CN111016199A

CN111016199A - Pipe penetrating mechanism and automatic pipe penetrating device

Info

Publication number: CN111016199A
Application number: CN201911351937.2A
Authority: CN
Inventors: 李超; 刘鹏; 汪军求; 崔拯庶; 张高林; 王碧川
Original assignee: Gree Electric Appliances Inc of Zhuhai; Gree Wuhu Electric Appliances Co Ltd
Current assignee: Gree Electric Appliances Inc of Zhuhai; Gree Wuhu Electric Appliances Co Ltd
Priority date: 2019-12-24
Filing date: 2019-12-24
Publication date: 2020-04-17

Abstract

The invention discloses a pipe penetrating mechanism and an automatic pipe penetrating device, wherein the pipe penetrating mechanism comprises a pipe penetrating die, two ends of the pipe penetrating die are respectively provided with two limiting slideways, and a first limiting slideway and a second limiting slideway are coaxially arranged and are mutually communicated; wherein the first limit slideway is used for inserting the capillary tube, and the second limit slideway is used for allowing the soft rubber tube to enter; the poling mould forms locating plane at two sections spacing slide junctions, and locating plane is used for with the flexible glue pipe butt to when locating plane supported the flexible glue pipe and made the flexible glue pipe static, the capillary continued to move and inserted in the flexible glue pipe, realize the poling.

Description

Pipe penetrating mechanism and automatic pipe penetrating device

Technical Field

The invention belongs to the field of pipe penetrating, and particularly relates to a pipe penetrating mechanism and an automatic pipe penetrating device.

Background

The outlet machine capillary tube process has the requirement of rubber tube sleeving, and generally, after the capillary tube is blanked, a process tube needs to be welded for positioning, and then the rubber tube sleeving process is carried out. The capillary is produced by a capillary blanking machine, and the rubber tube is produced by a rubber tube blanking machine and then is transported to an employee sleeving workbench for sleeving. Because capillary specification is less, and the cover tube time is longer, leads to intensity of labour big, and is inefficient, and the material is transported and is taken time simultaneously, and current single-shift single line body need drop into 2 personnel and carry out the sleeve pipe operation, exists personnel extravagant.

Disclosure of Invention

The invention aims to provide a tube penetrating mechanism and an automatic tube penetrating device, which are used for automatically sleeving a rubber sleeve on a capillary tube.

In order to achieve the purpose, the specific technical scheme of the pipe penetrating mechanism and the automatic pipe penetrating device is as follows:

a pipe penetrating mechanism comprises a pipe penetrating mold, two ends of the pipe penetrating mold are respectively provided with two limiting slideways, and a first limiting slideway and a second limiting slideway are coaxially arranged and are communicated with each other; wherein the first limit slideway is used for inserting the capillary tube, and the second limit slideway is used for allowing the soft rubber tube to enter; the poling mould forms locating plane at two sections spacing slide junctions, and locating plane is used for with the flexible glue pipe butt to when locating plane supported the flexible glue pipe and made the flexible glue pipe static, the capillary continued to move and inserted in the flexible glue pipe, realize the poling.

Furthermore, the joint of the positioning plane and the first limiting slide way is provided with a rounded corner.

Furthermore, the pipe penetrating die comprises a left die, a right die and a driving device, wherein profiles are respectively formed on the adjacent surfaces of the left die and the right die, and the driving device enables the left die and the right die which are symmetrically arranged to be mutually abutted, so that the profiles of the left die and the right die are spliced to form the limiting slide way.

Furthermore, a slitting device is arranged on one side of the automatic pipe penetrating device; the slitting device comprises a cutter and a cutting driver, wherein the cutter is driven by the cutting driver to move to one side of the inlet end of the second limiting slide way, so that the soft rubber pipe is divided.

Further, the side face of the cutter is used for being abutted with the capillary.

Furthermore, at least one auxiliary die is arranged on one side of the pipe penetrating die, a third limiting slide way is formed in the auxiliary die, and the third limiting slide way and the second limiting slide way are arranged in an equal-diameter and coaxial mode and are communicated with each other.

Further, gaps are formed between the auxiliary die and the pipe penetrating die and between the adjacent auxiliary dies; the gap is used for inserting the cutter, thereby dividing the soft rubber tube.

Further, the slitting device comprises a translation drive on which the cutting drive is mounted, the translation drive moving the cutter and aligning the cutter with one of the gaps.

An automatic pipe penetrating device comprises the pipe penetrating mechanism.

Further, the automatic pipe penetrating device also comprises a material pulling mechanism; the material pulling mechanism comprises a driving wheel and a driven wheel, the driving wheel and the driven wheel are used for clamping the soft rubber pipe, so that the soft rubber pipe is driven to move forwards, and a gap between the driven wheel and the driving wheel is parallel and level to the second limiting slide way.

Furthermore, the driving wheels and the driven wheels are arranged in a front group and a rear group, and the rotating speeds of the two groups of driving wheels are the same.

Furthermore, the material pulling mechanism comprises a limiting frame; the limiting frame is provided with an adjusting guide rail, two sliding platforms are connected in the adjusting guide rail in a sliding manner in sequence, and the driving wheel and the driven wheel are respectively connected to the two sliding platforms in a rotating manner; one end of the sliding platform is provided with a butting surface, and the other end of the sliding platform is provided with a pressure regulating mechanism; when the driving wheel and the driven wheel are contacted with each other, a gap is formed between the two sliding platforms; the pressure regulating mechanism presses the two sliding platforms on the butt joint surfaces in sequence and regulates the size of the gap.

The pipe penetrating mechanism and the automatic pipe penetrating device have the following advantages:

through utilizing capillary blanking machine theory of operation and flexible glue pipe supplied materials mode and material design one set of automatic poling device, reach the labour effect that alleviates operating personnel.

Drawings

FIG. 1 is a schematic structural diagram of an automatic pipe threading device according to the present invention;

FIG. 2 is a schematic structural view of a pipe-piercing mold of the present invention;

FIG. 3 is a top view of the present invention;

FIG. 4 is a schematic view of the slitting device according to the present invention;

fig. 5 is a schematic structural view of the material pulling mechanism of the present invention.

The notation in the figure is:

1. a pipe penetrating mold; 11. a first limiting slideway; 12. a second limiting slideway; 13. positioning a plane; 14. a left die; 15. a right die; 16. a drive device; 2. a slitting device; 21. a cutter; 22. a cutting drive; 23. a translation actuator; 3. an auxiliary mold; 4. a material pulling mechanism; 41. a driving wheel; 42. a driven wheel; 43. a groove; 44. a limiting frame; 441. adjusting the guide rail; 45. a sliding platform; 5. a pressure regulating mechanism; 51. a screw; 52. briquetting; 53. rotating the handle; 6. a guide tube.

Detailed Description

In order to better understand the purpose, structure and function of the present invention, a pipe threading mechanism and an automatic pipe threading device of the present invention are further described in detail below with reference to the accompanying drawings.

As shown in fig. 1, the automatic tube threading device of the invention is used for automatically threading a capillary tube in a soft rubber tube. The automatic pipe penetrating device comprises a pipe penetrating mechanism and a conveying mechanism.

As shown in fig. 2 and 3, the pipe threading mechanism includes a pipe threading mold 1. Two sections of limiting slide ways are respectively formed at two ends of the pipe penetrating die 1, wherein a first limiting slide way 11 is used for inserting a capillary pipe, and a second limiting slide way 12 is used for allowing a soft rubber pipe to enter. The first limiting slide way 11 and the second limiting slide way 12 are coaxially arranged and communicated with each other, the pipe penetrating die 1 forms a positioning plane 13 at the joint of the two limiting slide ways, and the positioning plane 13 is used for being abutted to the inserted soft rubber pipe. When the capillary and the soft rubber pipe are respectively inserted into the limiting slide ways and reach the joint of the two limiting slide ways, the positioning plane 13 props against the soft rubber pipe to make the soft rubber pipe static, and the capillary continues to move and is inserted into the soft rubber pipe to realize pipe penetration.

In order to ensure that the surface of the soft rubber tube does not directly contact with the capillary tube, the joint of the positioning plane 13 and the first limiting slideway 11 is chamfered with a round angle. In order to facilitate the entry of the flexible glue tube into the tube threading die 1, a horn mouth is formed at the inlet end of the second limiting slide way 12.

The pipe penetrating die 1 comprises a left die 14, a right die 15 and a driving device 16, wherein profiles are respectively formed on the adjacent surfaces of the left die 14 and the right die 15, and the driving device 16 enables the left die 14 and the right die 15 which are symmetrically arranged to be mutually abutted, so that the profiles of the left die 14 and the right die 15 are spliced to form the limiting slide way. The setting of spacing slide of having so convenient for, when drive arrangement 16 with left mould 14 and right mould 15 separation, the finished product that the poling was accomplished can directly drop, accomplishes the drawing of patterns moreover. Generally, the driving device 16 is a pneumatic finger, and the left mold 14 and the right mold 15 are respectively fixedly connected with two clamping jaws of the pneumatic finger, so as to drive the left mold 14 and the right mold 15 to be separated or folded.

The automatic pipe penetrating device is adjacent to the capillary blanking machine, the capillary blanking machine pushes the straight capillary of one section into the first limiting slide way 11 in sequence, and therefore the capillary blanking machine is possibly too fast, and the front half section and the rear half section of the two sections of capillaries penetrate into one soft rubber pipe.

In order to solve the above problems, referring to fig. 4, a cutting device 2 is arranged at the lower side of the automatic pipe penetrating device, the cutting device 2 comprises a cutter 21 and a cutting driver 22, the cutter 21 is driven by the cutting driver 22 to move to one side of the inlet end of the second limiting slide 12, and the soft rubber pipe is divided; the side of the cutter 21 is used for abutting against the capillary tube, so that the capillary tube and the corresponding soft rubber tube are prevented from being dislocated, and the technical problem is solved. And the flexible glue pipe blanking machine is prior art, and this embodiment is not repeated.

In order to manufacture finished products with different lengths, at least one auxiliary die 3 is arranged on one side of the pipe penetrating die 1, a third limiting slide way communicated with the second limiting slide way 12 is formed in the auxiliary die 3, the third limiting slide way and the second limiting slide way 12 are arranged in an equal-diameter and coaxial mode, and therefore the soft rubber pipes firstly enter the third limiting slide way and then enter the second limiting slide way 12. Gaps are formed between the auxiliary die 3 and the pipe penetrating die 1 and between the adjacent auxiliary dies 3, and the cutter 21 is inserted into the gaps, so that the soft rubber pipe is divided. While the slitting device 2 comprises a translation drive 23, the cutting drive 22 is mounted on the translation drive 23 so as to align the cutting knife 21 with one of the gaps for the manufacture of finished products of different lengths. Typically, the cutting drive 22 is a pneumatic cylinder and the translation drive 23 is a lead screw slide. The mounting structure of cylinder and lead screw slip table is prior art, and this embodiment is no longer repeated. The auxiliary die 3 also comprises a left die 14, a right die 15 and a driving device 16, which are similar to the pipe penetrating die 1, and the description of the embodiment is omitted.

As shown in fig. 5, the automatic pipe threading device further includes a material pulling mechanism 4, the material pulling mechanism 4 includes a driving wheel 41 and a driven wheel 42, the driving wheel 41 and the driven wheel 42 are used for clamping the soft rubber pipe, so as to drive the soft rubber pipe to move forward, and a gap between the driven wheel 42 and the driving wheel 41 is flush with the second limiting slide 12. The driving pulley 41 and the driven pulley 42 are nylon wheels and are formed with a positioning groove 43 on the surface to increase friction. In order to ensure that the flexible rubber hose entering the mold has no elastic deformation, the driving wheel 41 and the driven wheel 42 are provided with a front group and a rear group, and the rotating speeds of the two groups of driving wheels 41 are the same.

In order to adjust the friction force of the nylon wheel on the flexible rubber hose, the pulling mechanism 4 further comprises a limiting frame 44, an adjusting guide rail 441 is formed on the limiting frame 44, two sliding platforms 45 are sequentially connected in the adjusting guide rail 441 in a sliding manner, and the driving wheel 41 and the driven wheel 42 are respectively connected to the two sliding platforms 45 in a rotating manner; one end of the sliding platform 45 is provided with an abutting surface, the other end is provided with a pressure regulating mechanism 5, and when the driving wheel 41 and the driven wheel 42 are contacted with each other, a gap is formed between the two sliding platforms 45; the pressure regulating mechanism 5 sequentially presses the two sliding platforms 45 on the abutting surfaces, and adjusts the size of the gap so as to adjust the friction force of the nylon wheel to the flexible rubber hose.

The pressure regulating mechanism 5 is generally a screw 51, the screw 51 is in threaded connection with the limiting frame 44, one end of the screw 51, which extends into the limiting frame 44, is rotatably connected with a press block 52, the press block 52 is in sliding connection with the adjusting guide rail 441, and the press block 52 slides along the adjusting guide rail 441 and extrudes the two sliding platforms 45 along with the rotation of the screw 51. The end of the screw 51 extending out of the limiting frame 44 is provided with a rotating handle 53 so as to rotate the screw 51.

In order to ensure that the soft rubber tube is straight and not bent after being drawn out from the coil stock feeding frame, the automatic tube penetrating device comprises a guide tube 6, and the guide tube 6 and a second limiting slide way 12 are coaxially arranged and are used for the insertion of the soft rubber tube. The guide pipe 6 can be fixedly connected to one side of the upstream of the material pulling mechanism 4 and between the material pulling mechanism 4 and the die, so that the flexible glue pipe is prevented from being in a straight line in the transmission process.

Therefore, the flexible rubber tube is inserted into the second limiting slide way 12 through the material pulling mechanism 4, and the capillary tube is inserted into the first limiting slide way 11 by the existing capillary tube blanking machine; when the soft rubber tube is abutted against the positioning plane 13, the cutting knife 21 cuts the soft rubber tube; the capillary tube continues to advance and completes tube penetration in the tube penetrating die 1; the capillary tube is just inserted into the soft rubber tube due to the limit of the cutter 21; the mold is opened by the drive 16, the product is allowed to fall freely and continue to flow downstream of the line.

It is to be understood that the present invention has been described with reference to certain embodiments, and that various changes in the features and embodiments, or equivalent substitutions may be made therein by those skilled in the art without departing from the spirit and scope of the invention. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the invention without departing from the essential scope thereof. Therefore, it is intended that the invention not be limited to the particular embodiment disclosed, but that the invention will include all embodiments falling within the scope of the appended claims.

Claims

1. A pipe penetrating mechanism is characterized by comprising a pipe penetrating mold (1), wherein two ends of the pipe penetrating mold (1) are respectively provided with two sections of limiting slideways, and a first limiting slideway (11) and a second limiting slideway (12) are coaxially arranged and are communicated with each other; wherein the first limiting slide way (11) is used for inserting a capillary tube, and the second limiting slide way (12) is used for allowing a soft rubber tube to enter; the pipe threading die (1) forms a positioning plane (13) at the joint of the two sections of limiting slideways, and the positioning plane (13) is used for being abutted to the soft rubber pipe, so that when the positioning plane (13) abuts to the soft rubber pipe and the soft rubber pipe is static, the capillary pipe continues to move and is inserted into the soft rubber pipe, and pipe threading is realized.

2. A mechanism according to claim 1, wherein the junction of the locating surface (13) and the first stop ramp (11) is rounded.

3. The pipe threading mechanism according to claim 1, characterized in that the pipe threading die (1) comprises a left die (14), a right die (15) and a driving device (16), wherein the left die (14) and the right die (15) are respectively provided with molded surfaces on the adjacent surfaces, and the driving device (16) enables the left die (14) and the right die (15) which are symmetrically arranged to be abutted against each other, so that the molded surfaces of the left die (14) and the right die (15) are spliced to form the limiting slideway.

4. The pipe threading mechanism of claim 1, characterized in that a slitting device (2) is arranged on one side of the automatic pipe threading device; the slitting device (2) comprises a cutter (21) and a cutting driver (22), wherein the cutter (21) is driven by the cutting driver (22) to move to one side of the inlet end of the second limiting slide way (12) so as to divide the soft rubber pipe.

5. A tube threading arrangement according to claim 4, characterized in that the side of the cutting knife (21) is adapted to abut against the capillary tube.

6. The pipe penetrating mechanism according to claim 4, wherein at least one auxiliary die (3) is arranged on one side of the pipe penetrating die (1), a third limiting slide way is formed in the auxiliary die (3), and the third limiting slide way and the second limiting slide way (12) are arranged in an equal-diameter and coaxial mode and are communicated with each other.

7. The pipe threading mechanism according to claim 6, characterized in that gaps are formed between the auxiliary die (3) and the pipe threading die (1), and between adjacent auxiliary dies (3); the gap is used for inserting a cutter (21) so as to divide the soft rubber tube.

8. A threading mechanism according to claim 7, characterized in that the slitting device (2) comprises a translation drive (23), the cutting drive (22) being mounted on the translation drive (23), the translation drive (23) moving the cutter (21) and aligning the cutter (21) with one of the gaps.

9. An automatic pipe threading device, characterized by comprising a pipe threading mechanism according to any one of claims 1 to 8.

10. The automatic pipe threading device according to claim 9, characterized by further comprising a material pulling mechanism (4); the material pulling mechanism (4) comprises a driving wheel (41) and a driven wheel (42), the driving wheel (41) and the driven wheel (42) are used for clamping the soft rubber pipe, so that the soft rubber pipe is driven to move forwards, and a gap between the driven wheel (42) and the driving wheel (41) is parallel and level with the second limiting slide way (12).

11. An automatic pipe threading device according to claim 10, characterized in that the driving wheel (41) and the driven wheel (42) are provided in tandem two groups, the driving wheels (41) of the two groups having the same rotational speed.

12. The automatic pipe threading device according to claim 10, characterized in that the material pulling mechanism (4) comprises a limiting frame (44); an adjusting guide rail (441) is formed on the limiting frame (44), two sliding platforms (45) are sequentially connected in the adjusting guide rail (441) in a sliding manner, and the driving wheel (41) and the driven wheel (42) are respectively connected to the two sliding platforms (45) in a rotating manner; one end of the sliding platform (45) is provided with a butting surface, and the other end is provided with a pressure regulating mechanism (5); when the driving wheel (41) and the driven wheel (42) are contacted with each other, a gap is formed between the two sliding platforms (45); the pressure regulating mechanism (5) sequentially presses the two sliding platforms (45) on the abutting surfaces and regulates the size of the gap.