CN115352797B - Device and method for preventing glass tube from colliding during glass tube conveying turning - Google Patents

Abstract

The invention relates to the technical field of glass tube conveying, and provides a device and a method for preventing glass tubes from colliding during conveying and turning of the glass tubes. Through above-mentioned technical scheme, solved among the prior art glass pipe at the transportation process, the glass pipe of straightway can collide each other with the glass pipe of turn section, causes the problem that glass pipe damaged easily.

Description

Device and method for preventing glass tube from colliding during glass tube conveying turning

Technical Field

The invention relates to the technical field of glass tube conveying, in particular to a device and a method for preventing glass tubes from colliding during conveying and turning of the glass tubes.

Background

In the production technology of the glass tube, the glass tube is formed on the tube drawing runway, the formed glass tube is cut after passing through a tractor, the glass tube after being cut at a fixed length is sent into a round-mouth machine through a transmission device to be round-mouth, the glass tube after being round-mouth at two ends is detected through a quality monitoring device, unqualified glass tubes are subjected to waste kicking treatment, and qualified glass tubes enter a subsequent-order bundling plastic packaging device. In the whole process flow process, the glass tubes are out of the round-mouth device after being cut by the tractor, the glass tubes are arranged on the transmission line in an unordered mode, the problem of collision among the glass tubes can occur, particularly on a turning transmission track, the glass tubes can interfere with each other and are seriously collided, the surface of the glass tube can be scratched to influence the quality of the glass tube, and the qualification rate of the glass tube and the efficiency of subsequent production are influenced. The prior art is to increase the angle of the turning part of the conveying device, but the occupied area of the conveying device is increased, which is a great problem in the industry.

Therefore, a solution to the above problems is needed.

Disclosure of Invention

The invention provides a device and a method for preventing a glass tube from colliding during conveying and turning of the glass tube, and solves the problem that the glass tube is easily damaged because a straight-line glass tube and a turning-section glass tube collide with each other during conveying of the glass tube in the prior art.

The technical scheme of the invention is as follows:

a device for preventing glass tubes from colliding during conveying and turning of the glass tubes comprises a machine body and a conveying assembly arranged on the machine body, wherein the conveying assembly comprises a straight line section and a turning section, the height of the outlet end of the straight line section in the vertical direction is lower than that of the inlet end of the turning section in the vertical direction, the device also comprises a device body,

a first drive shaft rotatably disposed on the body such that the first drive shaft is positioned between the straight section and the turnaround section,

the feeding piece is arranged on the first driving shaft, a plurality of feeding pieces are distributed along the circumferential direction of the first driving shaft, the feeding piece is provided with a material clamping portion, an included angle is formed between the material clamping portion and the feeding piece, a material clamping space is formed by the material clamping portion and the feeding piece, the material clamping space is used for containing glass tubes, the first driving shaft rotates, the feeding piece rotates along with the first driving shaft, and the feeding piece sequentially penetrates through the outlet end of the straight line section and the inlet end of the turning section.

As a further technical scheme, the feeding piece is provided with a plurality of material clamping portions, the material clamping portions are distributed along the axial direction of the feeding piece, the material clamping portions are close to the first driving shaft along the direction of the feeding piece, and the included angle between the material clamping portions and the feeding piece is gradually increased.

As a further technical scheme, one end of the material clamping part is hinged to the feeding piece, and the material clamping part rotates along a hinged point to be used for adjusting the size of the material clamping space.

As a further technical scheme, the material clamping part is provided with an arc-shaped part, and the arc-shaped part is positioned at the other end of the material clamping part.

As a further technical solution, the feeding member has a sliding cavity; also comprises the following steps of (1) preparing,

a gear arranged on the feeding member, the gear being positioned on a hinge shaft of the feeding member,

the rack is arranged in the sliding cavity in a sliding mode, the rack is meshed with the gears, the rack drives the material clamping part to rotate along the hinge shaft in a sliding mode,

the adjusting shaft is rotatably arranged on the feeding piece and provided with a tooth part, the tooth part is meshed with the rack, the adjusting shaft rotates, and the adjusting shaft drives the rack to be slidably arranged in the sliding cavity.

As a further technical solution, the straight line segment comprises,

a first shaft body rotatably provided on the body,

the two first driving wheels are arranged on the first shaft body and rotate along with the first shaft body,

the two first driven wheels are rotatably arranged on the machine body, the first driven wheels are positioned at the outlet ends of the straight line sections, the feeding piece penetrates through the space between the two first driven wheels,

the first chain is sleeved on the first driving wheel and the first driven wheel respectively.

As a further technical solution, the turning section comprises,

a second shaft body rotatably disposed on the body,

two second driving wheels are arranged on the second shaft body and rotate along with the second shaft body,

the two second driven wheels are rotatably arranged on the machine body, the second driven wheels are positioned at the inlet end of the turning section, the feeding piece penetrates through the space between the two second driven wheels,

and the second chain is sleeved on the second driving wheel and the second driven wheel respectively.

As a further technical scheme, the chain conveyor device further comprises a material bearing seat, wherein the material bearing seat is provided with a plurality of grooves, the material bearing seat is arranged on the first chain and the second chain respectively, the material bearing seat is distributed along the feeding direction of the first chain and the feeding direction of the second chain, and the material bearing seat is provided with the grooves, and the adjacent grooves of the material bearing seat on the first chain or the second chain form a material bearing space.

A method for preventing glass tube collision during glass tube conveying turning comprises the following steps:

s1, discharging: the glass tube is sent out from the forming machine and then enters the straight-line section of the material bearing seat;

s2, arranging and conveying: the glass tubes sequentially enter the material clamping space of the feeding piece from the material bearing seat of the straight line section, and the glass tubes enter the material bearing seat of the turning section through the feeding piece;

s3, conveying and collecting: and the glass tube enters a collecting device for collection after passing through the turning section.

The working principle and the beneficial effects of the invention are as follows:

in order to solve the problems, the height difference is set between the outlet end of the straight line section and the inlet end of the turning section, in the conveying process, the glass tube located at the straight line section and the glass tube located at the turning section are not on the same plane and have a certain height difference, so that the glass tubes do not collide with each other, a feeding member is needed in the arrangement, the glass tube located at the outlet end of the straight line section is continuously conveyed to the inlet end of the turning section, the first driving shaft rotates to drive the feeding members to rotate along the first driving shaft, the feeding members sequentially penetrate through the outlet end of the straight line section and the inlet end of the turning section in the rotating process of the first driving shaft, the feeding member lifts the glass tube located at the straight line section from the lower part, the glass tube slides downwards along the feeding member under the action of gravity, a clamping space is formed between the clamping part and the feeding members, the glass tube rotates along with the feeding members, when the feeding members are conveyed to the inlet end of the turning section, the feeding members move downwards from the highest point of the rotating track, the two ends of the glass tube are firstly contacted with the material bearing seats of the turning section, the feeding members continuously move, so that the glass tube continuously collide with the glass tube on the glass tube, and the glass tube, and the glass tube conveying radius of the glass tube at the turning section is not increased, and the glass tube is not increased.

Drawings

The present invention will be described in further detail with reference to the accompanying drawings and specific embodiments.

FIG. 1 is a schematic view of the structure of the present invention;

FIG. 2 is an enlarged view of a portion of FIG. 1;

FIG. 3 is a schematic view of the feed member and first drive shaft configuration of the present invention;

FIG. 4 is a schematic view of the internal cross-sectional structure of the feeding member of the present invention;

in the figure: 1. the feeding mechanism comprises a machine body, 2, a conveying assembly, 21, a straight line section, 22, a turning section, 3, a first driving shaft, 4, a feeding piece, 41, a material clamping part, 411, an arc-shaped part, 42, a sliding cavity, 5, a gear, 6, a rack, 7, an adjusting shaft, 71, a tooth part, 211, a first shaft body, 212, a first driving wheel, 213, a first driven wheel, 214, a first chain, 221, a second shaft body, 222, a second driving wheel, 223, a second driven wheel, 224, a second chain, 8, a material bearing seat, 81 and a groove.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall relate to the scope of protection of the present invention.

As shown in fig. 1 to 4, the present embodiment provides a device for preventing collision of glass tubes during glass tube conveying and turning, which includes a machine body 1 and a conveying assembly 2 disposed on the machine body 1, wherein the conveying assembly 2 includes a straight line section 21 and a turning section 22, an outlet end of the straight line section 21 is lower than an inlet end of the turning section 22 in vertical direction, and further includes,

a first driving shaft 3, the first driving shaft 3 is rotatably arranged on the machine body 1, so that the first driving shaft 3 is positioned between the straight section 21 and the turning section 22,

the feeding piece 4 is arranged on the first driving shaft 3, the feeding pieces 4 are circumferentially distributed along the first driving shaft 3, the feeding piece 4 is provided with a material clamping portion 41, an included angle is formed between the material clamping portion 41 and the feeding piece 4, a material clamping space is formed between the material clamping portion 41 and the feeding piece 4 and used for containing glass tubes, the first driving shaft 3 rotates, the feeding piece 4 rotates along with the first driving shaft 3, and the feeding piece 4 sequentially penetrates through an outlet end of the straight line section 21 and an inlet end of the turning section 22.

In this embodiment, in order to solve the above problem, in the present application, a height difference is set between an outlet end of the straight line segment 21 and an inlet end of the turning segment 22, in a conveying process, a glass tube located at the outlet end of the straight line segment 21 and a glass tube located at the turning segment 22 are not in the same plane and have a certain height difference, and therefore do not collide with each other, and thus a feeding member 4 is required, the glass tube at the outlet end of the straight line segment 21 is continuously fed to the inlet end of the turning segment 22, the first driving shaft 3 drives a plurality of feeding members 4 to rotate along the first driving shaft 3, in a rotating process of the first driving shaft 3, the feeding member 4 sequentially passes through the outlet end of the straight line segment 21 and the inlet end of the turning segment 22, the feeding member 4 lifts up the glass tube of the straight line segment 21 from below, the glass tube slides downward under the gravity action along the feeding member 4, a clamping space is formed between the clamping portion 41 and the feeding member 4, the glass tube 4 rotates, when the feeding member 4 is fed to the turning segment 22, the glass tube contacts with the feeding seat 22, and thus the glass tube does not continuously moves from the feeding seat 8 on the turning segment 22, and the glass tube conveying seat, and the glass tube can not continuously move from the glass tube, and the glass tube conveying seat.

Further, the feeding member 4 is provided with a plurality of material clamping portions 41, the material clamping portions 41 are distributed along the axial direction of the feeding member 4, the material clamping portions 41 are arranged along the direction of the feeding member 4 towards the direction close to the first driving shaft 3, and the included angle between the material clamping portions 41 and the feeding member 4 is gradually increased.

In this embodiment, a plurality of material clamping portions 41 are provided, and the included angle of the material clamping portions 41 gradually increases, when glass tubes overlap each other on the material bearing seat 8 on the straight line segment 21, after two or more glass tubes enter the material clamping portion 41 at the highest point, the material clamping space is filled, the remaining glass tubes fall onto the material clamping portion 41 below, because the included angle between the feeding member 4 and the material clamping portion 41 gradually increases along the feeding member 4, when the glass tubes roll downward, the glass tubes cannot separate from the material clamping space formed by the material clamping portions 41, the length of the material clamping portions 41 below can be properly increased, so that the glass tubes are less likely to separate from the material clamping space, the glass tubes are not only conveyed but also sorted, so that the glass tubes overlapped with each other are divided into one, and finally enter the turning section 22 at a time, the ordered conveyance of the glass tubes is realized, when the feeding member 4 passes through the discharge end of the straight line segment 21, the glass tubes with the feeding portion separated from the feeding member 4 can be conveyed by the feeding member 4, and the feeding member 4 can swing at a speed after the glass tubes pass through the straight line segment 21, and the feeding member 4 can be conveyed, and the feeding member 4 can swing.

Further, one end of the material clamping part 41 is hinged to the feeding member 4, and the material clamping part 41 rotates along a hinge point to adjust the size of the material clamping space.

In this embodiment, material clamping portion 41 can be followed the articulated shaft pivoted, consequently can adjust the contained angle between material clamping portion 41 and the pay-off piece 4 to the glass pipe of different diameters adapts to, and material clamping portion 41 that is located on same pay-off piece 4 can be adjusted simultaneously, also can control respectively and rotate, thereby adjusts the contained angle separately, and two kinds of modes are each profitable and disadvantageous.

Further, the material clamping portion 41 has an arc portion 411, and the arc portion 411 is located at the other end of the material clamping portion 41.

In this embodiment, the arc portion 411 of the material clamping portion 41 is mainly used to make the glass tube fall into another material clamping portion 41 from one material clamping portion 41 more smoothly, and the glass tube is not easy to be damaged.

Further, the feeder 4 has a sliding chamber 42; also comprises a step of adding a new type of additive,

a gear 5, wherein the gear 5 is arranged on the feeding member 4, the gear 5 is positioned on a hinging shaft of the feeding member 4,

the rack 6 is slidably arranged in the sliding cavity 42, the rack 6 is meshed with the gears 5, the rack 6 slidably drives the material clamping part 41 to rotate along a hinge shaft,

the adjusting shaft 7 is rotatably arranged on the feeding member 4, the adjusting shaft 7 is provided with a tooth part 71, the tooth part 71 is meshed with the rack 6, the adjusting shaft 7 rotates, and the adjusting shaft drives the rack 6 to be slidably arranged in the sliding cavity 42.

In this embodiment, when needing to adjust the angle of pressing from both sides material portion 41 and pay-off 4, rotate regulating shaft 7 through the instrument, make regulating shaft 7 rotate, thereby it slides in sliding chamber 42 to drive rack 6 through tooth 71, rack 6 slides and can drive gear 5 and rotate, thereby it rotates to drive to press from both sides material portion 41 along the pin joint, this kind of mode can adjust simultaneously and be located the material portion 41 that presss from both sides on same pay-off 4, can keep each angle difference between the material portion 41 of pressing from both sides unchangeably, this angle difference can prevent that the glass pipe breaks away from and presss from both sides the material space, because it can't realize 360 rotations to press from both sides material portion 41, consequently sliding chamber 42 still can carry on spacingly to rack 6.

Further, the straight line segment 21 includes,

a first shaft body 211, the first shaft body 211 is rotatably arranged on the machine body 1,

a first driving wheel 212, two of the first driving wheels 212 are disposed on the first shaft body 211, the first driving wheels 212 rotate along with the first shaft body 211,

a first driven wheel 213, two first driven wheels 213 are rotatably arranged on the machine body 1, the first driven wheels 213 are positioned at the outlet end of the straight section 21, the feeding member 4 passes through the two first driven wheels 213,

and the first chain 214 is sleeved on the first driving wheel 212 and the first driven wheel 213 respectively.

In this embodiment, the first axis body 211 of motor drive drives first action wheel 212 and rotates, two first action wheels 212 distribute along the axial direction of first axis body 211, a first chain 214 is established to the cover on a first action wheel 212 and a first driven wheel 213, set up two first chains 214 altogether, support the partly of glass pipe respectively, thereby can make the glass pipe carry out the steady transport, do not communicate through the axis body between two first driven wheels 213, can make things convenient for pay-off piece 4 to pass between two first driven wheels 213, thereby realize the ejection of compact of glass pipe, send into in the section of turning 22.

Further, the turnaround section 22 comprises,

a second shaft body 221, wherein the second shaft body 221 is rotatably arranged on the machine body 1,

a second driving wheel 222, two of the second driving wheels 222 being disposed on the second shaft 221, the second driving wheels 222 rotating along with the second shaft 221,

a second driven wheel 223, two second driven wheels 223 are rotatably arranged on the machine body 1, the second driven wheels 223 are positioned at the inlet end of the turning section 22, the feeding member 4 passes through the two second driven wheels 223,

and the second chain 224 is sleeved on the second driving wheel 222 and the second driven wheel 223 respectively.

In this embodiment, the transmission mode in the turning section 22 is substantially the same as that in the straight section 21, and the difference is that the second driven wheel 223 is located at the inlet end of the turning section 22, and the first driven wheel 213 is located at the outlet end of the straight section 21, because the driven wheels need to pass through the feeding member 4, the driving through the shaft body is not needed.

Further, still include and hold the material seat 8, it has a plurality of to hold the material seat 8, a plurality of it is equally divided to set up respectively on first chain 214 and second chain 224, it distributes to hold the material seat 8 along the pay-off direction of first chain 214 with second chain 224, it has recess 81 to hold the material seat 8, first chain 214 or second chain 224 is last adjacent hold the material space of holding the material seat 8's recess 81 constitution.

In this embodiment, the material bearing seat 8 is arranged on the first chain 214 and the second chain 224, so that the glass tube can be stably conveyed, the glass tube can fall into the groove 81 as long as the glass tube falls on one material bearing seat 8, the shape of the groove 81 can be arc-shaped or triangular, the glass tube can be conveniently fed and discharged, the material bearing seat 8 in the same axial direction of the first chain 214 or the second chain 224 forms a material bearing space, and the glass tube can be conveyed more stably.

A method for preventing glass tubes from colliding during conveying and turning of the glass tubes comprises the device for preventing the glass tubes from colliding during conveying and turning of the glass tubes, and comprises the following steps:

s1, discharging: after being sent out from the forming machine, the glass tube enters the material bearing seat 8 of the straight line section 21;

s2, arranging and conveying: glass tubes enter the material clamping space of the feeding piece 4 from the material bearing seat 8 of the straight line section 21 in sequence, and enter the material bearing seat 8 of the turning section 22 through the feeding piece 4;

s3, conveying and collecting: after passing through the turning section 22, the glass tubes enter a collection device for collection.

The method can ensure that the glass tubes can be transported more stably, and the glass tubes discharged from the molding machine can be arranged, so that the glass tubes can be transported orderly, the transportation stability is improved, the transportation efficiency is improved, and the damage rate in the transportation process is reduced.

The present invention is not limited to the above preferred embodiments, and any modifications, equivalent substitutions, improvements, etc. within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (6)

1. The utility model provides a glass pipe transmission turns and prevents device that glass pipe collided with, includes fuselage (1) and sets up conveying component (2) on fuselage (1), conveying component (2) include straightway (21) and turn section (22), its characterized in that, the exit end of straightway (21) highly is less than along vertical direction the vertical direction height of turn section (22) entrance point still includes,

a first driving shaft (3), wherein the first driving shaft (3) is rotatably arranged on the machine body (1), the first driving shaft (3) is positioned between the straight section (21) and the turning section (22),

the glass tube feeding device comprises a feeding piece (4), the feeding piece (4) is arranged on a first driving shaft (3), a plurality of feeding pieces (4) are distributed along the circumferential direction of the first driving shaft (3), the feeding piece (4) is provided with a clamping part (41), an included angle is formed between the clamping part (41) and the feeding piece (4), a clamping space is formed between the clamping part (41) and the feeding piece (4), the clamping space is used for containing a glass tube, the first driving shaft (3) rotates, the feeding piece (4) rotates along with the first driving shaft (3), the feeding piece (4) sequentially passes through the outlet end of a straight line section (21) and the inlet end of a turning section (22), the feeding piece (4) is provided with a plurality of clamping parts (41), the clamping parts (41) are distributed along the axial direction of the feeding piece (4), the clamping parts (41) gradually increase the included angle with the feeding piece (4) towards the direction close to the first driving shaft (3) along the feeding piece (4),

one end of the material clamping part (41) is hinged on the feeding piece (4), the material clamping part (41) rotates along a hinged point to adjust the size of the material clamping space,

the feeding piece (4) is provided with a sliding cavity (42); also comprises the following steps of (1) preparing,

a gear (5), wherein the gear (5) is arranged on the material clamping part (41), the gear (5) is positioned on a hinge shaft of the feeding piece (4),

the rack (6) is arranged in the sliding cavity (42) in a sliding mode, the rack (6) is meshed with the gears (5), the rack (6) drives the material clamping part (41) to rotate along a hinged shaft in a sliding mode,

the adjusting shaft (7) is rotatably arranged on the feeding piece (4), the adjusting shaft (7) is provided with a tooth part (71), the tooth part (71) is meshed with the rack (6), the adjusting shaft (7) rotates, and the adjusting shaft (7) drives the rack (6) to be slidably arranged in the sliding cavity (42).

2. A glass tube conveying turn bump preventing device according to claim 1, wherein the clamping portion (41) has an arc portion (411), and the arc portion (411) is located at the other end of the clamping portion (41).

3. A glass tube conveying turn bump preventing device according to claim 1, characterized in that the straight line segment (21) includes,

a first shaft body (211), wherein the first shaft body (211) is rotatably arranged on the machine body (1),

the two first driving wheels (212) are arranged on the first shaft body (211), the first driving wheels (212) rotate along with the first shaft body (211),

the two first driven wheels (213) are rotatably arranged on the machine body (1), the first driven wheels (213) are positioned at the outlet end of the straight section (21), the feeding piece (4) penetrates between the two first driven wheels (213),

the first chain (214), the first chain (214) is established respectively on first action wheel (212) and first driven wheel (213).

4. A glass tube conveying turn bump prevention device as defined in claim 3, wherein the turn section (22) includes,

a second shaft body (221), wherein the second shaft body (221) is rotatably arranged on the machine body (1),

the two second driving wheels (222) are arranged on the second shaft body (221), the second driving wheels (222) rotate along with the second shaft body (221),

the two second driven wheels (223) are rotatably arranged on the machine body (1), the second driven wheels (223) are positioned at the inlet end of the turning section (22), the feeding piece (4) penetrates between the two second driven wheels (223),

and the second chain (224) is sleeved on the second driving wheel (222) and the second driven wheel (223) respectively.

5. The device for preventing glass tube collision during glass tube transmission turning according to claim 4, further comprising a material bearing seat (8), wherein the material bearing seat (8) has a plurality of material bearing seats (8), the plurality of material bearing seats (8) are respectively arranged on the first chain (214) and the second chain (224), the material bearing seats (8) are distributed along the feeding direction of the first chain (214) and the second chain (224), the material bearing seat (8) has a groove (81), and the adjacent groove (81) of the material bearing seat (8) on the first chain (214) or the second chain (224) forms a material bearing space.

6. A method for preventing glass tube from colliding during conveying and turning of a glass tube is characterized in that the method is suitable for the device for preventing the glass tube from colliding during conveying and turning of the glass tube, which is disclosed by claim 5, and comprises the following steps:

s1, discharging: the glass tube is sent out from the forming machine and then enters the straight-line section of the material bearing seat;

s2, arranging and conveying: the glass tubes sequentially enter the material clamping space of the feeding piece from the material bearing seat of the straight line section, and the glass tubes enter the material bearing seat of the turning section through the feeding piece;

s3, conveying and collecting: and the glass tube enters a collecting device for collection after passing through the turning section.

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