components comprise a feeding main rail and a plurality of discharging branch rails, the feeding main rail is communicated with the plurality of discharging branch rails, the counterweight direct vibration device is connected to the lower end of the shunting rail plate, the rail cover is provided with a rail groove matched with the one-to-many rail components, and the rail cover is connected to and covers above the shunting rail plate.

3. The vibratory pan diverter of claim 1, comprising a height adjustment screw having ends connected to the weighted linear vibrator mounting plate and the weighted linear vibrator, respectively.

4. The vibrating disk diverter device of claim 1, comprising an starved sensor at the diverter feed inlet.

5. A vibration disk dividing device according to claim 1, wherein the dividing mechanism includes a material pushing block, a sliding table cylinder, a cylinder fixing frame, and a cylinder height adjusting block, the cylinder fixing frame is connected to the counterweight direct vibration mounting plate, the cylinder height adjusting block is respectively connected to the cylinder fixing frame and the sliding table cylinder, the material pushing block is connected to the sliding table cylinder, a material dividing groove is arranged on the material pushing block, the material dividing groove is butted with a material dividing outlet when the sliding table cylinder is closed, and the material pushing block deviates from the material dividing outlet to send out the material when the sliding table cylinder is driven.

6. The vibratory pan diverter of claim 5 including a material in position sensor, one material in position sensor being located on each chute.

7. A vibration disk dividing device according to claim 5, wherein the dividing mechanism further comprises a limiting post, a buffer and a limiting slider, the material pushing block is connected to the sliding table cylinder through the limiting slider, the cylinder fixing frame is provided with a buffer fixing frame extending in the direction of movement of the material pushing block, the limiting post and the buffer are both connected to the buffer fixing frame, and the limiting slider is in contact with the limiting post and the buffer when the sliding table cylinder drives the material pushing block to a specified position.

8. A vibrating disk shunt method for a vibrating disk shunt device according to any one of claims 1 to 7, comprising the steps of:

s1, selecting a shunting track direct vibration mechanism with a corresponding specification according to actual production takt time, fixing the shunting track direct vibration mechanism on a workbench, and adjusting a circular vibration disc and a height adjusting screw rod to enable a discharge port of the circular vibration disc to be in butt joint with a shunting feed port of the shunting track direct vibration mechanism; the height adjusting block of the adjusting cylinder enables the material distributing groove of the material pushing block to be in butt joint with the material distributing outlet of the direct vibration mechanism of the distributing track;

s2, enabling the material of the circular vibration disk to flow into a feeding main rail of a shunt rail plate in a shunt rail direct vibration mechanism, and enabling the material to flow out of a plurality of discharging branch rails into a material distributing groove of a material pushing block through shunting;

s3, after the material in-place sensor senses that the material in the material distribution groove is in place, the sliding table cylinder drives the material push block to distribute the material, and the material is taken away and the sliding table cylinder drives the material push block to return to feed;

s4, repeating the steps S2-S3 until the material lack sensor does not sense the material, and sending a signal to alarm to remind feeding.

9. The vibrating disk dividing method according to claim 8, wherein the size-corresponding dividing track linear vibration mechanism in step S1 includes one of one-to-two, one-to-four, one-to-six, and one-to-eight dividing track plates.

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