CN221499483U - Glass fiber pipe discharging mechanism - Google Patents

Abstract

The utility model relates to the technical field of cigarette bullet assembly, in particular to a glass fiber tube discharging mechanism. The glass fiber tube discharging mechanism comprises a vibrating disc, a bottom frame, a feeding track and a turnover assembly which are arranged on a main frame; the underframe is arranged at the front side of the vibration disc; the feeding rail is arranged at the top of the underframe, a feeding channel is arranged in the feeding rail, and one end of the feeding rail extends into the vibration disc; the overturning assembly is arranged on the front side of the underframe and comprises an upper bracket, a storage seat and an overturning seat which are arranged on the main frame; the storage seat is fixedly connected to the bracket, a storage hole is formed in the middle of the storage seat, the other end of the feeding track extends to the rear side of the storage seat, and the feeding channel is communicated with the storage hole; a limiting part capable of limiting the glass fiber tube in the storage hole to move is arranged on the bracket; the turnover seat is arranged at the front side of the material storage seat, two ends of the turnover seat respectively rotate with the bracket, and a plurality of material placing grooves are formed in the turnover seat; the bracket is provided with a driving part for driving the turnover seat to rotate. The utility model solves the problem of low production efficiency of the existing cigarette bullet.

Description

Glass fiber pipe discharging mechanism

Technical Field

The utility model relates to the technical field of cigarette bullet assembly, in particular to a glass fiber tube discharging mechanism.

Background

The electronic cigarette bullet is a simple finished product atomizer, is a disposable consumable product, and has the advantages of no oil leakage, small size and convenient use. The electronic cigarette cartridge mainly comprises an oil cup, a glass fiber tube and a silica gel cover.

In the prior art, no effective feeding device can be used for arranging and feeding glass fiber tubes, so that the glass fiber tubes and oil cups cannot be automatically assembled by matching with a manipulator or other feeding devices, and only the glass fiber tubes and the oil cups can be assembled manually, so that the production efficiency is low.

Therefore, there is a need to provide a solution to the above-mentioned problems.

Disclosure of utility model

The utility model provides a glass fiber tube discharging mechanism, which aims to solve the problem that the production efficiency is low because no effective glass fiber tube feeding device exists in the prior art, and further, the assembly of a glass fiber tube and an oil cup can only be carried out manually.

In order to achieve the above purpose, the utility model provides a glass fiber tube discharging mechanism, which comprises a vibrating disc, a bottom frame, a feeding track and a turnover assembly which are arranged on a main frame; wherein:

The vibration disk is arranged on the main frame; the underframe is arranged on the front side of the vibration disc and is arranged on the main frame; the feeding rail is arranged at the top of the underframe, a feeding channel is arranged in the feeding rail, and one end of the feeding rail extends into the vibration disc; the overturning assembly is arranged on the front side of the underframe and comprises a bracket, a storage seat and an overturning seat; the bracket is arranged on the main frame; the storage seat is fixedly connected to the bracket, a storage hole is formed in the middle of the storage seat, the other end of the feeding track extends to the rear side of the storage seat, and the feeding channel is communicated with the storage hole; a limiting part capable of limiting the glass fiber tube in the storage hole to move is arranged on the bracket; the overturning seat is arranged at the front side of the storage seat, two ends of the overturning seat are respectively connected with the bracket in a rotating way, and a plurality of storage tanks are arranged at positions corresponding to the storage holes of the overturning seat; the support is provided with a driving part for driving the overturning seat to rotate.

More specifically, the storage seat is provided with a detection hole which is formed in the side wall of the storage groove and penetrates through the overturning seat outwards, the outer side of the detection hole is provided with a first sensor, the overturning seat is provided with a fixing sheet, and the first sensor is fixedly connected to the fixing sheet.

More specifically, the outside of first sensor is equipped with and is used for detecting whether put the glass fiber tube length in the silo up to standard second sensor, the second sensor is installed on the stationary blade.

More specifically, the limiting component comprises a limiting frame and a first cylinder; the limiting frame is arranged above the storage seat, and the first air cylinder is arranged on the bracket and used for driving the limiting frame to lift and slide; the top of the storage seat is provided with an extending hole which is downwards communicated with the storage hole; and a limiting rod is arranged at the bottom of the limiting frame at the position corresponding to the extending hole.

More specifically, the bottom of the limiting frame is fixedly connected with a guide column, and the storage seat is provided with a guide hole matched with the guide column; the guide post is connected in the guide hole in a sliding way.

More specifically, the driving component comprises a second cylinder, a transmission rack and a transmission gear; the second cylinder is arranged on the bracket; the transmission rack is connected to the bracket in a sliding way, and is driven by the second cylinder to lift and slide; the transmission gear is arranged at one end of the overturning seat, which is close to the transmission rack, and is in transmission fit with the transmission rack.

More specifically, the one end that the upset seat kept away from drive gear installs spacing, the support is in the outside of spacing is equipped with and is used for restricting spacing range of motion is not more than 90 degrees two limit stops.

More specifically, the overturning seat is provided with a guide chamfer at the opening of the material placing groove.

The glass fiber tube discharging mechanism has the technical effects that:

According to the application, the glass fiber tubes are subjected to vibration feeding by the vibration disc, so that the glass fiber tubes are orderly distributed and conveyed forwards along the feeding channel, when the glass fiber tubes pass through the storage holes and enter the material placing channel, the limiting part controls the glass fiber tubes in the storage holes to stop moving, and the driving part drives the storage seat to rotate, so that the glass fiber tubes are changed from a horizontal state to a vertical state, and the glass fiber tubes are conveniently clamped and driven by the externally arranged material taking mechanism. The continuous material loading of fine pipe of glass has been realized in this fine pipe discharge mechanism's of glass design, and makes the fine pipe of glass that is the horizontal form and carry can overturn to being vertical form through the design of upset subassembly, and then fine pipe extracting mechanism of glass can effectually press from both sides fine pipe of glass and get to this reduces the cost of labor, improves production efficiency.

Drawings

FIG. 1 is a schematic view of a glass fiber tube assembly apparatus;

FIG. 2 is a schematic view of a turnover assembly in a glass fiber tube assembly device;

FIG. 3 is an enlarged schematic view of FIG. 2 at A;

FIG. 4 is a schematic view of a structure of a turnover assembly of a glass fiber tube assembly device from another view;

FIG. 5 is an enlarged schematic view at B in FIG. 4;

FIG. 6 is a schematic view of a glass fiber tube take-off mechanism in a glass fiber tube assembly device;

FIG. 7 is a schematic view of a clamping assembly in a glass fiber tube assembly device;

FIG. 8 is a schematic view of a guide assembly in a glass fiber tube assembly apparatus;

Fig. 9 is a partial schematic view of an oil cup placement mechanism in a glass fiber tube assembly apparatus.

The marks in the figure:

1-a glass fiber tube discharging mechanism; 2-a glass fiber tube material taking mechanism; 3-an oil cup placement mechanism; 4-a glass fiber tube press-fitting mechanism;

11-a vibrating plate; 12-underframe; 13-a feeding track; 14-turning over the assembly; 141-a bracket; 142-a storage seat; 1421—a storage hole; 1422-an access hole; 143-a turnover seat; 1431-a material placing groove; 1432—a detection hole; 1433—a first sensor; 1434-a fixing piece; 1435-a second sensor; 144-a limiting component; 1441-a limiting frame; 1442—a first cylinder; 1443—a guide post; 1444-a stop lever; 145-a drive member; 1451-a second cylinder; 1452-a drive rack; 1453-a drive gear; 1454-limit bar; 1455-limit stops;

21-a mounting rack; 22-a distance adjusting component; 221-a first rail; 222-a first slider; 223-a distance adjusting frame; 224-third cylinder; 23-a lifting assembly; 231-a first electric slipway; 232-lifting seat; 24-clamping components; 241—finger cylinder; 242-clamping block; 25-a guide assembly; 251-strip plate; 252—a guide block; 2521-a tapered slot; 2522—a plug-in hole; 253—a control component; 2531—a second rail; 2532-a second slider; 2533—a control board; 2534—a fourth cylinder;

31-a second electric slipway; 32-a placing frame; 321-a baffle; 322-tabletting; 323-fixed block; 33-a material placing plate; 331-a positioning groove; 332-stop groove; 34-a stop assembly; 341-a fifth cylinder; 342-stop block;

41-a slipway cylinder; 42-a material pressing frame; 43-a material pressing plate; 44-a material pressing rod;

Detailed Description

The present utility model will be described in further detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present utility model more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.

It will be understood that when an element is referred to as being "fixed" or "disposed" on another element, it can be directly on the other element or intervening elements may also be present; when an element is referred to as being "connected to" another element, it can be directly connected to the other element or intervening elements may also be present.

Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include one or more such feature. In the description of the present invention, the meaning of "a plurality" is two or more, unless explicitly defined otherwise.

In the description of the embodiments of the present invention, it should be understood that the directions or positional relationships indicated by "upper", "lower", "front", "rear", "left", "right", "top", "bottom", "inner", "outer", etc. are based on the directions or positional relationships shown in the drawings, are merely for convenience in describing the embodiments of the present invention and to simplify the description, and do not indicate or imply that the devices 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 invention.

In order to more clearly illustrate the technical solution of the present invention, a preferred embodiment is provided below, and referring specifically to fig. 1 to 9, a glass fiber tube assembling device includes a glass fiber tube discharging mechanism 1, a glass fiber tube extracting mechanism 2, an oil cup placing mechanism 3 and a glass fiber tube pressing mechanism 4 disposed on a main frame (shown in the drawings), wherein:

The glass fiber tube discharging mechanism 1 comprises a vibration disc 11, a bottom frame 12, a feeding track 13 and a turnover assembly 14; the vibration plate 11 is mounted on the main frame; the underframe 12 is arranged on the front side of the vibration disc 11 and is arranged on the main frame; the feeding track 13 is arranged at the top of the underframe 12, a feeding channel is arranged in the feeding track, and one end of the feeding track 13 extends into the vibration disc 11; the turnover assembly 14 is arranged on the front side of the chassis 12 and comprises a bracket 141, a storage seat 142 and a turnover seat 143; the bracket 141 is mounted on the main frame; the material storage seat 142 is fixedly connected to the bracket 141, a material storage hole 1421 is formed in the material storage seat 142, the front side and the rear side of the material storage hole 1421 penetrate through the material storage seat 142, the other end of the feeding track 13 extends to the rear side of the material storage seat 142, and the feeding channel is communicated with the material storage hole 1421; a limiting component 144 which can limit the glass fiber tube in the storage hole 1421 to move is arranged on the bracket 141; the overturning seat 143 is arranged at the front side of the material storage seat 142, two ends of the overturning seat 143 are respectively connected with the bracket 141 in a rotating way, and a plurality of material placing grooves 1431 are formed in the overturning seat 143 at positions corresponding to the material storage holes 1421; the bracket 141 is mounted with a driving part 145 for driving the flip seat 143 to rotate.

The working process of the glass fiber tube discharging mechanism 1 is as follows: a large amount of glass fiber tube raw materials are placed in the vibration disc 11, after the vibration disc 11 is started, the glass fiber tube continuously enters the feeding groove under the vibration effect and is conveyed forwards along the feeding groove, at the moment, the glass fiber tube is horizontally placed in the feeding groove, when the glass fiber tube passes through the storage hole 1421 and enters the storage groove 1431, the limiting component 144 controls the glass fiber tube in the storage hole 1421 to stop moving, the driving component 145 drives the storage seat 142 to rotate by 90 degrees, so that the glass fiber tube is changed from the horizontal state to the vertical state, and the follow-up glass fiber tube taking mechanism 2 is convenient to clamp and drive. The continuous material loading of fine pipe of glass has been realized in this fine pipe discharge mechanism 1's of glass design, and makes the fine pipe of glass that is the horizontal form and carry can overturn to being vertical form through the design of upset subassembly 14, and then fine pipe feeding mechanism 2 of glass can effectually press from both sides fine pipe of glass and get to this reduces the cost of labor, improves production efficiency.

As a preferred solution of this embodiment, the material storage seat 142 is provided with a detection hole 1432 formed from the side wall of the material storage groove 1431 to penetrate the overturning seat 143, a first sensor 1433 is disposed at the outer side of the detection hole 1432, a fixing piece 1434 is mounted on the overturning seat 143, and the first sensor 1433 is fixedly connected to the fixing piece 1434. The first sensor 1433 is configured to detect whether the glass fiber tube in the material placing groove 1431 is accurately conveyed into the material placing groove 1431, so as to avoid the situation that the glass fiber tube is not placed in the material placing groove 1431 due to abnormal conveyance of the glass fiber tube, and then the subsequent glass fiber tube taking mechanism 2 is empty, and the glass fiber tube is not placed in the oil cup.

As a preferable solution of this embodiment, a second sensor 1435 for detecting whether the glass fiber tube length in the material placing groove 1431 meets the standard is disposed on the outer side of the first sensor 1433, and the second sensor 1435 is mounted on the fixing piece 1434. After the overturning seat 143 overturns, the glass fiber tube falls to contact with the bottom of the material placing groove 1431, at this time, the second sensor 1435 detects the top of the glass fiber tube, if the second sensor 1435 does not detect the glass fiber tube, the glass fiber tube is proved to be insufficient in length, and then the glass fiber tube taking mechanism 2 is controlled to stop clamping, so that the quality of produced cigarettes is prevented from being up to standard.

As a preferred embodiment of the present embodiment, the limiting member 144 includes a limiting frame 1441, a first cylinder 1442, and a guiding post 1443; the limiting frame 1441 is disposed above the material storage seat 142, and the first cylinder 1442 is mounted on the bracket 141 and is configured to drive the limiting frame 1441 to slide up and down; the guiding post 1443 is mounted at the bottom of the limiting frame 1441, and a guiding hole matched with the guiding post 1443 is formed in the material storage seat 142; the guiding post 1443 is slidably connected in the guiding hole, and an extending hole 1422 that is opened downward to be communicated with the storing hole 1421 is provided at the top of the storing seat 142; the bottom of the limiting frame 1441 is provided with a limiting rod 1444 at a position corresponding to the extending hole 1422. When the first cylinder 1442 drives the limiting frame 1441 to move downward, the limiting rod 1444 extends into the extending hole 1422 and compresses the glass fiber tube in the storage hole 1421, so as to prevent the glass fiber tube in the storage hole 1421 from continuously moving forward when the turnover seat 143 is driven to turn by the driving component 145, so that the glass fiber tube in the storage hole 1421 cannot enter the material placing groove 1431 when the turnover seat 143 returns.

As a preferred version of the present embodiment, the driving part 145 includes a second cylinder 1451, a driving rack 1452 and a driving gear 1453; the second cylinder 1451 is installed on the bracket 141; the transmission rack 1452 is slidably connected to the bracket 141, and is driven by the second cylinder 1451 to lift and slide; the transmission gear 1453 is mounted at one end of the turnover seat 143 near the transmission rack 1452, and is in transmission fit with the transmission rack 1452. Under the cooperation of the driving rack 1452 and the driving gear 1453, when the second cylinder 1451 drives the driving rack 1452 to move upwards, the driving gear 1453 rotates to drive the overturning seat 143 to overturn, so that the horizontally placed glass fiber tube input into the material placing groove 1431 is overturned to be in a vertical state.

Preferably, a protective cover is mounted on the bracket 141, and the protective cover is disposed outside the transmission rack 1452 and the transmission gear 1453.

Further, a stop 1454 is mounted at one end of the turning seat 143 away from the transmission gear 1453, and two stop blocks 1455 are disposed on the outer side of the stop 1454 of the bracket 141. The cooperation of the limit stop 1455 and the limit stop 1454 limits the overturning seat 143 to only 90 degrees of overturning, so as to ensure that the glass fiber tube is in a vertical state after the overturning seat 143 drives the glass fiber tube to overturn, thereby facilitating the subsequent glass fiber tube inserting work.

As a preferable solution of this embodiment, the overturning seat 143 is provided with a guiding chamfer at the opening of the material placing groove 1431. The design of the guide chamfer ensures that the glass fiber tube can smoothly enter the material placing groove 1431.

Preferably, in this embodiment, two vibration trays 11 are provided, six feeding rails 13 are provided, and three feeding rails 13 are correspondingly provided in each vibration tray 11, so that feeding of three glass fiber tubes is simultaneously achieved for each vibration tray 11. Correspondingly, six storage holes 1421 and six storage grooves 1431 are respectively formed.

The glass fiber tube taking mechanism 2 comprises a mounting frame 21, a distance adjusting assembly 22, a lifting assembly 23, a clamping assembly 24 and a guiding assembly 25; wherein:

The mounting frame 21 is mounted on the main frame.

The distance adjusting assembly 22 is arranged above the turnover assembly 14, and comprises a first guide rail 221, a first sliding block 222, a distance adjusting frame 223 and a third cylinder 224; the first guide rail 221 is fixedly connected to the mounting rack 21, and the first slider 222 is slidably connected to the first guide rail 221, and can slide back and forth along the first guide rail 221; the distance adjusting frame 223 is mounted on the first slider 222; the third cylinder 224 is mounted on the mounting frame 21, and its output end is fixedly connected with the distance adjusting frame 223.

The lifting assembly 23 comprises a first electric sliding table 231 and a lifting seat 232; the first electric sliding table 231 is arranged above the turnover assembly 14 and is arranged on the distance adjusting frame 223; the lifting seat 232 is mounted on the output end of the first electric sliding table 231, and is driven by the first electric sliding table 231 to lift and slide.

The clamping assembly 24 comprises a finger cylinder 241; the finger cylinder 241 is mounted on the lifting seat 232, and two output pieces of the finger cylinder 241 are fixedly connected with clamping blocks 242 respectively.

The guide assembly 25 is disposed at the front side of the turnover assembly 14, and includes a strip plate 251, a guide block 252 and a control member 253; the strip plate 251 is located below the clamping assembly 24, two control parts 253 are respectively arranged on two sides of the strip plate 251 and are mounted on the mounting frame 21, the two control parts are used for driving the strip plate 251 to lift and slide, the control parts 253 comprise a second guide rail 2531, a second sliding block 2532, a control plate 2533 and a fourth air cylinder 2534, the second guide rail 2531 is fixedly connected to the mounting frame 21, the second sliding block 2532 is slidingly connected to the second guide rail 2531, the control plate 2533 can lift and slide along the second guide rail 2531, the control plate 2533 is mounted on the second sliding block 2532, two ends of the strip plate 251 are respectively fixedly connected with the two control plates 2533, and the fourth air cylinder 2534 is mounted on the mounting frame 21 and is used for driving the control plate 2533 to lift and slide. The guide block 252 is correspondingly arranged below the finger cylinder 241 and is mounted on the strip plate 251, a conical groove 2521 is formed in the top of the guide block 252, and an inserting hole 2522 which is formed downwards and penetrates through the guide block 252 is formed in the middle of the conical groove 2521.

Preferably, the bottom of the guide block 25 is provided with a plug-in portion, and the diameter of the plug-in portion gradually decreases from top to bottom, so that when the control member 253 drives the strip plate 251 to descend, the plug-in portion can extend into the top of the oil cup to be positioned, and the plug-in hole 2522 is aligned with the mounting hole inside the oil cup.

Preferably, six finger cylinders 241 are provided corresponding to the material placing grooves 1431; six guide blocks 252 are arranged corresponding to the finger cylinder 241.

The oil cup placing mechanism 3 is arranged below the guide assembly 25 and comprises a second electric sliding table 31, a placing frame 32 and a placing plate 33; the second electric sliding table 31 is installed on the main frame; the placing frame 32 is installed on the output end of the second electric sliding table 31, and is driven by the second electric sliding table 31 to slide back and forth, and two front-back arranged baffles 321 are installed at the top of the placing frame 32; the material placing plate 33 is disposed on the placement frame 32, the front and rear sides of the material placing plate are respectively contacted with the two baffles 321, a positioning groove group is disposed at the top of the material placing plate 33, and the positioning groove group is correspondingly disposed below the guide block 252, and includes a plurality of positioning grooves 331 arranged in an array from front to back.

Preferably, in this embodiment, six positioning groove groups are provided corresponding to the guide blocks 252.

As a preferable solution of this embodiment, a stop assembly 34 is disposed on either side of the material placing plate 33, the stop assembly 34 includes a fifth cylinder 341 and a stop block 342, the fifth cylinder 341 is fixedly connected to the main frame, the stop block 342 is fixedly connected to an output end of the fifth cylinder 341, and the stop block is driven by the fifth cylinder to lift and slide. Preferably, the material placing plate 33 is provided with a stop groove 332 adapted to the stop block 342. Specifically, an oil cup is manually placed in the positioning groove 331 at the top of the material placing plate 33, and then the material placing plate 33 is pushed onto the placement frame 32 from a side end by matching with a transmission belt or other conveying components, and under the action of the stop block 342, the placement position of the material placing plate 33 can be limited, so that the position of the oil cup corresponds to the position of the finger cylinder 241, and the normal operation of the subsequent glass fiber tube loading operation is ensured, and after the glass fiber tube loading operation is completed on the material placing plate 33, the sliding table cylinder 41 drives the stop block 342 to move downwards, and then the material placing plate 33 can be output outwards from the other side.

As a preferred solution of this embodiment, the retaining plate 321 is slidably connected with a pressing plate 322, one end of the pressing plate 322 is in contact with the material placing plate 33, the other end of the pressing plate 322 is fixedly connected with a spring, a fixed block 323 is disposed on one side of the pressing plate 322 away from the material placing plate 33, the fixed block 323 is fixedly connected to the retaining plate 321, and the other end of the spring is fixedly connected with the fixed block 323. Under the action of the spring, the pressing piece 322 generates a pressing force on the material placing plate 33, so that when the second electric sliding table 31 drives the placing frame 32 to move forwards and backwards, the material placing plate 33 cannot deviate in the left-right direction.

Preferably, the pressing sheet 322 is provided with chamfers on two sides near one end of the material placing plate 33, so that when the material placing plate 33 is inserted, the material placing plate 33 can press the pressing sheet 322 to slide outwards under the action of the chamfers, and the position of the pressing sheet 322 is not required to be manually adjusted, so that convenience is improved.

The glass fiber tube press-mounting mechanism 4 comprises a sliding table cylinder 41, a press rack 42 and a press plate 43; the sliding table cylinder 41 is installed on the lifting seat 232; the material pressing frame 42 is arranged at the output end of the sliding table cylinder 41, and is driven by the sliding table cylinder 41 to lift and slide; the pressing plate 43 is disposed below the finger cylinder 241, between the two clamping blocks 242, and mounted on the pressing frame 42; a pressing rod 44 is arranged at the bottom of the pressing plate 43 at a position corresponding to the finger cylinder 241; the bottoms of the finger cylinders 241 are respectively provided with a avoidance hole corresponding to the material pressing rod 44 on the opposite surfaces of the two material clamping blocks 242.

Preferably, in this embodiment, six pressing rods 44 are provided corresponding to the finger cylinder 241.

The glass fiber tube assembly process comprises the following steps: the third cylinder 224 drives the distance adjusting frame 223 to slide along the first guide rail 221, so that the material clamping assembly 24 slides to the position right above the overturning assembly 14, then the first electric sliding table 231 drives the lifting seat to slide downwards until the two material clamping assemblies 242 are positioned at the front side and the rear side of a glass fiber tube mounting hole in the overturning assembly 14, the finger cylinder 241 drives the two material clamping assemblies 242 to retract, clamps a glass fiber tube above the overturning assembly 14, the second electric sliding table 31 drives the positioning groove 331 positioned at the rearmost side in the positioning groove group to move to the position right below the guide block 252, then the control part 253 drives the strip plate 251 to move downwards, so that the guide block 252 is pressed at the top of the glass fiber cup, the insertion hole 2522 is positioned right above the mounting hole of the glass fiber tube in the glass fiber cup, then the distance adjusting assembly 22 and the lifting assembly 23 are controlled downwards, the material clamping assembly 24 clamps the glass fiber tube positioned above the overturning assembly 14, the guide block 252 is driven to move downwards, the two material clamping assemblies 252 are driven downwards, the two glass fiber tube mounting holes are completely along the guide block 252, the insertion hole 2522 is completely inserted into the glass fiber tube mounting hole in the glass fiber tube, and the glass tube is completely inserted into the glass tube mounting hole 2522, and the glass fiber tube is completely inserted into the guide hole 2522, and the glass tube is completely inserted into the guide hole is pressed into the glass tube, and the glass tube is completely. In this process, the second electric sliding table 31 continuously drives the placement frame 32 to move backward, so that the plurality of oil cups arranged in an array on the placement plate 33 sequentially perform glass fiber tube assembly work.

The utility model relates to a glass fiber tube discharging mechanism, which solves the problem that the production efficiency is low because no effective glass fiber tube feeding device exists in the prior art and the assembly of a glass fiber tube and an oil cup can only be carried out manually through reasonable structural arrangement.

The above-mentioned embodiments of the present utility model are not limited to the above-mentioned embodiments, but can be modified, equivalent, and improved within the spirit and principle of the present utility model, and the present utility model is also included in the scope of the present utility model.

Claims (8)

1. The utility model provides a fine pipe discharge mechanism of glass, its characterized in that: comprises a vibrating disc, a bottom frame, a feeding track and a turnover assembly which are arranged on a main frame; wherein:

The vibration disk is arranged on the main frame; the underframe is arranged on the front side of the vibration disc and is arranged on the main frame; the feeding rail is arranged at the top of the underframe, a feeding channel is arranged in the feeding rail, and one end of the feeding rail extends into the vibration disc; the overturning assembly is arranged on the front side of the underframe and comprises a bracket, a storage seat and an overturning seat; the bracket is arranged on the main frame; the storage seat is fixedly connected to the bracket, a storage hole is formed in the middle of the storage seat, the other end of the feeding track extends to the rear side of the storage seat, and the feeding channel is communicated with the storage hole; a limiting part capable of limiting the glass fiber tube in the storage hole to move is arranged on the bracket; the overturning seat is arranged at the front side of the storage seat, two ends of the overturning seat are respectively connected with the bracket in a rotating way, and a plurality of storage tanks are arranged at positions corresponding to the storage holes of the overturning seat; the support is provided with a driving part for driving the overturning seat to rotate.

2. A glass fiber tube discharging mechanism according to claim 1, wherein: the material storage seat is provided with a detection hole which is formed in the side wall of the material storage groove and penetrates through the overturning seat outwards, a first sensor is arranged on the outer side of the detection hole, the overturning seat is provided with a fixing sheet, and the first sensor is fixedly connected to the fixing sheet.

3. A glass fiber tube discharging mechanism according to claim 2, wherein: the outside of first sensor is equipped with and is used for detecting whether glass fiber pipe length in the putting groove is up to standard second sensor, the second sensor is installed on the stationary blade.

4. A glass fiber tube discharging mechanism according to claim 1, wherein: the limiting component comprises a limiting frame and a first cylinder; the limiting frame is arranged above the storage seat, and the first air cylinder is arranged on the bracket and used for driving the limiting frame to lift and slide; the top of the storage seat is provided with an extending hole which is downwards communicated with the storage hole; and a limiting rod is arranged at the bottom of the limiting frame at the position corresponding to the extending hole.

5. The glass fiber tube discharging mechanism according to claim 4, wherein: the bottom of the limiting frame is fixedly connected with a guide column, and a guide hole matched with the guide column is formed in the storage seat; the guide post is connected in the guide hole in a sliding way.

6. A glass fiber tube discharging mechanism according to claim 1, wherein: the driving part comprises a second cylinder, a transmission rack and a transmission gear; the second cylinder is arranged on the bracket; the transmission rack is connected to the bracket in a sliding way, and is driven by the second cylinder to lift and slide; the transmission gear is arranged at one end of the overturning seat, which is close to the transmission rack, and is in transmission fit with the transmission rack.

7. The glass fiber tube discharging mechanism according to claim 6, wherein: the turnover seat is far away from one end of the transmission gear and is provided with a limit bar, and the support is provided with two limit stops which are used for limiting the movement range of the limit bar to be not more than 90 degrees at the outer side of the limit bar.

8. A glass fiber tube discharging mechanism according to claim 1, wherein: the overturning seat is provided with a guide chamfer at the opening of the material placing groove.