CN105293029A

CN105293029A - Discharge device for ceramic ferrules

Info

Publication number: CN105293029A
Application number: CN201510716303.8A
Authority: CN
Inventors: 徐刚; 朱俊
Original assignee: NINGBO BRIGHT PHOTOELECTRIC TECHNOLOGY CO LTD
Current assignee: NINGBO BRIGHT PHOTOELECTRIC TECHNOLOGY CO LTD
Priority date: 2015-10-24
Filing date: 2015-10-24
Publication date: 2016-02-03
Anticipated expiration: 2035-10-24
Also published as: CN105293029B

Abstract

The invention provides a discharge device for ceramic ferrules. The discharge device comprises a feed pipe, a first discharge pipe, a screening module and a second discharge pipe. The ceramic ferrules are fed into the discharge device from the feed pipe. The first discharge pipe is arranged below the feed pipe, and an inlet of the first discharge pipe is opposite to an outlet of the feed pipe. The screening module is arranged between the feed pipe and the first discharge pipe and is suitable for enabling the small-end-downward ceramic ferrules falling from the feed pipe to pass through the screening module and fall into the first discharge pipe and enabling the big-end-downward ceramic ferrules falling from the feed pipe to be pushed out of the screening module. The second discharge pipe is used for discharging the ceramic ferrules pushed out of the screening module.

Description

A kind of ceramic insertion core discharge device

Technical field

The present invention relates to a kind of ceramic insertion core discharge device, particularly relate to a kind of can by ceramic insertion core with identical towards discharge discharge device.

Background technology

Ceramic insertion core is the core component of the joints of optical fibre, asymmetric due to the two ends of ceramic insertion core, after therefore ceramic insertion core machines, need by be arranged as towards unordered ceramic insertion core identical towards.If by artificial to ceramic insertion core towards selecting, by human resources a large amount of for waste, also greatly can reduce production efficiency, in actual production, be therefore badly in need of providing a kind of can be converted to towards unordered ceramic insertion core towards the device of orderly ceramic insertion core.

Summary of the invention

Main purpose of the present invention is to provide a kind of ceramic insertion core discharge device, this discharge device can by difference towards ceramic insertion core be separated, thus realize the ordered arrangement of ceramic insertion core.

For reaching above object, the invention provides a kind of ceramic insertion core discharge device, comprising:

Feed pipe, ceramic insertion core sends into described discharge device from described feed pipe;

First discharge nozzle, it is located at below described feed pipe, and the entrance of described first discharge nozzle is relative with the outlet of described feed pipe;

Screening module, it is located between described feed pipe and described first discharge nozzle, the small end ceramic insertion core down that described screening module is suitable for making to fall from described feed pipe falls into described first discharge nozzle by described screening module, the large end ceramic insertion core down fallen from described feed pipe is shifted out described screening module, described screening module comprises a block and and releases baffle plate, described block can be located at the side of described feed pipe and described first discharge nozzle up or down, a gear platform is extended to the below of described feed pipe in the side of described block, described gear edge of table is less than the external diameter of the large end of described ceramic insertion core to the distance of described feed pipe line of centers, be greater than the external diameter of described ceramic insertion core small end, described release baffle plate is located at above described block, described release baffle plate and described block are worked in coordination, when being moved down into an end position to make described block, described release baffle plate laterally moves to the direction of ceramic insertion core, when small end ceramic insertion core down falls along the line of centers of described feed pipe, the distance of described block movement can not arrive described end position, now small end ceramic insertion core down falls into described first discharge nozzle, when the line of centers holding greatly ceramic insertion core down along described feed pipe falls, promote described block and move to end position, now the ceramic insertion core held greatly is down released described screening module by described release baffle plate, and

Second discharge nozzle, for discharging the described ceramic insertion core released from described screening module.

Preferably, described screening module also comprises a stopper spring, and described stopper spring acts on described block, is suitable for, when described block is not by external force, making described block be moved upwards up to initial position.

Preferably, described screening module also comprises a tumbler and a rotation spring, described tumbler is located at the opposite side of described block rotationally, the upper end of described tumbler extends to above described block, the upper end of described tumbler forms an arc surface, described rotation spring acts on described tumbler, be suitable for the arc surface of described tumbler is laterally moved to the direction of described ceramic insertion core, the middle part of described tumbler tilts to be butted on described block, when described block is moved down, the arc surface of described tumbler laterally moves to the direction of described ceramic insertion core, described release baffle plate is located at the inner side of the arc surface of described tumbler.

Preferably, the arc surface of described tumbler has one first limit track, the upper surface of described block has one second limit track, the rear side of described release baffle plate extends a connection piece, described attaching parts is located at described second limit track movably through the first limit track, described first limit track and described second limit track have an end position, when described attaching parts moves to the end position of described first limit track and described second limit track, described block moves to its end position, before described attaching parts moves to the end position of described first limit track and described second limit track, described attaching parts drives described release baffle plate to rotate along the arc surface of described tumbler, after described attaching parts moves to the end position of described first limit track and described second limit track, described attaching parts drives described release baffle plate laterally inwardly to move side relative to the arc surface of described tumbler, thus described ceramic insertion core is released described screening module.

Preferably, described discharge device also comprises swings to module, described module of swinging to comprises rotating disk, motor, lock pin support, described lock pin props up the side being set up in described screening module, be suitable for supporting the ceramic insertion core released from described screening module, the side of described lock pin support is located at rotationally by described rotating disk, described motor is for driving described dial rotation, described rotating disk comprises multiple lock pin locking pin, when described dial rotation, described lock pin locking pin is periodically through described lock pin support, when described lock pin support there being ceramic insertion core, described lock pin locking pin can insert in the lock pin hole of described ceramic insertion core, thus ceramic insertion core described in described driven by rotary disc rotates, the opposite side of described rotating disk is located at by described second discharge nozzle, the described ceramic insertion core fallen from described rotating disk is made to fall into described second discharge nozzle.

Preferably, described feed pipe is the plastic pipe with certain deformability.

Preferably, described module of swinging to also comprises transmission bracket, described transmission bracket comprises a rocking bar and a driving lever, described rotating disk comprises a rotating shaft and multiple fixture block, each described fixture block is corresponding with each described lock pin locking pin, described rocking bar one end is connected with the output shaft of described motor, the middle part of the other end and described driving lever is hinged, the front end of described driving lever forms Y shaped bracket, described fixture block on described rotating disk is suitable for the Y shaped bracket snapping in described driving lever, the rear end of described driving lever has a slide rail, described rotating shaft is through the slide rail of described driving lever, when described rocking bar moves in a circle under the drive of described motor, described driving lever rotates along a circular arc under the drive of described rocking bar and under the restriction of described rotating shaft, move up and down simultaneously, the Y shaped bracket of described driving lever is separated or clamping successively with each described fixture block on described rotating disk, thus stir described dial rotation.

Above preferred embodiment of the present invention has following beneficial effect: ceramic insertion core discharge device provided by the invention can effectively and quickly by difference towards ceramic insertion core be separated, and the ceramic insertion core be separated is discharged from different drainage conduit respectively, make the ceramic insertion core in each drainage conduit be all according to identical towards arrangement, realize the ordered arrangement of ceramic insertion core; By reversing mechanism, the direction of the ceramic insertion core that two drainage conduit are discharged is identical, further increases work efficiency; Ceramic insertion core discharge device provided by the invention, when screening, due to the setting of tumbler, makes ceramic insertion core be not easy to occur stuck state; The structure that ceramic insertion core discharge device relates to is all lower-cost mechanical mechanism, and therefore holistic cost is low.

Accompanying drawing explanation

Fig. 1 is the using state figure of a preferred embodiment according to ceramic insertion core discharge device of the present invention.

Fig. 2 is the schematic perspective view of a preferred embodiment according to ceramic insertion core discharge device of the present invention.

Fig. 3 is the schematic diagram of the screening module of a preferred embodiment according to ceramic insertion core discharge device of the present invention.

Fig. 4 is the schematic diagram of swinging to module of a preferred embodiment according to ceramic insertion core discharge device of the present invention.

Fig. 5 is the exploded view of swinging to module of a preferred embodiment according to ceramic insertion core discharge device of the present invention.

Fig. 6 A-D show the large end of ceramic insertion core down time change schematic diagram.

Fig. 7 A-C show ceramic insertion core small end downward time change schematic diagram.

Detailed description of the invention

Below describe and realize the present invention for disclosing the present invention to enable those skilled in the art.Preferred embodiment in below describing only as an example, it may occur to persons skilled in the art that other apparent modification.

Fig. 1 shows the real use state of a kind of ceramic insertion core discharge device 1 of the present invention.Discharge device 1 is connected with a hopper 2, and hopper 2 is suitable for ceramic insertion core to send into discharge device 1 successively disorderly.Hopper 2 has a conveying track, and the width of described conveying track mates with the width of ceramic insertion core, thus ceramic insertion core sends into discharge device 1 one by one successively.The transport of hopper 2 pairs of ceramic insertion cores is prior art, and the present invention no longer describes in detail.

As shown in Figure 2, discharge device 1 comprises feed pipe 11, screening module 12, first discharge nozzle 14 and the second discharge nozzle 15.The entrance of feed pipe 11 is communicated with hopper 2, and the outlet of feed pipe 11 is relative with the top of screening module 12, thus ceramic insertion core enters screening module 12 when the outlet of feed pipe 11 falls.The below of screening module 12 is relative with the first discharge nozzle 14, screening module 12 be suitable for making predetermined towards ceramic insertion core pass through and discharge from the first discharge nozzle 14, and make a reservation for ceramic insertion core towards the opposite and be moved out of and screen module 12.Second discharge nozzle 15 is suitable for discharging the ceramic insertion core shifted out from screening module 12.By screening module 12, ceramic insertion core towards the opposite is separated.

In the above-described embodiments, although the ceramic insertion core in the first discharge nozzle 14 and the second discharge nozzle 15 is towards the opposite, but follow-up need ceramic insertion core in disposable change first discharge nozzle 14 or the second discharge nozzle 15 towards, can make all ceramic insertion cores towards identical.Therefore, compared with manually sorting, this embodiment still drastically increases work efficiency.

In a further advantageous embodiment, discharge device 1 also comprises swings to module 13, swing to module 13 for the ceramic insertion core that reverses towards.Swing to the side that module 13 is located at screening module 12, thus ceramic insertion core enters and swings to module 13 after being moved out of screening module 12, swing to module 13 relative with the second discharge nozzle 15, discharge towards from the second discharge nozzle 15 according to predetermined through swinging to the ceramic insertion core that module 13 swings to, thus the ceramic insertion core that the first discharge nozzle 14 is discharged with the second discharge nozzle 15 towards identical.

Preferably, discharge device 1 also comprises a mounting shell 100.Screening module 12 is installed on mounting shell 100; Mounting shell 100 is located at by feed pipe 11, and is in the top of screening module 12, falls into screening module 12 to make the ceramic insertion core fallen from the outlet of feed pipe 11; Swing to module 13 and be installed on mounting shell 100, and be in the side of screening module 12, swing to module 13 to make the ceramic insertion core shifted out from screening module 12 enter; Mounting shell 100 is located at by first discharge nozzle 14, and is in the below of screening module 12, discharges from the first discharge nozzle 14 to make the ceramic insertion core by screening module 12; Mounting shell 100 is located at by second discharge nozzle 15, and relative with swinging to module 13, discharges from the second discharge nozzle 15 to make the ceramic insertion core of swinging to through swinging to module 13.

In a preferred embodiment of the invention, screening module 12 is suitable for small end ceramic insertion core is down passed through, and the ceramic insertion core held greatly is down shifted out screening module 12.It is worth mentioning that, the small end of ceramic insertion core refers to and has carried out one end of chamfered, and the external diameter of the small end of ceramic insertion core is significantly less than the external diameter of large end.As shown in Figure 3, screen module 12 and comprise block 121, stopper spring 122, tumbler 123, rotation spring 124 and a release baffle plate 125.

The outlet of feed pipe 11 is relative with the entrance of the first discharge nozzle 14, and distance is between the two greater than the length of a ceramic insertion core.Block 121 can be located at the side of feed pipe 11 and the first discharge nozzle 14 up or down by stopper spring 122, a gear platform is extended to the below of feed pipe 11 in the side of block 121, described gear edge of table is less than the external diameter of the large end of ceramic insertion core to the distance of feed pipe 11 line of centers, is greater than the external diameter of ceramic insertion core small end, thus when ceramic insertion core falls from feed pipe 11 and offsets with block 121, ceramic insertion core promotes block 121 and moves down together, when block 121 moves down, there is deformation in stopper spring 122.It is worth mentioning that, due to the position of the gear platform of block 121, make to only have the outside of ceramic insertion core could contact with the gear platform of block 121, and the small end that ceramic insertion core external diameter is less, the gear platform of block 121 can not be touched.During in order to ensure that each ceramic insertion core falls from the outlet of feed pipe 11, the line of centers of ceramic insertion core overlaps with the line of centers of feed pipe 11, the internal diameter of feed pipe 11 less times greater than ceramic insertion core external diameter, to ensure that ceramic insertion core is when falling, and sway does not occur.By above structure, make different towards ceramic insertion core fall time, ceramic insertion core promotes the distance difference that block 121 moves down, also namely when the large end of ceramic insertion core falls down, the distance of block 121 movement than ceramic insertion core small end down time distance, because when ceramic insertion core small end down time, one section of ceramic insertion core front end does not reach with block 121, can not promote block 121 and move down.

Preferably, mounting shell 100 comprises a sleeve 101, the line of centers of sleeve 101 and the centerline parallel of feed pipe 11, and block 121 is movable to is located at sleeve 101, thus block 121 can move up and down along the line of centers of sleeve 101.Stopper spring 122 is sheathed on sleeve 101, and the lower end of stopper spring 122 is fixed, upper end and block 121 offset, thus when block 121 moves down along sleeve 101, stopper spring 122 is extruded generation elastic deformation.When block 121 is not by external force, stopper spring 122 makes block 121 be between feed pipe 11 and the first discharge nozzle 14.

Tumbler 123 is located at the opposite side of block 121 rotationally, the upper end of tumbler 123 extends to above block 121, the upper end of described tumbler 123 forms an arc surface 1231, the radian of arc surface 1231 mates with the radian of ceramic insertion core, and the arc surface 1231 along described tumbler 123 when making ceramic insertion core fall from feed pipe 11 moves down.Rotation spring 124 acts on tumbler 123, is suitable for the arc surface 1231 of tumbler 123 is laterally moved to ceramic insertion core.Tumbler 123 is butted on the opposite side of block 121 obliquely, thus when block 121 moves down, tumbler 123 rotates, and the arc surface 1231 of tumbler 123 laterally moves to the direction of ceramic insertion core.By above structure, while ceramic insertion core promotion block 121 is moved down, the arc surface 1231 of tumbler 123 promotes ceramic insertion core transverse shifting, when this is to ensure that ceramic insertion core moves to the entrance of the first discharge nozzle 14, ceramic insertion core is separated with block 121, avoids occurring stuck situation.

Preferably, tumbler 123 one-tenth obtuse angle shape, the arc surface 1231 of tumbler 123 is in one end of tumbler 123 traversing section, and the middle part of the tilting section of tumbler 123 is butted on block 121, and the lower end of the tilting section of tumbler 123 is articulated with mounting shell 100.Mounting shell 100 is fixed in one end of rotation spring 124, and the other end is connected with the tilting section of tumbler 123, thus keeps tumbler 123 to rotate to the direction of ceramic insertion core, also namely keeps the arc surface 1231 of tumbler 123 laterally to move to ceramic insertion core.

Releasing baffle plate 125 is an arc-shaped baffle, releases the radian of baffle plate 125 and mates with the radian of ceramic insertion core, releases the inner side that baffle plate 125 is located at the arc surface 1231 of tumbler 123, when ceramic insertion core falls, releases baffle plate 125 and directly contacts with ceramic insertion core.

The arc surface 1231 of tumbler 123 has one first limit track 1232, the upper surface of block 121 has one second limit track 1211, the rear side releasing baffle plate 125 extends a connection piece 1251, attaching parts 1251 is located in the second limit track 1211 through the first limit track 1232 movably, thus block 121 is driven by attaching parts 1251 when moving down and releases baffle plate 125 and move down, attaching parts 1251 is mobile in the first limit track 1232 and the second limit track 1211 simultaneously, and drives release baffle plate 125 to move.First limit track 1232 and the second limit track 1211 have an end position, and before attaching parts 1251 moves to end position, attaching parts 1251 drives release baffle plate 125 to rotate along the arc surface 1231 of tumbler 123; When after the end position that attaching parts 1251 moves to the first limit track 1232 and the second limit track 1211, the motion track of attaching parts 1251 changes, attaching parts 1251 drives release baffle plate 125 laterally inwardly to move side relative to the arc surface 1231 of tumbler 123, thus ceramic insertion core is pushed away between feed pipe 11 and the first discharge nozzle 14, also release screening module 12 by ceramic insertion core.That is, before attaching parts 1251 turns to end position, release baffle plate 125 and transverse shifting does not occur, ceramic insertion core falls smoothly; After attaching parts 1251 turns to end position, release baffle plate 125 and transverse shifting occurs, ceramic insertion core is laterally released.It is worth mentioning that, when attaching parts 1251 moves to end position, attaching parts 1,251 one section of being in outside arc surface 1231 is vertical with the first limit track 1232, thus ensure that attaching parts 1251 can pass the first limit track 1232 transverse shifting.

In conjunction with different towards ceramic insertion core fall time, ceramic insertion core promotes the distance difference that block 121 moves down, by adjusting the first limit track 1232 and the second limit track 1211 can make: the small end of ceramic insertion core down time, the distance of block 121 movement can not make attaching parts 1251 move to end position, thus ceramic insertion core is not pushed out, but fall into the first discharge nozzle 14 smoothly; The large end of ceramic insertion core down time, the distance of block 121 movement can make attaching parts 1251 turn to end position, thus ceramic insertion core is released screening module 12.

In addition, preferably, feed pipe 11 is for having the plastic pipe of certain deformability, this considers: drop to the ceramic insertion core of half under the promotion of tumbler 123 from feed pipe 11, slight transverse shifting can occur, and if now feed pipe 11 be rigidity, the state that ceramic insertion core is stuck may be there is, therefore, preferably, feed pipe 11 has certain flexibility.But the flexibility of feed pipe 11 is not easily excessive, otherwise be difficult to ensure that each ceramic insertion core linearly falls when falling.

As described in Fig. 4,5, swing to module 13 and comprise rotating disk 131, motor 132, lock pin support 133.The side of screening module 12 is located at by lock pin support 133, is suitable for temporarily supporting the ceramic insertion core released from screening module 12.Rotating disk 131 comprises multiple lock pin locking pin 1311, the side of lock pin support 133 is located at rotationally by rotating disk 131, thus when rotating disk 131 rotates, lock pin locking pin 1311 is periodically through lock pin support 133, when lock pin support 133 there being ceramic insertion core, lock pin locking pin 1311 just inserts in the lock pin hole of ceramic insertion core, thus rotating disk 131 drives ceramic insertion core to rotate, after rotating disk 131 turns over half cycle with ceramic insertion core, ceramic insertion core towards change, and ceramic insertion core falls from lock pin locking pin 1311 under gravity.The opposite side of rotating disk 131 is located at by second discharge nozzle 15, makes the ceramic insertion core fallen from rotating disk 131 just fall into the second discharge nozzle 15.

Motor 132 is connected with rotating disk 131, rotates for driving rotating disk 131.

Preferably, swing to module 13 and also comprise transmission bracket 134, the effect of transmission bracket 134 is the power of motor 132 to pass to rotating disk 131 with certain frequency and speed, to ensure the time gap that two lock pin locking pins 1311 are successively moved out of through time gap and adjacent two ceramic insertion cores of lock pin support 133.Transmission bracket 134 comprises rocking bar 1341 and a driving lever 1342.Rotating disk 131 is located at mounting shell 100 rotationally by a rotating shaft 1312.Rotating disk 131 also comprises multiple fixture block 1313, and each fixture block 1313 is corresponding with a lock pin locking pin 1311.

One end of rocking bar 1341 is connected with the output shaft of motor 132, and the middle part of the other end and driving lever 1342 is hinged.The front end of driving lever 1342 forms Y shaped bracket, and the fixture block 1313 on rotating disk 131 is suitable for the Y shaped bracket snapping in driving lever 1342.The rear end of driving lever 1342 has a slide rail, and rotating shaft 1312 is installed on mounting shell 100 through the slide rail of driving lever 1342, thus driving lever 1342 can move up and down along rotating shaft 1312, or 1312 rotates around the shaft.When rocking bar 1341 moves in a circle under the drive of motor 132, driving lever 1342, under the drive of rocking bar 1341 and under the restriction of rotating shaft 1312, move up and down, thus driving lever 1342 is separated or clamping with the fixture block 1313 on rotating disk 131 while a circular arc rotates.When driving lever 1342 and fixture block 1313 clamping, driving lever 1342 drives rotating disk 131 to rotate, and after rotating disk 131 turns over certain angle, driving lever 1342 is separated with fixture block 1313, then driving lever 1342 and the clamping of next fixture block 1313, continues to drive rotating disk 131 to rotate.

Fig. 6 A-D shows state when the large end of ceramic insertion core falls down.First, after ceramic insertion core 3 falls from feed pipe 11, the large end of ceramic insertion core 3 is butted on block 121, as shown in Figure 6A; Ceramic insertion core 3 moves down under gravity, and promote block 121 and move down, tumbler 123 rotates simultaneously, and the arc surface 1231 of tumbler 123 promotes ceramic insertion core and while whereabouts, transverse shifting occurs, as shown in Fig. 6 B, C; After attaching parts 1251 turns to end position, release baffle plate 125 transverse shifting, laterally released by ceramic insertion core, now block 121 moves up under the effect of stopper spring 122, and tumbler 123 also rotates thereupon, as shown in Figure 6 D.After ceramic insertion core is laterally released, just drop on lock pin support 133, the lock pin locking pin 1311 now on rotating disk 131 just turns to the below of ceramic insertion core, thus ceramic insertion core is taken away by rotating disk 131.

Fig. 7 A-C shows state when ceramic insertion core small end falls down.First, after ceramic insertion core 3 feed pipe 11 falls, the front end of ceramic insertion core 3 does not contact with block 121, but the rear side of ceramic insertion core 3 front end is butted on block 121, as shown in Figure 7 A; Ceramic insertion core 3 moves down under gravity, and promote block 121 and move down, tumbler 123 rotates simultaneously, and the arc surface 1231 of tumbler 123 promotes ceramic insertion core, while whereabouts, transverse shifting occurs, as shown in Figure 7 B; When ceramic insertion core 3 moves to the entrance of the first discharge nozzle 14, attaching parts 1251 does not also move to end position, now the distance of ceramic insertion core 3 transverse shifting is also just separated with block 121, ceramic insertion core enters the first discharge nozzle 14 smoothly, as seen in figure 7 c, after ceramic insertion core is separated with block 121, block 121 is moved upwards up to initial position in the effect of stopper spring 122, and the arc surface 1231 of tumbler 123 moves laterally to initial position simultaneously.

More than show and describe groundwork of the present invention, principal character and advantage of the present invention.The technical personnel of the industry should be understood; the present invention is not restricted to the described embodiments; the just principle of the present invention described in above-described embodiment and specification sheets; the present invention also has various changes and modifications without departing from the spirit and scope of the present invention, and these changes and improvements all fall in claimed scope of the present invention.The protection domain of application claims is defined by appending claims and equivalent thereof.

Claims

1. a ceramic insertion core discharge device, is characterized in that, comprising:

2. discharge device according to claim 1, is characterized in that, described screening module also comprises a stopper spring, and described stopper spring acts on described block, is suitable for, when described block is not by external force, making described block be moved upwards up to initial position.

3. discharge device according to claim 2, it is characterized in that, described screening module also comprises a tumbler and a rotation spring, described tumbler is located at the opposite side of described block rotationally, the upper end of described tumbler extends to above described block, the upper end of described tumbler forms an arc surface, described rotation spring acts on described tumbler, be suitable for the arc surface of described tumbler is laterally moved to the direction of described ceramic insertion core, the middle part of described tumbler tilts to be butted on described block, when described block is moved down, the arc surface of described tumbler laterally moves to the direction of described ceramic insertion core, described release baffle plate is located at the inner side of the arc surface of described tumbler.

4. discharge device according to claim 3, it is characterized in that, the arc surface of described tumbler has one first limit track, the upper surface of described block has one second limit track, the rear side of described release baffle plate extends a connection piece, described attaching parts is located at described second limit track movably through the first limit track, described first limit track and described second limit track have an end position, when described attaching parts moves to the end position of described first limit track and described second limit track, described block moves to its end position, before described attaching parts moves to the end position of described first limit track and described second limit track, described attaching parts drives described release baffle plate to rotate along the arc surface of described tumbler, after described attaching parts moves to the end position of described first limit track and described second limit track, described attaching parts drives described release baffle plate laterally inwardly to move side relative to the arc surface of described tumbler, thus described ceramic insertion core is released described screening module.

5. according to the arbitrary described discharge device of claim 1-4, it is characterized in that, described discharge device also comprises swings to module, described module of swinging to comprises rotating disk, motor, lock pin support, described lock pin props up the side being set up in described screening module, be suitable for supporting the ceramic insertion core released from described screening module, the side of described lock pin support is located at rotationally by described rotating disk, described motor is for driving described dial rotation, described rotating disk comprises multiple lock pin locking pin, when described dial rotation, described lock pin locking pin is periodically through described lock pin support, when described lock pin support there being ceramic insertion core, described lock pin locking pin can insert in the lock pin hole of described ceramic insertion core, thus ceramic insertion core described in described driven by rotary disc rotates, the opposite side of described rotating disk is located at by described second discharge nozzle, the described ceramic insertion core fallen from described rotating disk is made to fall into described second discharge nozzle.

6. discharge device according to claim 5, is characterized in that, described feed pipe is the plastic pipe with certain deformability.

7. discharge device according to claim 5, it is characterized in that, described module of swinging to also comprises transmission bracket, described transmission bracket comprises a rocking bar and a driving lever, described rotating disk comprises a rotating shaft and multiple fixture block, each described fixture block is corresponding with each described lock pin locking pin, described rocking bar one end is connected with the output shaft of described motor, the middle part of the other end and described driving lever is hinged, the front end of described driving lever forms Y shaped bracket, described fixture block on described rotating disk is suitable for the Y shaped bracket snapping in described driving lever, the rear end of described driving lever has a slide rail, described rotating shaft is through the slide rail of described driving lever, when described rocking bar moves in a circle under the drive of described motor, described driving lever rotates along a circular arc under the drive of described rocking bar and under the restriction of described rotating shaft, move up and down simultaneously, the Y shaped bracket of described driving lever is separated or clamping successively with each described fixture block on described rotating disk, thus stir described dial rotation.