CN219173574U

CN219173574U - Flat-mouth ceramic tube feeding mechanism

Info

Publication number: CN219173574U
Application number: CN202122571710.8U
Authority: CN
Inventors: 苏毅镇
Original assignee: Hollyland Xiamen Circuit Protection Technology Co ltd
Current assignee: Hollyland Xiamen Circuit Protection Technology Co ltd
Priority date: 2021-10-25
Filing date: 2021-10-25
Publication date: 2023-06-13
Anticipated expiration: 2031-10-25

Abstract

The utility model discloses a flat-mouth ceramic tube feeding mechanism which comprises a discharging device, a feeding clamping jaw, a rotary cylinder and a sliding cylinder, wherein the clamping jaw of the feeding clamping jaw is connected to the discharging end of the discharging device and is used for clamping or releasing a flat-mouth ceramic tube output by the discharging end, the rotary cylinder is connected with the feeding clamping jaw, the sliding cylinder is connected with the rotary cylinder, the sliding cylinder drives the rotary cylinder and the feeding clamping jaw to slide, and simultaneously the feeding clamping jaw is driven to rotate by being matched with the rotation of the rotary cylinder, so that the flat-mouth ceramic tube can be fed to the next production procedure from the discharging end. Through discharging device's discharge end combination material loading clamping jaw's setting, the stable accurate material loading operation of completion that can automize to do benefit to and link up next production process department, improve automated production's efficiency, have simple structure, reliable and stable, reduce cost's advantage.

Description

Flat-mouth ceramic tube feeding mechanism

Technical Field

The utility model relates to the field of automation equipment, in particular to a flat-mouth ceramic tube feeding mechanism.

Background

The ceramic tube is commonly used for manufacturing fuses, has better explosion-proof performance relative to glass fuses, is not easy to break, has good heat dissipation, can pass larger current, and has the effects of cooling and arc extinction.

In the current production process of ceramic tube fuses, the feeding operation of flat ceramic tubes often needs manual feeding, which consumes labor cost and has low efficiency, so that the smooth operation of the next production process is affected, and improvement is needed.

Disclosure of Invention

The utility model aims to provide a flat-mouth ceramic tube feeding mechanism which can overcome the defects of low efficiency and high cost of the existing manual feeding and has the advantages of simple structure, stability, reliability and capability of improving the production efficiency.

In order to achieve the above object, the solution of the present utility model is:

the flat-mouth ceramic tube feeding mechanism comprises a discharging device, a feeding clamping jaw, a rotary cylinder and a sliding cylinder, wherein the clamping jaw of the feeding clamping jaw is connected to the discharging end of the discharging device and is used for clamping or releasing a flat-mouth ceramic tube output by the discharging end, the rotary cylinder is connected with the feeding clamping jaw, the sliding cylinder is connected with the rotary cylinder, the sliding cylinder drives the rotary cylinder and the feeding clamping jaw to slide, and meanwhile, the feeding clamping jaw is driven to rotate by being matched with the rotation of the rotary cylinder so as to feed the flat-mouth ceramic tube from the discharging end to the next production procedure;

preferably, the discharging device comprises a guide chute capable of enabling the flat-mouth ceramic tubes to be sequentially output side by side and a correction mechanism arranged on the guide chute, one end of the guide chute is a feeding end, the other end of the guide chute is a discharging end, the correction mechanism is positioned between the feeding end and the discharging end and comprises at least one correction gear disc and a driving motor for driving the correction gear disc to rotate, and the correction gear disc can drive planes of different flat-mouth ceramic tubes in the guide chute to rotate to a uniform orientation so as to ensure that the directions of the planes of the flat-mouth ceramic tubes discharged by the discharging end are consistent.

Preferably, the top of the guide chute is vertical the feed end, the bottom of the guide chute is horizontal the discharge end, an inclined part is obliquely arranged between the feed end and the discharge end, the upper part of the inclined part is connected with the feed end, a rotary side groove is arranged on the upper part of the inclined part, the width of the rotary side groove is larger than the widest part of the flat port end of the flat port ceramic tube, the lower part of the inclined part is connected with the discharge end, limit side grooves are arranged on the lower part of the inclined part and the two sides of the discharge end, the width of the limit side groove is smaller than the widest part of the flat port end of the flat port ceramic tube, the width of the limit side groove is larger than the narrowest part of the flat port end of the ceramic tube, the flat port ceramic tube can slide towards the discharge end from the feed end along the rotary side groove and the limit side groove of the inclined part under the action of self gravity, and the correction mechanism is arranged on the inclined part.

Preferably, at least one side between the upper part and the lower part of the inclined part is provided with a correction window for communicating the rotary side groove with the limit side groove, the correction gear disc of the correction structure is positioned at the correction window, teeth of the correction gear disc can extend into the correction window, and the teeth can rotate to stir the flat mouth end of the flat mouth ceramic tube to rotate, so that the plane rotation of the flat mouth ceramic tube is parallel to the bottom surface of the limit side groove.

Preferably, the driving motor is located at one side of the guide chute, and is pivoted at the top of the guide chute through a swing arm, and a spring ejector rod is arranged between the swing arm and the side surface of the guide chute, so that the correction gear disc connected with the driving motor can swing at the correction window movably, and the correction gear disc is prevented from being clamped in the correction process.

Preferably, the feeding end of the discharging device is provided with a guiding mechanism, the guiding mechanism comprises an input port, a guiding platform, a guiding block and a guiding air cylinder, the input port is communicated with the guiding platform, the guiding platform is connected with the inlet of the feeding end, the guiding block is provided with a positioning groove with an opening at the bottom and a side surface, the guiding air cylinder is arranged on one side of the guiding platform and used for driving the guiding block to slide between the guiding platform and the inlet of the feeding end, the opening of the positioning groove can be positioned at the input port so as to receive the flat-mouth ceramic tube input by the input port, and the flat-mouth ceramic tube in the positioning groove can be driven by the guiding air cylinder to slide out of the guiding platform and enter the inlet of the feeding end from the opening of the guiding groove.

Preferably, a feeding sensor is arranged at the feeding end of the discharging device and used for detecting the number of flat-mouth ceramic tubes at the feeding end so as to control the action of the guide cylinder and control the feeding speed.

Preferably, the discharging end is provided with a locking mechanism, the locking mechanism comprises a locking ejector rod and a locking cylinder, the locking ejector rod penetrates through the side face of the tail end of the discharging end, the locking ejector rod can be driven by the locking cylinder to stretch and lock a flat-mouth ceramic tube of the tail end of the discharging end, which is nearest to the outlet, so that the feeding speed of the feeding clamping jaw is matched, and the flat-mouth ceramic tube is controlled to be output to the clamping jaw of the feeding clamping jaw one by one from the discharging end.

Preferably, a discharge sensor is arranged below the outer side of the discharge end outlet and used for detecting whether the flat-mouth ceramic tube at the feeding clamping claw exists or not in the feeding process of the feeding clamping claw, and a control locking cylinder drives a locking ejector rod to lock or release the flat-mouth ceramic tube at the discharge end, so that the discharge end sequentially outputs the flat-mouth ceramic tubes one by one.

After the technical scheme is adopted, the flat-mouth ceramic tube feeding mechanism provided by the utility model has the advantages that the stable and accurate feeding operation can be automatically finished by combining the discharge end of the discharging device with the setting of the feeding clamping jaw, so that the next production procedure can be connected, the automatic production efficiency is improved, the structure is simple, the stability and the reliability are realized, the cost is reduced, and the like.

Drawings

FIG. 1 is a perspective view of a flat-mouth ceramic tube;

FIG. 2 is a perspective view of an embodiment of the present utility model;

FIG. 3 is another perspective view of an embodiment of the present utility model;

FIG. 4 is a side view of an embodiment of the present utility model;

FIG. 5 is a top view of an embodiment of the present utility model;

FIG. 6 is a cross-sectional view A-A of FIG. 5;

FIG. 7 is a perspective view of an inclined portion according to an embodiment of the present utility model;

FIG. 8 is a cross-sectional view B-B of FIG. 5;

FIG. 9 is a schematic diagram of a guide cylinder pushing a guide block to move according to an embodiment of the present utility model;

FIG. 10 is an exploded view of a guide mechanism according to an embodiment of the present utility model;

FIG. 11 is a schematic perspective view of a locking mechanism according to an embodiment of the present utility model;

fig. 12 to 13 are schematic diagrams of feeding operations according to embodiments of the present utility model.

Symbol description:

100. flat-mouth ceramic tube, 101. Flat-mouth end, 102. Plane,

1. the machine frame is provided with a machine frame,

2. the device comprises a discharging device, 20, a material guiding groove, 21, a feeding end, 22, a discharging end, 211, an inlet of the feeding end, 23, an inclined part, 231, an upper part of the inclined part, 232, a lower part of the inclined part 24, a rotary side groove, 25, a limit side groove, 251, a bottom surface,

3. the feeding clamping claw, 31, the clamping claw, 4, the rotary cylinder, 5, the sliding cylinder, 6, the sliding rail,

7. the correcting mechanism 71, the correcting gear disc 711, the tooth, 72, the driving motor 73, the swing arm 74, the spring ejector rod,

8. guide mechanism, 81, input port, 82, guide platform, 83, guide block, 84, guide cylinder, 85, positioning slot, 851, opening, 852,

9. locking mechanism, 91, locking ejector rod, 92, locking cylinder

10. The detection mechanism, 11, the feeding sensor, 12, the discharging sensor.

Detailed Description

In order to further explain the technical scheme of the utility model, the utility model is explained in detail by specific examples.

In the description of the present utility model, it should be understood that the terms "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are merely for convenience in describing the present utility model and simplifying the description, and do not indicate or imply that the apparatus or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present utility model.

As shown in fig. 1, the main body of the flat-mouth ceramic tube 100 is cylindrical, and two flat-mouth ends 101 each have two opposite flat surfaces 102 to form a flat mouth shape.

As shown in fig. 2 to 5, the utility model provides a flat-mouth ceramic tube feeding mechanism, which comprises a frame 1, a discharging device 2, a feeding clamping claw 3, a rotary cylinder 4 and a sliding cylinder 5, wherein a clamping claw 31 of the feeding clamping claw 3 is connected with a discharging end 22 of the discharging device 2 and is used for clamping or releasing a flat-mouth ceramic tube 100 output by the discharging end 22, the rotary cylinder 4 is slidably mounted on a sliding rail 6 on the frame 1 and is connected with the feeding clamping claw 3, the sliding cylinder 5 is arranged on the frame 1 and is connected with the rotary cylinder 4, the rotary cylinder 4 and the feeding clamping claw 3 can be driven by the sliding cylinder 5 to slide back and forth along the sliding rail 6, and meanwhile, the feeding clamping claw 3 is driven to rotate by being matched with the rotary cylinder 4 so as to feed the flat-mouth ceramic tube 100 from the discharging end 22 to the next production process (not shown).

As shown in fig. 3 and 6, the discharging device 2 includes a guide chute 20 capable of sequentially outputting the flat ceramic tubes 100 side by side, and a straightening mechanism 7 disposed on the guide chute 20, wherein the top of the guide chute 20 is a vertical feeding end 21, and the bottom is a horizontal discharging end 22;

referring to fig. 6 and 7, an inclined portion 23 is obliquely disposed between the feeding end 21 and the discharging end 22, an upper portion 231 of the inclined portion is connected to the feeding end 21, an upper portion 231 of the inclined portion is provided with a rotating side groove 24, a width D1 of the rotating side groove 24 is larger than a widest portion H1 of the flat ends ceramic tube 100, the two flat ends of the flat ends ceramic tube 100 can slide in the rotating side groove 24 in a rotating manner, a lower portion of the inclined portion 23 is connected to the discharging end 22, both sides of the lower portion of the inclined portion 23 and the discharging end 22 are provided with limiting side grooves 25, a width D2 of the limiting side groove 25 is smaller than a widest portion H1 of the flat ends ceramic tube 100, and is larger than a narrowest portion H2 of the flat ends of the ceramic tube, the flat ends 101 are parallel and attached to a bottom surface 251 of the limiting side groove 25, the flat ends can slide in the limiting side groove 25, the ceramic tube 100 can slide in the limiting side groove 25, and a correcting window 26 communicating the rotating side groove 24 and the limiting side groove 25 is disposed between the upper portion 231 and the lower portion 232, and the ceramic tube 20 can slide from the discharging end 20.

Referring to fig. 3, the straightening mechanism 7 includes two straightening gear plates 71 and a driving motor 72 for driving the straightening gear plates 71 to rotate, wherein the straightening gear plates 71 are respectively located at the straightening windows 26 of the inclined portion 23 between the feeding end 21 and the discharging end 22;

referring to fig. 6, the teeth 711 of the correcting gear disc 71 may extend into the correcting window 26, if the flat-mouth ceramic tube 100 is not clamped by the plane 102 parallel to the bottom surface 251 of the limiting side groove 25 and cannot enter the limiting side groove 25, the teeth 711 rotate to stir the flat-mouth end 101 of the flat-mouth ceramic tube 100, so that the plane 102 of the flat-mouth ceramic tube 100 rotates parallel to the bottom surface 251 of the limiting side groove 25, and then smoothly enters the limiting side groove 25 from the rotating side groove 24, so as to ensure that the planes 102 of the mouth ceramic tubes in the limiting side groove 25 are uniformly oriented, so as to ensure that the direction of the planes 102 of the flat-mouth ceramic tube 100 of the final bottom discharge end 22 is consistent, and the direction position of the planes 102 of the flat-mouth ceramic tube 100 from the clamping jaw 31 to the next production process is consistent after feeding;

referring to fig. 4, the driving motor 72 is located at one side of the guide chute 20, and is pivoted to the top of the guide chute 20 by a swing arm 73, and a spring push rod 74 is disposed between the swing arm 73 and the side surface of the guide chute 20, so that the correction gear disc 71 connected to the driving motor 72 can swing at the correction window 26 movably, so as to avoid the correction gear disc 71 being blocked during the correction process.

As shown in fig. 8 to 10, the feeding end 21 of the guide chute 20 may be provided with a guide mechanism 8, the guide mechanism 8 includes an input port 81, a guide platform 82, a guide block 83 and a guide cylinder 84, the input port 81 is communicated with the guide platform 82, the guide platform 82 is connected to the inlet 211 of the feeding end, the guide block 83 is provided with a bottom opening 851 and a positioning slot 85 with a side opening 852, the guide cylinder 84 is mounted on one side of the guide platform 82 and is used for driving the guide block 83 to slide between the guide platform 82 and the inlet 211 of the feeding end, the opening 852 of the positioning slot 85 is capable of being positioned at the input port 81 to receive the flat ceramic tube 100 input by the input port 81 (the input port 81 is capable of inputting the flat ceramic tube 100 by being connected to a vibration disc, which is not shown in a specific structure diagram, and is driven by the guide cylinder 84 to drive the flat ceramic tube 100 in the positioning slot 85 to slide out of the guide platform 82 and enter the inlet 211 of the feeding end from the opening 851 (see fig. 8).

The positioning groove 85 can keep the flat-mouth ceramic tube 100 parallel to the inlet 211 of the feeding end when feeding, so that the flat-mouth ceramic tube 100 can smoothly enter the feeding end 21, and the situation that the flat-mouth ceramic tube 100 is obliquely clamped when being directly input into the guide platform 82 from the input port 81, or the input port 81 is directly abutted against the feeding end 21 and is obliquely clamped when being input into the flat-mouth ceramic tube 100, and the like can be avoided.

As shown in fig. 11 and 2, the discharging end 22 may further be provided with a locking mechanism 9, which includes a locking ejector rod 91 and a locking cylinder 92, wherein the locking ejector rod 91 penetrates through a side surface of the end of the discharging end 22 and extends into the limit side groove 25, and the locking ejector rod 91 may be driven by the locking cylinder 92 to extend to lock a flat-mouth ceramic tube 100 of the end of the discharging end 22 nearest to the outlet, thereby matching the feeding speed of the feeding clamping jaw 3, and controlling the flat-mouth ceramic tubes 100 to be output from the discharging end 22 to the clamping jaw 31 of the feeding clamping jaw 3 one by one.

As shown in fig. 8, the guide chute 20 is provided with a detection mechanism 10, which includes a feed sensor 11 disposed at the junction of the upper portion 231 of the inclined portion and the feed end 21, and a discharge sensor 12 disposed below the outer side of the outlet of the discharge end 22.

The feeding sensor 11 is used for detecting the feeding end 21 and the flat-mouth ceramic tube 100 at the upper part 231 of the inclined part, and is used for controlling the guide cylinder 84 to operate, so that the feeding speed can be controlled, the blocking of the feeding end 21 can be avoided, and whether the correction mechanism 7 is successfully corrected or blocked can be detected according to the feeding speed, so that the abnormality can be found out in time, and the production efficiency can be improved; the discharge sensor 12 is located below the outer side of the outlet of the discharge end 22, that is, the clamping jaw 31 of the feeding clamping jaw 3 is located below the station of the outlet of the discharge end 22, after the clamping jaw 31 is detected to feed smoothly, the locking cylinder 92 is controlled to drive the locking ejector rod 91 to release the flat-mouth ceramic tube 100 at the discharge end 22, so that the discharge end 22 conveys a new flat-mouth ceramic tube 100 to the clamping jaw 31 of the feeding clamping jaw 3, and after the discharge sensor 12 detects that the clamping jaw 31 has a new flat-mouth ceramic tube 100, the locking cylinder 92 is controlled to drive the locking ejector rod 91 to lock the flat-mouth ceramic tube 100 at the discharge end 22, thereby sequentially enabling the discharge end 22 to output the flat-mouth ceramic tubes 100 one by one.

The working principle of the utility model is as follows, referring to fig. 2, the guide mechanism 8 at the top end of the guide chute 20 can smoothly feed the flat-mouth ceramic tube 100 into the feed end 21 of the guide chute 20, the flat-mouth ceramic tube 100 slides to the discharge end 22 at the bottom side by side in sequence at the top feed end 21 of the guide chute 20 under the action of gravity, the correction gear disc 71 of the correction mechanism 7 arranged on the guide chute corrects the flat-mouth end 101 of the flat-mouth ceramic tube 100 in the guide chute at the same time, so that the direction of the flat-mouth ceramic tube 100 output by the final discharge end 22 to the flat-mouth ceramic tube 100 of the feeding gripper 3 is consistent, the flat-mouth ceramic tube 100 output by the discharge end 22 is clamped by the feeding gripper 3, as shown in fig. 12, the rotary cylinder 4 drives the feeding gripper 3 to rotate 90 °, as shown in fig. 13, the rotary cylinder 4 and the feeding gripper 3 slide to feed the flat-mouth ceramic tube 100 clamped by the next production procedure, then the gripper 31 releases the flat-mouth ceramic tube 100, and then the feeding gripper 3 is retracted to the discharge end 22 for repeating the next feeding operation.

In summary, according to the flat-mouth ceramic tube feeding mechanism provided by the utility model, the flat-mouth ceramic tube 100 with the same direction as the plane 102 can be automatically output through the guide chute 20 and the correction mechanism 7, and meanwhile, the stable and accurate feeding operation can be automatically completed by combining with the arrangement of the feeding clamping jaw 3, so that the next production procedure can be connected, the defects of low manual feeding efficiency and high cost in the prior art can be overcome, the automatic production efficiency can be improved, and the feeding mechanism has the advantages of simple structure, stability, reliability and the like.

In the above description, the preferred embodiments of the present utility model are only described, and the scope of the present utility model is not limited by the above embodiments, for example, the guide chute of the present utility model is used for sliding conveying the flat-mouth ceramic tube by gravity, and of course, other transmission modes such as conveying belt can be used for conveying, and conveying effect and correcting effect can be achieved by matching with the correcting mechanism; equivalent changes and modifications are intended to be covered by the claims and the specification.

Claims

1. The utility model provides a flat mouthful of ceramic tube feed mechanism which characterized in that: the feeding clamping jaw is connected to the discharge end of the discharge device and used for clamping or releasing a flat-mouth ceramic tube output by the discharge end, the feeding clamping jaw is connected to the rotary cylinder, the rotary cylinder is connected to the sliding cylinder, the sliding cylinder drives the rotary cylinder and the feeding clamping jaw to slide, and meanwhile the rotary cylinder is matched to rotate to drive the feeding clamping jaw to rotate, so that the flat-mouth ceramic tube can be fed to the next production procedure from the discharge end.

2. The flat-mouth ceramic tube feeding mechanism according to claim 1, wherein: the discharging device comprises a guide chute capable of enabling flat-mouth ceramic tubes to be sequentially output side by side and a correction mechanism arranged on the guide chute, one end of the guide chute is a feeding end, the other end of the guide chute is a discharging end, the correction mechanism is positioned between the feeding end and the discharging end and comprises at least one correction gear disc and a driving motor for driving the correction gear disc to rotate, and the correction gear disc rotates to drive planes of different flat-mouth ceramic tubes in the guide chute to rotate to a uniform orientation so as to ensure that the directions of the planes of the flat-mouth ceramic tubes discharged by the discharging end are consistent.

3. The flat-mouth ceramic tube feeding mechanism according to claim 2, wherein: the top of the guide chute is vertical the feed end, the bottom of the guide chute is horizontal the discharge end, an inclined part is obliquely arranged between the feed end and the discharge end, the upper part of the inclined part is connected with the feed end, the upper part of the inclined part is provided with a rotary side groove, the width of the rotary side groove is larger than the widest part of the flat mouth end of the flat mouth ceramic pipe, the lower part of the inclined part is connected with the discharge end, both sides of the lower part of the inclined part and the discharge end are provided with limit side grooves, the width of the limit side groove is smaller than the widest part of the flat mouth end of the flat mouth ceramic pipe and larger than the narrowest part of the flat mouth end of the ceramic pipe, the flat mouth ceramic pipe can slide to the discharge end from the feed end along the rotary side groove and the limit side groove of the inclined part in the guide chute under the action of self gravity, and the correction mechanism is arranged on the inclined part.

4. A flat-mouth ceramic tube feeding mechanism according to claim 3, wherein: at least one side between the upper part and the lower part of the inclined part is provided with a correction window for communicating the rotary side groove with the limit side groove, a correction gear disc of the correction mechanism is positioned at the correction window, teeth of the correction gear disc can extend into the correction window, and the teeth rotate to stir the flat mouth end of the flat mouth ceramic tube to rotate, so that the plane rotation of the flat mouth ceramic tube is parallel to the bottom surface of the limit side groove.

5. The flat-mouth ceramic tube feeding mechanism according to claim 4, wherein: the driving motor is located on one side of the guide chute and pivoted to the top of the guide chute through a swing arm, and a spring ejector rod is arranged between the swing arm and the side face of the guide chute, so that the correction gear disc connected with the driving motor can swing movably at the correction window, and the correction gear disc is prevented from being clamped in the correction process.

6. The flat-mouth ceramic tube feeding mechanism according to claim 1, wherein: the feeding end of the discharging device is provided with a guide mechanism, the guide mechanism comprises an input port, a guide platform, a guide block and a guide cylinder, the input port is communicated with the guide platform, the guide platform is connected with the inlet of the feeding end, the guide block is provided with a positioning groove with an opening at the bottom and a side surface, the guide cylinder is arranged on one side of the guide platform and used for driving the guide block to slide between the guide platform and the inlet of the feeding end, the opening of the positioning groove can be positioned at the input port so as to receive the flat-mouth ceramic tube input by the input port, and the flat-mouth ceramic tube in the positioning groove can be driven by the guide cylinder to slide out of the guide platform and enter the inlet of the feeding end from the opening of the guide groove.

7. The flat-mouth ceramic tube feeding mechanism according to claim 6, wherein: and a feeding sensor is arranged at the feeding end of the discharging device and used for detecting the number of flat-mouth ceramic tubes at the feeding end so as to control the action of the guide cylinder and control the feeding speed.

8. The flat-mouth ceramic tube feeding mechanism according to claim 1, wherein: the discharge end is provided with a locking mechanism, the locking mechanism comprises a locking ejector rod and a locking cylinder, the locking ejector rod penetrates through the side face of the tail end of the discharge end, the locking ejector rod can be driven by the locking cylinder to stretch and lock a flat-mouth ceramic tube of the tail end of the discharge end, which is nearest to the outlet, so that the feeding speed of the feeding clamping jaw is matched, and the flat-mouth ceramic tube is controlled to be output to the clamping jaw of the feeding clamping jaw one by one from the discharge end.

9. The flat-mouth ceramic tube feeding mechanism according to claim 8, wherein: and a discharge sensor is arranged below the outer side of the discharge end outlet and used for detecting whether the flat-mouth ceramic tube at the feeding clamping claw exists or not in the feeding process of the feeding clamping claw, and a control locking cylinder drives a locking ejector rod to lock or release the flat-mouth ceramic tube at the discharge end, so that the discharge end sequentially outputs the flat-mouth ceramic tubes one by one.