CN209974610U - Glass tube processing machine - Google Patents

Abstract

The utility model discloses a glass tube processing machine, including frame, flame spray gun, glass pipe rotating-structure, length processing structure, central processing structure, lateral part processing structure and synchronous drive structure, flame spray gun, glass pipe rotating-structure, length processing structure, central processing structure and lateral part processing structure all install in the frame, glass pipe rotating-structure is connected with central processing structure through synchronous drive structure. The utility model discloses in, usable flame spray gun comes to spray flame to the glass pipe and makes it soften to in the softening of glass pipe, length processing structure can change the length of the glass pipe after softening, and central processing structure and lateral part processing structure then can restrict the inside and the outside shape of the glass pipe after softening respectively, the three can be jointly moulding the glass pipe after softening promptly, make the shape and the length of glass pipe can accord with the user's needs, and realize by mechanical mechanism, machining efficiency is high, and the precision is good.

Description

Glass tube processing machine

Technical Field

The utility model belongs to the technical field of mechanical design and specifically relates to a glass tube processing machine is related to.

Background

In the processing of the glass tube, the shape of the glass tube is often required to be changed and thickened, so that the shape and the performance of the glass tube can meet the requirements of users, and the subsequent use of the glass tube, such as assembly, connection and the like, is facilitated. However, the processing of the glass tube at present is usually realized manually, the production efficiency is low, and the precision is difficult to be ensured, so that the glass tube processing is changed into mechanical processing, which is an urgent need of people.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a glass tube processing machine can solve one or more of above-mentioned problem.

According to the utility model discloses an aspect provides a glass tube processing machine, including frame, flame spray gun, glass pipe rotating-structure, length processing structure, central processing structure, lateral part processing structure and synchronous drive structure, flame spray gun, glass pipe rotating-structure, length processing structure, central processing structure and lateral part processing structure all install in the frame, glass pipe rotating-structure is connected with central processing structure through the synchronous drive structure.

The utility model has the advantages that: the utility model discloses in, can utilize glass pipe slewing mechanism to come to carry out the centre gripping to the glass pipe that needs processing, and utilize the flame spray gun to come to spray flame to glass pipe and make it soften, so that the softening of glass pipe, glass pipe slewing mechanism can make the glass pipe of processing be in the rotating state simultaneously, with the surface of guaranteeing that flame can be even has burnt glass pipe, afterwards, length processing structure can change the length of the glass pipe after softening, and central processing structure and lateral part processing structure then can restrict the inside and the outside shape of the glass pipe after softening respectively, the three can carry out moulding to the glass pipe after softening jointly promptly, make the shape and the length of glass pipe can accord with user's needs, in order to adapt to different user demands, and realize by mechanical mechanism, machining efficiency is high, and the precision is good. On the other hand, because the glass tube is in a rotating state in the processing process, the mold on the central processing structure can rotate synchronously with the glass tube by arranging the synchronous transmission structure, so that the friction caused by inconsistent rotation angles in the processing process is prevented.

In some embodiments, the glass tube rotating structure comprises a motor, a first rotating shaft and a glass tube clamping chuck, wherein one end of the first rotating shaft is connected with the motor, the other end of the first rotating shaft is connected with the glass tube clamping chuck, and the motor is installed on the rack. From this, glass centre gripping chuck can carry out the centre gripping to the glass pipe that needs processed, and the motor can drive the rotation of glass centre gripping chuck through first pivot, realizes the rotation of glass pipe promptly.

In some embodiments, the central processing structure comprises a central mold clamping chuck, a central processing mold, a second rotating shaft, a shaft seat and a first air cylinder, wherein the second rotating shaft is installed on the shaft seat, the central mold clamping chuck clamps the central processing mold, the central mold clamping chuck is connected with the second rotating shaft, the first air cylinder is connected with the shaft seat, and the first air cylinder is installed on the machine frame. Therefore, the first air cylinder can realize the feeding of the shaft seat, namely the feeding of the central processing die.

In some embodiments, the central processing mold includes a base and a protruding block connected to the base, the base having a cross-sectional area greater than a cross-sectional area of the protruding block. The stretching block can be convenient for processing the inside of the glass tube, and the base can be convenient for being in contact with the glass tube when being processed in place, so that the stretching of the stretching block is avoided.

In some embodiments, the synchronous drive comprises a first chain drive, a second chain drive and a drive rod, the first chain drive and the second chain drive being connected by the drive rod, the first chain drive being connected to the first spindle, the second chain drive being connected to the second spindle. Therefore, the power of the motor can be synchronously transmitted to the second rotating shaft through the first chain transmission mechanism and the second chain transmission mechanism, and the synchronous rotation of the first rotating shaft and the second rotating shaft is realized.

In some embodiments, the length processing structure includes a length processing mold connected to the connecting rod, a second cylinder installed on the frame, a connecting rod connected to the second cylinder, and a stopper rod installed on the frame and limiting a position of the connecting rod. From this, the second cylinder can drive the motion of connecting rod to drive the motion of length processing mould, and the gag lever post can prevent that the motion position of connecting rod from surpassing expectation, causing the damage of mechanism.

In some embodiments, the length tooling die includes a contact block and a stop block, the stop block being connected to the contact block. The contact block can be conveniently contacted with the surface of the glass tube to realize positioning, and the stop block can be used for processing the end part of the glass tube so as to realize the limitation on the length of the glass tube.

In some embodiments, the side processing structure includes a side processing mold, a third cylinder and a bracket, the third cylinder is mounted on the frame, the third cylinder is connected with the bracket, and the side processing mold is mounted on the bracket. Therefore, the third cylinder can realize the movement of the side part processing die, so that the side part processing die can be positioned at different positions before and after processing.

In some embodiments, the side tooling mold is provided with a circular arc shaped opening. The opening can be adapted to the external shape of the glass tube to facilitate processing of the exterior of the glass tube.

Drawings

Fig. 1 is a plan view schematically showing a glass tube processing machine according to an embodiment of the present invention.

FIG. 2 is a front view of a schematic structural view of a length processing structure of the glass tube processing machine of FIG. 1.

FIG. 3 is a plan view schematically showing the structure of a length processing structure of the glass tube processing machine of FIG. 1.

Fig. 4 is a structural view of a length processing mold of the length processing structure of fig. 3.

Fig. 5 is a front view of a structure schematic of a stopper rod of the length processing structure of fig. 3.

FIG. 6 is a right side view showing a schematic configuration of a side processing structure of the glass tube processing machine of FIG. 1.

Fig. 7 is a schematic view of the first chain transmission of the synchronous transmission of the glass tube processing machine of fig. 1.

Fig. 8 is a schematic view of the second chain drive of the synchronous drive of the glass tube processing machine of fig. 1.

Detailed Description

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

Referring to fig. 1-8, the present invention provides a glass tube processing machine, which comprises a frame 1, a flame spray gun 2, a glass tube rotating structure 3, a length processing structure 4, a central processing structure 5, a lateral processing structure 6 and a synchronous transmission structure 7.

The glass tube rotating structure 3 includes a motor 31, a first rotating shaft 32, and a glass tube holding chuck 33. One end of the first rotating shaft 32 and the driving shaft of the motor 31 are fixedly connected through a coupler, the other end of the first rotating shaft is fixedly connected with the glass tube clamping chuck 33 through a bolt, the body of the motor 31 is fixedly installed on the rack 1 through a motor base, and then the motor 1 can drive the glass tube clamping chuck 33 to rotate through the first rotating shaft 32.

The central processing structure 5 includes a central mold holding chuck 51, a central processing mold 52, a second rotating shaft 53, a shaft seat 54, and a first cylinder 55. The second rotating shaft 53 is mounted on the shaft seat 54 through a bearing, the central mold clamping chuck 51 clamps the central processing mold 52, the central mold clamping chuck 51 is fixedly connected with the second rotating shaft 53 through a bolt, the piston rod of the first air cylinder 55 is fixedly connected with the shaft seat 54 through a bolt, and the cylinder body of the first air cylinder 55 is fixedly mounted on the frame 1 through a cylinder seat.

The synchronous transmission 7 comprises a first chain transmission 71, a second chain transmission 72 and a transmission rod 73. The first chain transmission mechanism 71 comprises a first driving wheel 711, a first driven wheel 712 and a first chain 713, wherein the first chain 713 is connected end to end, the first chain 713 bypasses the first driving wheel 711 and the first driven wheel 712, the first driving wheel 711 is sleeved on the first rotating shaft 32, and the first driven wheel 712 is sleeved on one end of the transmission rod 73; the second chain transmission mechanism 72 includes a second driving wheel 721, a second driven wheel 722 and a second chain 723, the second chain 723 is connected end to end, the second chain 723 bypasses the second driving wheel 721 and the second driven wheel 722, the second driving wheel 721 is sleeved on the other end of the transmission rod 73, and the second driven wheel 722 is sleeved on the second rotating shaft 53. Therefore, the first rotating shaft 32 is connected with the second rotating shaft 53 through the synchronous transmission structure 7, so that the first rotating shaft 32 can synchronously drive the second rotating shaft 53 to rotate when rotating.

The central processing mold 52 comprises a base 521 and an extending block 522, the extending block 522 and the base 521 are both cylindrical, the extending block 522 and the base 521 are integrally connected, and the cross-sectional area of the base 521 is larger than that of the extending block 522, so that the base 521 can effectively prevent the central processing mold 52 from excessively extending into the glass tube when in use. And the center of the set protrusion block 522 is opposite to the center of the glass tube holding chuck 33.

The length processing structure 4 includes a length processing die 41, a second cylinder 42, a connecting rod 43, and a stopper rod 44. Bolt fixed connection is passed through with the one end of connecting rod 43 to length processing mould 41, and the cylinder body of second cylinder 42 passes through cylinder block fixed mounting in frame 1, and the piston rod of second cylinder 42 and the other end fixed connection of connecting rod 43 for second cylinder 42 can drive length processing mould 41 through connecting rod 43 and be close to or keep away from the glass pipe that needs processing. The limiting rod 44 is fixedly mounted on the frame 1 through a bolt and is used for limiting the position of the connecting rod 43, so that the damage to the mechanism caused by the fact that the moving position of the connecting rod 43 exceeds the requirement of a user is avoided.

The length processing mold 41 includes a contact block 411 and a stop block 412, the stop block 411 is connected to the contact block 412 by welding, and the stop block 411 is located above the contact block 412.

The side working structure 6 includes a side working die 61, a third cylinder 62, and a bracket 63. The cylinder body of the third cylinder 62 is fixedly mounted on the frame 1 through a cylinder block, the piston rod of the third cylinder 62 is fixedly connected with the bracket 63 through a bolt, and the side part processing mold 61 is fixedly mounted on the bracket 63 through a bolt.

The side processing mold 61 is semi-cylindrical, and is further provided with an arc-shaped opening 611, and the position of the mounted side processing mold 61 is matched with the position of the central processing mold 52, so that the opening 611 on the side processing mold 61 faces to a straight line where the center of the glass tube clamping chuck 41 is located, and the side processing mold 611 can be conveniently attached to a glass tube to be processed to shape the periphery of the glass tube.

The flame spray gun 2 is hinged on the frame 1 through a pin shaft, so that the flame spray gun 2 can swing on the frame 1 to a certain extent.

The utility model discloses when carrying out glass tube machining, use glass pipe centre gripping chuck 33 to grasp the glass pipe that needs processing earlier, later starter motor 31, motor 31 drives glass pipe centre gripping chuck 33 through first pivot 32 this moment and rotates, and glass pipe also rotates thereupon promptly. Meanwhile, the first rotating shaft 32 can drive the second rotating shaft 53 to synchronously rotate through the synchronous transmission structure 7, so that the central mold clamping chuck 51 connected with the second rotating shaft 53 also rotates, and finally the central processing mold 52 connected with the central mold clamping chuck 51 also synchronously rotates.

Then, the flame spray gun 2 is started, and the flame spray gun 2 sprays flame to soften the glass tube. The user can adjust the fire position of the flame spray gun 2 by swinging the flame spray gun 2, and since the glass tube to be processed is in a rotating state, the glass tube to be processed can be uniformly softened as much as possible.

When the length of the softened glass tube needs to be adjusted, a user can start the second air cylinder 42, so that the second air cylinder 42 drives the length processing mold 41 to lean against the glass tube through the connecting rod 43 until the contact block 411 contacts with the glass tube, and meanwhile, the stop block 412 contacts with the end of the glass tube, at this time, the stop block 412 also applies force to the end of the glass tube through the force supplied by the second air cylinder 42, and under the limitation of the limiting rod 44 on the connecting rod 43, the stop block 412 is finally maintained at the position of the length of the glass tube that the user needs to process, so that the stop block 412 can press the end of the softened glass tube to the specific position, namely, the length adjustment of the glass tube is realized.

When the softened glass tube needs to be subjected to shape processing, on one hand, a user can start the first cylinder 55, so that the first cylinder 55 drives the shaft seat 54 to move towards the direction of the glass tube, namely the central processing mold 52 moves along with the glass tube, the extending block 522 can extend into the glass tube to shape the inside of the glass tube, on the other hand, the base 521 on the central processing mold 52 can be in contact with the end part of the glass tube to avoid the excessive extension of the extending block 522, on the other hand, the user can also start the third cylinder 62, so that the third cylinder 62 drives the support 63 to move towards the direction of the glass tube, namely the side processing mold 61 also moves along with the glass tube, and the side processing mold 61 can be attached to the outer side of the glass tube to shape the outside of the glass tube. Thus, the shape of the glass tube can be processed by shaping the inside and outside of the glass tube by the center processing die 52 and the side processing die 61. In addition, since the central processing mold 52 is in a synchronous rotation state with the glass tube being processed during the processing, friction between the central processing mold and the glass tube due to a rotation difference can be effectively eliminated.

What has been described above are only some embodiments of the invention. For those skilled in the art, without departing from the inventive concept, several modifications and improvements can be made, which are within the scope of the invention.

Claims (9)

1. The glass tube processing machine is characterized by comprising a machine frame (1), a flame spray gun (2), a glass tube rotating structure (3), a length processing structure (4), a center processing structure (5), a side processing structure (6) and a synchronous transmission structure (7), wherein the flame spray gun (2), the glass tube rotating structure (3), the length processing structure (4), the center processing structure (5) and the side processing structure (6) are all installed on the machine frame (1), and the glass tube rotating structure (3) is connected with the center processing structure (5) through the synchronous transmission structure (7).

2. The glass tube processing machine according to claim 1, wherein the glass tube rotating structure (3) comprises a motor (31), a first rotating shaft (32) and a glass tube holding chuck (33), one end of the first rotating shaft (32) is connected with the motor (31), the other end is connected with the glass tube holding chuck (33), and the motor (31) is mounted on the frame (1).

3. A glass tube processing machine according to claim 2, characterized in that the central processing structure (5) comprises a central mold holding chuck (51), a central processing mold (52), a second rotating shaft (53), a shaft seat (54) and a first air cylinder (55), the second rotating shaft (53) is mounted on the shaft seat (54), the central mold holding chuck (51) holds the central processing mold (52), the central mold holding chuck (51) is connected with the second rotating shaft (53), the first air cylinder (55) is connected with the shaft seat (54), and the first air cylinder (55) is mounted on the frame (1).

4. The glass tube processing machine according to claim 3, wherein the central processing mold (52) comprises a base (521) and a protruding block (522), the protruding block (522) and the base (521) being connected, the base (521) having a cross-sectional area larger than the cross-sectional area of the protruding block (522).

5. The glass tube processing machine according to claim 3, characterized in that the synchronous transmission mechanism (7) comprises a first chain transmission mechanism (71), a second chain transmission mechanism (72) and a transmission rod (73), the first chain transmission mechanism (71) and the second chain transmission mechanism (72) are connected through the transmission rod (73), the first chain transmission mechanism (71) is connected with the first rotating shaft (32), and the second chain transmission mechanism (72) is connected with the second rotating shaft (53).

6. The glass tube processing machine according to claim 1, wherein the length processing structure (4) comprises a length processing mold (41), a second cylinder (42), a connecting rod (43) and a limiting rod (44), the length processing mold (41) is connected with the connecting rod (43), the second cylinder (42) is installed on the frame (1), the second cylinder (42) is connected with the connecting rod (43), and the limiting rod (44) is installed on the frame (1) and used for limiting the position of the connecting rod (43).

7. The glass tube processing machine according to claim 6, wherein the length processing mold (41) comprises a contact block (411) and a stop block (412), the stop block (412) being connected to the contact block (411).

8. A glass tube processing machine according to claim 1, characterized in that the side processing structure (6) comprises a side processing mold (61), a third cylinder (62) and a bracket (63), the third cylinder (62) being mounted on the frame (1), the third cylinder (62) being connected to the bracket (63), the side processing mold (61) being mounted on the bracket (63).

9. The glass tube processing machine according to claim 8, wherein the side processing mold (61) is provided with a circular arc-shaped opening (611).

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