CN115710083A

CN115710083A - Glass manages blocking device and glass manages production system

Info

Publication number: CN115710083A
Application number: CN202211493460.3A
Authority: CN
Inventors: 李博; 王刚; 薄昌盛; 刘彬; 董华伟; 孙昌
Original assignee: Tunghsu Technology Group Co Ltd; Gansu Xukang Material Technology Co Ltd
Current assignee: Tunghsu Technology Group Co Ltd; Gansu Xukang Material Technology Co Ltd
Priority date: 2022-11-25
Filing date: 2022-11-25
Publication date: 2023-02-24
Anticipated expiration: 2042-11-25
Also published as: CN115710083B

Abstract

The present disclosure relates to a glass tube blocking device and a glass tube production system, the glass tube blocking device includes: the supporting device is used for being arranged on a glass tube production line, the glass tube production line comprises a conveying device, a cutting device arranged on the conveying device and a crushing device arranged on the outer side of the conveying device, and the supporting device is used for being arranged between the cutting device and the crushing device; the blocking piece is arranged on one side of the supporting device, close to the cutting device, extends into the conveying device and is used for blocking the cut glass tube so that the glass tube falls on the conveying device, and the blocking piece can be arranged in an opening and closing mode so that the glass tube which is not cut off can enter the crushing device. The glass tube is blocked by the blocking piece after being cut by the cutting device, the glass tube is prevented from being separated from the conveying device under the action of inertia, and the blocking piece can be arranged in an openable and closable manner and used for opening the blocking piece to enter the crushing device when the glass tube is not cut off, so that the glass tube is prevented from being blocked at the blocking piece when being cut off continuously, and the subsequent treatment of the glass tube is prevented.

Description

Glass manages blocking device and glass manages production system

Technical Field

The disclosure relates to the technical field of glass production, in particular to a glass tube blocking device and a glass tube production system.

Background

In the production of the horizontal Danner tube, molten glass flow forms a preliminary glass tube root on a rotary tube in a muffle furnace, then the molten glass is drawn into a glass tube by a tractor, the glass tube is cut into a length convenient for packaging under the cutting of a glass tube cutting device and then falls on a conveying device to enter a next processing link, and the glass tube is quickly cut in the drawing process, so that the cut glass tube can continue to move along the original movement direction under the action of inertia, and can be separated from the conveying device, and the glass tube cannot well enter the next processing link.

Disclosure of Invention

An object of the present disclosure is to provide a glass tube blocking device and a glass tube production system, which can solve the above-mentioned problems.

In order to achieve the above object, the present disclosure provides a glass tube blocking device, including: the glass tube production line comprises a conveying device, a cutting device arranged on the conveying device and a crushing device arranged outside the conveying device, wherein the supporting device is arranged between the cutting device and the crushing device; the blocking piece is arranged on one side, close to the cutting device, of the supporting device and extends into the conveying device, and is used for blocking the cut glass tube so that the glass tube falls on the conveying device, and the blocking piece can be arranged in an opening and closing mode so that the glass tube which is not cut off can enter the crushing device.

Optionally, the blocking member comprises a baffle plate perpendicular to the conveying direction of the glass tube, one side of the baffle plate is hinged to the supporting device, and a channel is arranged on the supporting device, so that the baffle plate can be pushed open to enter the crushing device through the channel when the glass tube is not cut off.

Optionally, the supporting device comprises a height adjusting device, and the blocking member is connected with the height adjusting device to adjust the height of the blocking member.

Optionally, the height adjusting device includes a first sliding assembly, a first driving motor, a first lead screw connected to a driving end of the first driving motor, and a first nut sleeved on the first lead screw and connected to the first lead screw through a thread, the blocking member is connected to the first sliding assembly, the first lead screw is vertically disposed, and the first nut is connected to the first sliding assembly to drive the blocking member to move up and down.

Optionally, the first sliding assembly comprises two first guide rails, two first sliding blocks and a connecting plate, the two first guide rails are vertically arranged at intervals, each first guide rail is connected with one first sliding block in a sliding mode, the connecting plate is arranged between the two first sliding blocks, a through hole for the glass tube which is not cut off to pass through is formed in the connecting plate, the first screw is connected with the connecting plate, and the first lead screw is arranged on one side of the through hole.

Optionally, the first sliding block is disposed on one side of the first guide rail, which is close to the baffle, the blocking piece further comprises a connecting rod which is horizontally disposed, one end of the connecting rod is connected with the top of the connecting plate, the other end of the connecting rod is hinged to the top of the baffle so that the baffle can rotate up and down along the hinged end, and the length of the connecting rod is greater than the width of the baffle.

Optionally, the glass tube blocking device further comprises a horizontal adjusting device, and the supporting device is connected with the horizontal adjusting device so that the supporting device can move towards the direction close to or away from the conveying device.

Optionally, the horizontal adjusting device includes a second guide rail horizontally disposed, a second slider slidably connected to the second guide rail, a second driving motor, a second lead screw connected to a driving end of the second driving motor, and a second nut sleeved on the second lead screw and threadedly connected to the second lead screw, the supporting device is connected to the second slider, and the second nut is connected to the supporting device to drive the supporting device to move horizontally.

Optionally, a silica gel layer is arranged on one side of the baffle plate, which is close to the conveying device.

The present disclosure also provides a glass tube production system, comprising: the glass tube blocking device; and the glass tube production line is provided with the glass tube blocking device.

According to the technical scheme, the glass tube blocking device comprises a supporting device and a blocking piece, wherein the blocking piece is arranged on the supporting device, the supporting device is arranged between the cutting device and the crushing device, the glass tube is blocked by the blocking piece after being cut by the cutting device, the glass tube is prevented from being separated from the conveying device under the action of inertia, the blocking piece can be arranged in an opening and closing mode and used for opening the blocking piece to enter the crushing device when the glass tube is not cut off, and the glass tube is prevented from being blocked at the blocking piece when being cut off continuously to hinder the processing of the subsequent glass tube.

Additional features and advantages of the present disclosure will be set forth in the detailed description which follows.

Drawings

The accompanying drawings, which are included to provide a further understanding of the disclosure and are incorporated in and constitute a part of this specification, illustrate embodiments of the disclosure and together with the description serve to explain the disclosure, but do not constitute a limitation of the disclosure. In the drawings:

FIG. 1 is a schematic structural view of a glass tube production system according to the present disclosure;

FIG. 2 is a schematic front view of a glass tube block apparatus according to the present disclosure;

FIG. 3 is a schematic view of a backside structure of a glass tube blocking device according to the present disclosure;

fig. 4 is a side view of a baffle according to the present disclosure.

Description of the reference numerals

1. A glass tube production line; 2. a cutting device; 3. a glass tube blocking device; 31. a support device; 311. a channel; 32. a blocking member; 321. a baffle plate; 322. a connecting rod; 323. a silica gel layer; 33. a leveling device; 331. a second drive motor; 332. a second guide rail; 333. a second slider; 334. a second lead screw; 34. a height adjustment device; 341. a first sliding assembly; 3411. a first guide rail; 3412. a first slider; 3413. a connecting plate; 3414. a through hole; 342. a first drive motor; 343. a first lead screw; 344. a first screw nut; 4. a crushing device; 5. a conveying device; 6. a glass tube.

Detailed Description

The following detailed description of specific embodiments of the present disclosure is provided in connection with the accompanying drawings. It should be understood that the detailed description and specific examples, while indicating the present disclosure, are given by way of illustration and explanation only, not limitation.

In the present disclosure, unless otherwise specified, use of the terms of orientation such as "upper, lower, bottom, top" generally refer to upper, lower, bottom, top of the respective component in the direction of gravity, and "inner, outer" refers to inner, outer relative to the profile of the component or structure itself. In addition, it should be noted that terms such as "first", "second", and the like are used to distinguish one element from another, and have no order or importance. In addition, in the description with reference to the drawings, the same reference numerals in different drawings denote the same elements.

As shown in fig. 1-4, the present disclosure provides a glass tube blocking device comprising: the glass tube production line 1 comprises a conveying device 5, a cutting device 2 arranged on the conveying device 5 and a crushing device 4 arranged outside the conveying device 5, wherein the crushing device 4 is arranged at the tail end of the movement direction of a glass tube 6, and the supporting device 31 is arranged between the cutting device 2 and the crushing device 4; and a blocking member 32 which is arranged at one side of the supporting device 31 close to the cutting device 2 and extends into the conveying device 5 and is used for blocking the cut glass tube 6 so that the glass tube 6 falls on the conveying device 5, wherein the blocking member 32 can be arranged in an opening and closing manner so that the glass tube 6 which is not cut off can enter the crushing device 4.

Through the technical scheme, the glass tube blocking device provided by the disclosure comprises a supporting device 31 and a blocking piece 32, wherein the blocking piece 32 is arranged on the supporting device 31, the supporting device 31 is arranged between a cutting device 2 and a crushing device 4, a glass tube 6 is blocked by the blocking piece 32 after being cut by the cutting device 2, the glass tube 6 is prevented from being separated from a conveying device 5 under the action of inertia, the cut glass tube 6 is conveyed to a next-stage process for processing through the conveying device 5 or a conveying device of the next-stage process, for example, the conveying device 5 can be L-shaped, the crushing device 4 and the cutting device 2 are arranged at the tail end of linear conveying, namely, a corner, and then the cut glass tube 6 turns to enter the next-stage process, or the conveying device 5 is a linear conveying device, the next-stage conveying device is connected with the tail end of the conveying device 5 to convey the cut glass tube 6 to the next-stage process, and the crushing device 4 and the cutting device 2 are arranged at the tail end of the conveying device 5; the blocking member 32 is openably and closably provided to open the blocking member 32 to enter the crushing device 4 when the glass tube 6 is not cut, crush the section of the glass tube 6 to the next cutting point, and the uncut glass tube 6 is completely entered into the crushing device 4 under the thrust force of the subsequent glass tube 6, the inertia thereof, the action force of the conveying device 5 and the action force of the crushing device 4, so as to prevent the glass tube 6 from being blocked at the blocking member 32 when being cut continuously and prevent the subsequent glass tube 6 from being processed, because the glass tube 6 is formed with a certain rigidity but not processed by cooling and the like at this time, the rigidity is not yet completely finished, and the breakage is not easily extended to the glass tube 6 at the front section when the crushing device 4 crushes.

As an alternative embodiment, as shown in fig. 2-3, the blocking member 32 comprises a blocking plate 321 perpendicular to the transportation direction of the glass tube 6 for blocking the cut glass tube 6, one side of the blocking plate 321 is hinged, i.e. openably and closably arranged, with the supporting device 31 provided with a passage 311 for pushing the blocking plate 321 into the crushing device 4 through the passage 311 when the glass tube 6 is not cut.

Optionally, the supporting device 31 comprises a height adjusting device 34, and the blocking member 32 is connected with the height adjusting device 34 to adjust the height of the blocking member 32 for adapting to different glass tube production lines 1.

The height adjusting device 34 includes a first sliding assembly 341, a first driving motor 342, a first lead screw 343 connected to a driving end of the first driving motor 342, and a first nut 344 sleeved on the first lead screw 343 and in threaded connection with the first lead screw 343, the blocking member 32 is connected to the first sliding assembly 341, the first lead screw 343 is vertically disposed, and the first nut 344 is connected to the first sliding assembly 341 to drive the blocking member 32 to move up and down. For example, the first driving motor 342 is fixed on the supporting device 31, a driving end of the first lead screw 343 is upward, a bottom end of the first lead screw 343 is connected to the driving end, a top end of the first lead screw 343 is rotatably connected to a top plate disposed on a top of the supporting device 31 to stabilize the first lead screw 343, and the first driving motor 342 rotates to drive the first nut 344 to move up and down along the first lead screw 343, so that the first sliding component 341 drives the blocking member 32 to move up and down. In other embodiments, height adjustment device 34 may also be an electric telescopic rod or hydraulic rod to which blocking member 32 is attached.

The first sliding assembly 341 includes two first guide rails 3411, two first sliding blocks 3412 and a connecting plate 3413, the space between the two first guide rails 3411 is a passage 311 for passing through an uncut glass tube 6 on the supporting device 31, each first guide rail 3411 is connected with one first sliding block 3412 in a sliding manner, the connecting plate 3413 is arranged between the two first sliding blocks 3412, the connecting plate 3413 is provided with a through hole 3414 for passing through the uncut glass tube 6, the first nut 344 is connected with the connecting plate 3413, the connecting plate 3413 is connected with the two first sliding blocks 3412, the first nut 341344 is connected with the connecting plate 3413, the two first sliding blocks 3412 are driven to move by a first driving motor 342, the first lead screw 343 is arranged on one side of the through hole 3414, and the first lead screw 343 and the first nut 344 are prevented from blocking the through hole 3414 from passing through the glass tube 6. In other embodiments, the connecting plate 3413 may be configured as a rod-shaped structure connected to the top of the two first sliding blocks 3412, the first nut 344 is connected to the rod-shaped structure, and the glass tube 6 passes under the rod-shaped structure.

Alternatively, the first sliding block 3412 is disposed on one side of the first guiding rail 3411 close to the baffle 321, the blocking member 32 further includes two connecting rods 322 disposed horizontally, for example, the two connecting rods 322 are disposed vertically to the baffle 321, one end of the connecting rod 322 is connected to the top of the connecting plate 3413, the other end is hinged to the top of the baffle 321 so that the baffle 321 can rotate up and down along the hinged end, and the length of the connecting rod 322 is greater than the width of the baffle 321. The connecting rod 322 is provided to prevent the connecting plate 3413 from obstructing the rotation of the baffle 321 to prevent the baffle 321 from being opened, the uncut glass tube 6 pushes the baffle 321 to make the baffle 321 rotate counterclockwise along the hinged end, the glass tube 6 enters the crushing device 4 from the through hole 3414, and the baffle 321 returns to the original position under the action of gravity after the glass tube 6 passes through the through hole, so that other driving equipment is not needed.

As an alternative embodiment, as shown in fig. 2 to 3, the glass tube blocking device 3 further comprises a horizontal adjusting device 33, the supporting device 31 is connected with the horizontal adjusting device 33 so that the supporting device 31 can move towards or away from the conveying device 5, and the horizontal adjusting device 33 can adjust the distance from the supporting device 31 to the conveying device 5 so as to block glass tubes 6 with different lengths. The supporting device 31 further comprises a supporting member arranged below the height adjusting device 34, the supporting member comprises a vertically arranged supporting rod and a supporting plate which is connected to the upper end and the lower end of the supporting rod and is horizontally arranged, the upper supporting plate is connected with the bottom of the height adjusting device 34, and the lower supporting plate is connected with the top of the horizontal adjusting device 33.

Optionally, the horizontal adjusting device 33 includes a second guide rail 332 disposed horizontally, a second slider 333 slidably connected to the second guide rail 332, a second driving motor 331, a second lead screw 334 connected to a driving end of the second driving motor 331, and a second nut sleeved on the second lead screw 334 and threadedly connected to the second lead screw 334, the supporting device 31 is connected to the second guide rail 333, and the second nut is connected to the supporting device 31 to drive the supporting device 31 to move horizontally. For example, the second guide rails 332 are provided with two second guide rails 332 at intervals, each second guide rail 332 is provided with a second slider 333, the extending direction of the second guide rails 332 is perpendicular to the baffle 321, two ends of the second guide rails 332 are respectively provided with a first mounting plate and a second mounting plate vertically, the second driving motor 331 is horizontally arranged and fixed on the first mounting plate to be kept stationary, one end of the second lead screw 334 is connected with the driving end of the second driving motor 331, the other end of the second lead screw is extended in the same direction as the second guide rails 332 and is rotatably connected with the second mounting plate, the second driving motor 331 rotates to drive the second nut to horizontally move along the second lead screw 334, the second nut is connected with the bottom of the supporting device 31, the supporting device 31 is connected with the second slider 333, and the supporting device 31 is driven by the second nut and horizontally moves on the second guide rails 332 through the second slider 333. In other embodiments, the horizontal adjusting device 33 may also be an electric telescopic rod or a hydraulic rod, and the bottom of the supporting device 31 is connected to the electric telescopic rod or the hydraulic rod to drive the supporting device 31 to move horizontally.

As an alternative embodiment, as shown in fig. 4, a silicone layer 323 is disposed on a side of the baffle 321 close to the conveying device 5 to prevent the glass tube 6 from being cracked when the glass tube 6 hits the baffle 321, and the silicone layer 323 can be adhered to the baffle 321 or can be connected to the baffle 321 through bolts, and if the bolts are connected, the ends of the bolts are located inside the silicone layer 323 or flush with the outer surface of the silicone layer 323 to prevent the glass tube 6 from hitting the bolts.

As shown in fig. 1, the present disclosure also provides a glass tube production system comprising: the glass tube blocking device 3 described above; and a glass tube production line 1, and a glass tube blocking device 3 is arranged on the glass tube production line 1. The blocking piece 32 is arranged on the supporting device 31, the supporting device 31 is arranged between the cutting device 2 and the crushing device 4, the glass tube 6 is blocked by the blocking piece 32 after being cut by the cutting device 2, the glass tube 6 is prevented from being separated from the conveying device 5 under the action of inertia, the blocking piece 32 is arranged in an openable and closable mode and is used for opening the blocking piece 32 to enter the crushing device 4 when the glass tube 6 is not cut, and the blocking piece 32 is prevented from being blocked at the blocking piece 32 when the glass tube 6 is not cut continuously to hinder the processing of the subsequent glass tube 6.

In actual use, the cutting device 2 is arranged on the conveying device 5, the crushing device 4 is arranged on the outer side of the conveying device 5, the glass tube blocking device 3 is arranged between the cutting device 2 and the conveying device 5, the glass tube 6 is cut by the cutting device 2 and is blocked by the baffle 321 to prevent the glass tube 6 from separating from the conveying device 5, then the glass tube is conveyed to the next stage of process by the conveying device 5 or a conveying device of the next stage of process, if the glass tube 6 is not cut off, the baffle 321 is pushed open, the glass tube enters the crushing device 4 through the through hole 3414 to be crushed, and the glass tube 6 is reset under the action of gravity through the rear baffle 321 to continue working.

The preferred embodiments of the present disclosure are described in detail with reference to the accompanying drawings, however, the present disclosure is not limited to the specific details of the above embodiments, and various simple modifications may be made to the technical solution of the present disclosure within the technical idea of the present disclosure, and these simple modifications all belong to the protection scope of the present disclosure.

It should be noted that, in the above embodiments, the various features described in the above embodiments may be combined in any suitable manner, and in order to avoid unnecessary repetition, various possible combinations will not be further described in the present disclosure.

In addition, any combination of various embodiments of the present disclosure may be made, and the same should be considered as the disclosure of the present disclosure as long as it does not depart from the gist of the present disclosure.

Claims

1. A glass tube blocking device, comprising:

the glass tube production line comprises a conveying device, a cutting device arranged on the conveying device and a crushing device arranged outside the conveying device, wherein the supporting device is arranged between the cutting device and the crushing device;

the blocking piece is arranged on one side, close to the cutting device, of the supporting device and extends into the conveying device, and is used for blocking the cut glass tube so that the glass tube falls on the conveying device, and the blocking piece can be arranged in an opening and closing mode so that the glass tube which is not cut off can enter the crushing device.

2. The glass tube blocking device according to claim 1, wherein the blocking member comprises a baffle plate disposed perpendicular to a transport direction of the glass tube, one side of the baffle plate being hinged to the supporting device, the supporting device being provided with a passage for ejecting the baffle plate through the passage into the breaking device when the glass tube is not cut.

3. The glass tube blocking device according to claim 2, wherein the supporting device comprises a height adjusting device, and the blocking member is connected with the height adjusting device to adjust the height of the blocking member.

4. The glass tube blocking device according to claim 3, wherein the height adjusting device comprises a first sliding assembly, a first driving motor, a first lead screw connected with a driving end of the first driving motor, and a first nut sleeved on the first lead screw and in threaded connection with the first lead screw, the blocking member is connected with the first sliding assembly, the first lead screw is vertically arranged, and the first nut is connected with the first sliding assembly to drive the blocking member to move up and down.

5. The glass tube blocking device according to claim 4, wherein the first sliding assembly comprises two first guide rails, two first sliding blocks and a connecting plate, the two first guide rails are vertically spaced, one first sliding block is slidably connected to each first guide rail, the connecting plate is arranged between the two first sliding blocks, a through hole for the uncut glass tube to pass through is formed in the connecting plate, the first screw is connected with the connecting plate, and the first screw is arranged on one side of the through hole.

6. The glass tube blocking device as claimed in claim 5, wherein the first slider is disposed on one side of the first guide rail close to the baffle, the blocking member further comprises a connecting rod disposed horizontally, one end of the connecting rod is connected to the top of the connecting plate, the other end of the connecting rod is hinged to the top of the baffle so that the baffle can rotate up and down along the hinged end, and the length of the connecting rod is greater than the width of the baffle.

7. The glass tube blocking device as claimed in claim 1, further comprising a horizontal adjustment device, wherein the support device is connected to the horizontal adjustment device such that the support device is movable toward or away from the conveying device.

8. The glass tube blocking device according to claim 7, wherein the horizontal adjustment device comprises a second guide rail, a second slider, a second driving motor, a second lead screw and a second nut, the second guide rail is horizontally arranged, the second slider is slidably connected with the second guide rail, the second lead screw is connected with a driving end of the second driving motor, the second nut is sleeved on the second lead screw and is in threaded connection with the second lead screw, the supporting device is connected with the second slider, and the second nut is connected with the supporting device to drive the supporting device to horizontally move.

9. The glass tube blocking device according to claim 2, wherein a silicone layer is disposed on a side of the baffle plate close to the conveying device.

10. A glass tube production system, comprising:

the glass tube blocking device of any one of claims 1-9; and

the glass tube blocking device is arranged on the glass tube production line.