KR101963418B1 - Tube expanding device for capillary tube - Google Patents

Abstract

The present invention relates to an apparatus to expand a capillary tube, which is used for expanding an end part of a capillary tube made of a copper or aluminum material to a set diameter and, more specifically, to an apparatus to expand a capillary tube, capable of quickly and uniformly expanding the diameter and depth of an expanded part while preventing damage, such as tearing or bursting of the expanded part. According to the present invention, the apparatus to expand a capillary tube comprises: a fixing unit to fix a capillary tube to be expanded; a transfer unit to horizontally transfer the capillary tube fixed in the fixing unit in an axial direction; an expanding unit horizontally transferred to the end side of the capillary tube fixed in the fixing unit by the transfer unit to allow an expanding pin coupled to a fixing unit side to be inserted into the capillary tube while being rotated by a rotating means to expand the inner diameter of the capillary tube by a set diameter and length; and a control unit to control operation of the transfer unit and the rotating means. The expanding pin comprises: a taper part having a side inclined by a set angle to be inserted into the capillary tube; a cutting part having an outer surface cut in a longitudinal direction to come in contact with the taper part; and a clamping part integrated to the rear side of the cutting part to be fixed to the expanding unit.

Description

{TUBE EXPANDING DEVICE FOR CAPILLARY TUBE}

The present invention relates to a capillary tube expansion device used for expanding an end portion of a capillary made of copper or aluminum to a predetermined diameter, and more particularly, to a capillary expansion device used for expanding a diameter of a expansion portion, And a capillary tube expansion device capable of rapidly and uniformly expanding the depth.

Generally, when connecting capillaries to each other, they are welded by using a bushing. However, since this method requires fixing both ends of the capillary so that they are positioned on the same line, the welding should be performed with the bushing accurately positioned on the joint portion It took a lot of time and there was a problem that defects were generated on the welded portion when the welded joint was not fixed accurately.

In order to shorten the working time required to connect the capillaries and to securely connect the connecting portion with the airtightness maintained, a tube portion having an expanded inner diameter is formed on one side of the capillary tube, The welding is performed in a state in which the welding wire is inserted.

However, since the capillary has a very small inner diameter of less than 1 mm, work must be done very precisely and carefully in order to artificially enlarge the inner diameter of such a capillary. As a result, it takes a lot of time to expand the capillary, resulting in poor efficiency and productivity.

Conventionally, as disclosed in Korean Patent Laid-Open Publication No. 10-2009-0012574, a fixing part for fixing a pipe can be installed on one side of a base, and a fixing pipe for fixing a pipe can be rotated on the other side in order to enlarge the inside diameter of the pipe The tool bar and the tool pipe are provided with a transfer part that can be moved forward and backward toward the end of the pipe fixed to the fixing part, and a pipe pipe expansion device is proposed in which a rotating pipe is inserted into the end part of the pipe, .

However, since the expansion pipe is expanded by the rotational force of the pipe and the force transmitted to the pipe, it is possible to prevent the pipe from being deformed by the frictional heat when the inner circumferential surface of the pipe contacts the rotating pipe, The end of the pipe is torn due to the fact that the outer circumferential surface of the pipe is forcedly inserted into the pipe in a state where the outer circumferential surface of the pipe is in contact with the inner circumferential surface of the pipe even if the pipe is expanded with lubricant supplied to the inner surface of the pipe end or the outer circumferential surface of the pipe. There is a problem that damage such as breakage or cracking occurs.

In addition, Korean Patent Laid-Open Publication No. 10-2014-0125236 discloses an oil pipe which is formed along the axial direction of an expanding shaft so as to reduce thermal deformation of the pipe to be expanded, and an oil supplying oil to the inside of the pipe through the oil pipe A pipe expansion system with a supply part has been proposed.

However, there is also a problem that the end portion is damaged due to the expansion of the expansion shaft by the pressure of the expansion shaft which is driven forward while the outer surface of the expansion shaft is in contact with the inner surface of the pipe, and the oil discharged through the oil pipe of the expansion shaft Since the oil is discharged not in a wide range but in the axial direction of the expanding shaft, there is a problem that the oil is unnecessarily wasted in a state in which the frictional heat due to the oil can not be reduced.

Korean Patent Laid-Open No. 10-2009-0012574 (Oct. 1, 2009) Korean Patent Laid-Open Publication No. 10-2014-0125236 (May 12, 2015)

SUMMARY OF THE INVENTION Accordingly, the present invention has been made keeping in mind the above problems occurring in the prior art, and it is an object of the present invention to provide a capillary tube which can easily insert a widening pin into an end portion of a capillary tube and prevent damage And a capillary tube expansion device capable of rapidly and accurately expanding the capillary tube to a predetermined diameter and length.

In order to achieve the above-mentioned object, the present invention provides a capillary tube including a fixing portion formed to fix a capillary to be expanded, a transfer portion formed to be moved in the axial direction of the capillary fixed to the fixing portion, And a control unit for controlling the driving of the fixing unit, the conveying unit, and the rotating unit, and a control unit for controlling the driving of the fixing unit, the conveying unit, and the rotating unit Wherein the expanding pin has a tapered portion formed at an angle to be inserted into the capillary and inclined at a predetermined angle, a cutting portion having an outer surface tinged with the tapered portion cut in the longitudinal direction, and a rear portion integrally formed at the rear of the cutting portion, And a clamping part fixed to the clamping part.

Here, it is preferable that two or more cutting portions are formed at equal intervals on the outer surface of the expanding pin.

The expanding portion may include an expanding shaft installed coaxially with the capillary fixed to the fixed portion and formed to be rotated about the axial direction by the rotating means, and an expansion shaft provided at the end of the expanding shaft, And a heat dissipating member installed on an outer surface of the expansion shaft to prevent heat generated in the expansion pin from being transmitted to the expansion shaft.

In addition, a plurality of sensor units for sensing a position where the expanded portion is transported in the forward and backward directions are provided at one side of the transport unit, and a movement distance limiting sensor for limiting the transport distance of the expanded portion is installed at the foremost and the last, Preferably, a shift position detecting sensor is provided between the movement distance limiting sensors for detecting a time point at which the transport speed changes while the expanding portion is being transported to the stationary portion.

The capillary tube is guided to be positioned at the same end of the capillary tube fixed to the fixed portion and is moved upward or downward to prevent the tube tube from being interfered with entering the capillary tube during forward movement. And a guide portion formed to be in contact with the guide portion.

The guiding portion may include a guiding block provided at one side of the bending portion and having a sloped surface inclined at a predetermined angle and a horizontal surface inclined to the inclined surface. The guiding block may be moved along the inclined surface of the guiding block A guide shaft installed on the guide bar and configured to rotate in the forward and reverse directions as the guide roller reciprocates between the inclined surface of the guide block and a horizontal plane; And a guide plate formed to contact an end surface of the capillary fixed to the fixing portion in a state where the expanding portion is retreated and to be upwardly or downwardly rotated together with the guide shaft when the expanding portion is advanced.

As described above, the capillary expansion device according to the present invention can smoothly insert the end portion of the expansion pipe into the end portion of the capillary by tapering the end portion of the expansion pipe, cut the outer surface of the expansion pin into the direction of insertion into the capillary, The capillary tube can be expanded to a predetermined diameter and length while preventing damage such as tearing or cracking. In addition, the capillary tube can be always fixed at the same position, and the tube can be rapidly and accurately expanded to a uniform size. It is possible to increase the productivity.

1 is a perspective view showing a capillary expansion apparatus according to the present invention,
2 is a plan view showing a capillary expansion apparatus according to the present invention,
FIG. 3 is a perspective view illustrating a widening pipe according to the present invention,
FIG. 4 is a perspective view illustrating a capillary tube according to an embodiment of the present invention,
FIG. 5 is a perspective view sequentially illustrating a process of expanding and expanding a widening pin according to the present invention,
FIG. 6A is a perspective view showing a guide portion in a state in which the expanding portion is retracted according to the present invention, FIG.
FIG. 6B is a perspective view showing a guide portion in a state in which the expansion portion according to the present invention is advanced.

Hereinafter, the capillary pipe expansion device according to the present invention will be described in detail with reference to FIGS. 1 to 6B.

1 and 2, the capillary pipe expansion device according to the present invention mainly includes a fixing unit 200, a transfer unit 300, an expansion unit 400, and a control unit 700.

The fixing part 200, the conveying part 300 and the expansion part 400 are installed at a set height from the ground so that the operator can easily work. The fixing part 200, the conveying part 300 And the expansion portion 400 are provided on the upper surface of the support portion 100 formed in a table shape.

The fixing part 200 is formed on one side of the supporting part 100 so as to press and fix the outer surface of the capillary tube C after the end part of the capillary tube C to be expanded is inserted and protruded. It is preferable that fixing grooves are formed on one or both inner surfaces of the fixing part 200 to which the capillary tube C is to be contacted so as to firmly fix the capillary tube C while preventing the capillary tube C from being deformed when the capillary tube C is pressed .

Also, it is preferable that the fixing and releasing operations of the capillary C through the fixing part 200 at this time are formed so as to be automatically operated by the control part 700. [

The transferring part 300 is provided on the other side of the supporting part 100 and moves forward along the axial direction of the capillary C fixed to the fixing part 200 so as to approach the fixing part 200, It is formed to retreat away.

The conveyance unit 300 includes a conveyance rail 310 installed parallel to the axial direction of the capillary C, a conveyance panel 320 installed to guide the conveyance by the conveyance rail 310, The transfer panel 320 may be configured to include a hydraulic cylinder 330 that is installed at a side or a rear side of the transfer panel 320 so as to move forward or backward along the transfer rail 310. In this embodiment, But it is also possible to use a known construction which can move the conveying panel 320 forward and backward including the forward and reverse motors.

The expansion unit 400 is installed to advance or retreat to the end of the capillary C fixed to the fixing unit 200 by the transfer unit 300 and to be connected to the fixing unit 200 The pipe pin 450 is rotated by the rotating means 410 such as a motor to enter the inside of the capillary C fixed to the fixed portion 200 so that the inner diameter of the end portion of the capillary C is expanded to a predetermined diameter and length Respectively.

As shown in FIG. 3, the expansion pin 450 includes a tapered portion 451 which is sloped at a predetermined angle to be inserted into the capillary C, an outer surface facing the tapered portion 451, And a clamping part 453 which is integrally formed at the rear of the cutting part and is fixed to the expansion part 400.

The control unit 700 controls the operations of the fixing unit 200, the transfer unit 300 and the rotating unit 410. That is, the capillary C is fixed by the fixing unit 200, An operation of advancing or retracting the expanding part 400 by the transferring part 300 and an operation of rotating the expanding pin 450 about the central axis by the rotating part 410 are controlled.

The control unit 700 controls the temperature of the expanding pipe 450 during the expansion of the capillary C, the rotation speed of the expansion pipe 450, the feeding speed of the expanding unit 400 by the feeding unit 300, A plurality of sensors for measuring the depth or the like into which the expansion pin 450 is inserted into the capillary C, and a monitor for receiving signals sensed by the sensors and displaying the signals in numerical or graphic form.

The operation effect of the capillary pipe expansion device having the above-described structure will be described as follows.

4, when the start button provided on the controller 700 is pressed in a state where the capillary C to be expanded is sandwiched between the positions set in the fixing unit 200, the fixing unit 200 moves the outer surface of the capillary C And the expanding portion 400 operates so that the expanding pin 450 is rotated at a predetermined speed.

In this case, before fixing the capillary C to the fixing part 200, a lubricant is sprayed on the inner surface of the end part of the capillary C to be expanded, or the end part of the capillary C is dipped in the container containing the lubricant It is preferable that lubricant is applied to the expanding region to reduce the generation of frictional heat at the contact surface between the capillary C and the expansion pin 450 during the expanding operation.

When the fixing operation of the capillary C by the fixing unit 200 is completed, the transfer unit 300 performs an operation to move the expanding unit 400 to move toward the fixed unit 200 side.

Since the center axis of the capillary C fixed to the fixing unit 200 and the central axis of the expansion pin 450 installed in the expansion unit 400 are located on the same line, the expansion unit 400 is positioned on the transfer unit 300 The expansion pin 450 enters the end portion of the capillary C fixed to the fixing portion 200. As a result,

Since the outer diameter of the expansion pin 450 is larger than the inner diameter of the capillary C and enters the capillary C while rotating at a speed set by the expansion portion 400, C can be expanded to the same size as the outer diameter of the expansion pin 450. [

Referring to FIG. 5, the process of expanding the capillary C by the expansion pin 450 will be sequentially described. In the initial state (a), when the expansion pin 450 enters the capillary C, The capillary C begins to be expanded by the tapered portion 451 such that the capillary C begins to be expanded by the tapered portion 451 as shown in FIG. The capillary C is deformed by the portion where the cutting portion 452 is not formed as shown in (d) when the cutting portion 452 further rotates and enters the inside of the capillary C, It is expanded to the same diameter.

By forming the tapered portion 451 at the end of the expansion pin 450 as described above, the expansion pin 450 can smoothly enter the inside of the capillary C and the cutting portion 452 can be smoothly inserted into the tapered portion 451, It is possible to prevent the frictional heat from being excessively generated in the capillary tube C and prevent deformation due to the frictional heat as well as to gradually expand the capillary tube C by the entry of the cutting portion 452, It is possible to prevent damage such as tearing or cracking of the end portion of the core (C).

If the capillary tube 450 is expanded by using the expansion tube 450 having no cut portion 452 as in the prior art, the expansion tube 450 is moved in the state of being in contact with the inside of the capillary tube C Accordingly, when the expanding pin 450 enters at a high speed, damage such as tearing of the end portion of the capillary C is more easily caused by the force.

In order to prevent the tip of the capillary tube C from being damaged, if the entry speed of the fusing pin 450 is slowed down, the productivity is greatly lowered and the frictional heat is more excessively generated on the contact portion, There is a problem that it can not be expanded to a precise thickness. Even if it is enlarged, the thickness of the expanded portion becomes uneven, so that the portion expanded to a thin thickness can not withstand the set pressure,

Since the outer surface of the expansion pipe 450 is in contact with the inner surface of the capillary C all at the same time as the expansion pin 450 enters the inside of the capillary C, This makes it easy to damage the end of the capillary C such as tearing or cracking, and of course it is difficult to expand the capillary C to an exact size. Even if the capillary C is enlarged, the enlarged portion due to the frictional heat expands to a uniform diameter Or the thickness of the expanded region becomes uneven.

As described above, like the expansion pipe 450 according to the present invention, the cutting part 452 is formed in the longitudinal direction on the outer surface connected to the taper part 451, thereby solving the conventional problems as described above.

At this time, the above-mentioned tube-expanding unit 400 is installed on the same axis as the capillary C fixed to the fixing unit 200, and is provided with the expanding shaft 420 A spindle 430 provided at an end of the expansion shaft 420 and fixed with a clamping part 453 inserted therein and a spindle 430 installed at an outer surface of the expansion shaft 420 to prevent heat generated from the expansion pin 450 And a heat dissipating member 440 for preventing the heat dissipation member 440 from being transmitted to the expanding shaft 420.

Even if the frictional heat generated while the expanding pin 450 enters the inside of the capillary C and expands through the heat dissipating member 440 is transmitted to the expanding shaft 420, the heat is quickly radiated to the outside, It is possible to prevent a malfunction and a failure of the apparatus.

On the other hand, a plurality of sensor units 500 are installed at one side of the conveyance unit 300 to sense the position of the expansion unit 400 in the forward and backward directions. In the forward and rearward directions, the conveyance distance of the expansion unit 400 A shift position detecting sensor 510 for detecting a time point at which the conveying speed changes while the expanding portion 400 is being conveyed to the fixing portion 200 side is provided between the moving distance limiting sensors 510, (520) is preferably installed.

At this time, the movement distance limit sensor 510 limits the maximum movement distance that the expanding part 400 can move forward and backward so that the expanding pin 450 can always enter the capillary C with uniform length .

Further, the shift position detecting sensor 520 allows the expanding portion 400 to advance rapidly at the initial stage when the expanding portion 400 is advanced to the fixed portion 200 side, and after the position of the expanding portion 400 is detected by the shift position detecting sensor 520 So that the expanding part 400 can be moved forward and backward to the position of the movement distance limiting sensor 510 installed at the rear end after completing the expanding operation of the capillary C. [

The maximum movement distance of the expansion unit 400 is restricted to the movement distance limit sensor 510 and the speed at which the expansion unit 400 is moved is controlled by the shift position detection sensor 520, And the time required for the movement of the expanding unit 400 is minimized, so that the operation can be performed quickly. In addition, the expansion pipe 450 can be moved in a direction When entering the capillary (C), the capillary (C) is prevented from being damaged, thereby reducing the defective rate of the product, increasing the working efficiency and greatly increasing the productivity.

In addition, the capillary tube 400 is guided such that the end portion of the capillary tube C fixed to the fixing portion 200 is equally positioned on one side of the tube portion 400, The guide part 600 may be installed so as to be upwardly or downwardly pivotally moved so as not to be interrupted by entering the inside of the guide part 600. [

The guide portion 600 fixes the capillary C to the fixed portion 200 at the same position so that the expanding pins 450 entering the capillary C enter the same length, So that the lengths of the capillaries C to be expanded by the expansion pin 450 are all equal to each other even if the capillary C is expanded by fixing the capillary C to the fixing portion 200 alternately. .

6A and 6B, the guide unit 600 includes a guide block 610 provided at one side of the tube-expanding unit 400 and having a sloped surface inclined at a predetermined angle and a horizontal surface inclined to the inclined surface, A guide bar 630 provided at an end of a guide roller 620 moving along the inclined surface and the horizontal plane of the guide block 610 by movement of the expanding part 400 before and after the guide part 610, A guide shaft 640 formed to guide the guide roller 620 in the forward and reverse directions as the guide roller 620 reciprocally moves along the inclined surface and the horizontal surface of the guide block 610, A guide plate 650 is formed so as to be rotated upward or downward together with the guide shaft 640 when the tube portion 400 is moved forward, .

6A, when the extended portion 400 is retreated, that is, when a plurality of sensor units 500 are provided, the movement distance limiting sensor 510 located behind the guide unit 600 The guide roller 620 is brought into contact with the lower portion of the inclined surface of the guide block 610. [

At this time, the guide plate 650 is positioned between the fixed portion 200 and the expanded portion 400. When the capillary C is fixed to the fixed portion 200, the end surface of the capillary C is fixed to the guide plate 650).

6B, the fixing unit 200 fixes the capillary C and the expanding unit 400 is fixed to the fixing unit 200 by the operation of the transferring unit 300, At this time, the guide roller 620, which is in contact with the inclined lower surface of the guide block 610, moves upward along the inclined surface and is positioned on the horizontal surface adjacent to the inclined surface.

Here, the guide bar 630 is raised by the height of the guide block 610 moving along the upper and horizontal surfaces of the inclined surface of the guide block 610, and the guide bar 630 is lifted up The guide shaft 640 rotates about the center axis.

At this time, when the guide roller 620 is positioned on the inclined bottom surface of the guide block 610, the guide roller 620 is positioned between the fixing portion 200 and the expansion portion 400 and fixed to the fixing portion 200 Since the guide plate 650 is provided to limit the position where the end surface of the capillary tube C is protruded, the guide plate 650 also rotates upward as the guide shaft 640 rotates, It is possible to prevent the forward movement of the capillary tube 450 and the expansion pin 450 from entering the end of the capillary C fixed to the fixing portion 200. [

On the contrary, when the expanding part 400 is retreated after the capillary C is expanded, the guide roller 620 is positioned on the horizontal plane and moved to the lower side of the inclined plane. At this time, And the guide shaft 640 rotates in the opposite direction by the guide bar 630. When the guide shaft 640 rotates in the reverse direction, The capillary tube 650 may also be rotated downward to limit the position at which the end surface of the capillary C protrudes.

The upward and downward rotation of the guide bar 630 and the guide plate 650 and the forward and reverse rotation of the guide shaft 640 are interlocked with each other as the expanding unit 400 moves forward and backward, The end portion of the capillary tube C can always be fixed at the same position when the capillary tube C is fixed to the fixing portion 200 while the capillary tube 400 is retracted, The capillary C is expanded to the same length and diameter by repeating the movement of the expanding portion 400 and the expanding operation of the capillary C when the expanding operation is performed while entering the inside of the capillary C It is possible to reduce the time required to fix the capillary C at the same position as well as to increase productivity and productivity.

As described above, the capillary tube expansion device according to the present invention can smoothly insert the end portion of the expansion pipe 450 into the end portion of the capillary C by tapering the outer end of the expansion pin 450, So that the capillary tube C can be always fixed at the same position. In addition, the capillary tube C can be fixed at the same position, So that the efficiency of the work and the productivity of the product can be increased.

100: support part 200:
300: conveying unit 310: conveying rail
320: Transfer panel 330: Hydraulic cylinder
400: expanding part 410: rotating means
420: Expansion shaft 430: Spindle
440: Heat dissipating member 450:
451: Tapered portion 452: Cutting portion
453: Clamping section
500: sensor unit 510: movement distance limit sensor
520: Shift position detection sensor
600: guide portion 610: guide block
620: guide roller 630: guide bar
640: guide shaft 650: guide plate
700:
C: capillary tube

Claims (6)

A fixing unit 200 configured to fix a capillary C to be expanded;
A transfer part 300 formed to be moved in the axial direction of the capillary C fixed to the fixing part 200 before and after the capillary C;
The expansion pipe 450 is installed to be transferred back and forth by the transfer unit 300 and enters the capillary C while being rotated by the rotation means 410 to expand the inner diameter of the capillary C to a predetermined diameter and length. An expanding portion 400 formed on the base plate 400;
The capillary tube 400 is guided so that the end of the capillary tube C fixed to the fixing part 200 is positioned at the same position and the expansion tube 450 is moved forward A guide part 600 formed to be upwardly or downwardly pivoted so as not to be interfered with entering into the capillary C;
And a control unit (700) for controlling the driving of the fixing unit (200), the feeding unit (300), and the rotating unit (410)
The expanding pin 450 has a tapered portion 451 formed at an angle to be inserted into the capillary C and inclined at a predetermined angle and a cutting portion 452 having an outer surface facing the tapered portion 451, And a clamping part (453) integrally formed behind the cutting part and fixed to the expansion part (400).
The method according to claim 1,
Wherein two or more cutting portions (452) are formed at equal intervals on the outer surface of the expanding pin (450).
The method according to claim 1,
The expansion unit 400 includes an expansion shaft 420 disposed coaxially with the capillary C fixed to the fixing unit 200 and configured to rotate about the axial direction by the rotation unit 410, A spindle 430 installed at an end of the expanding shaft 420 and fixed with the clamping unit 453 inserted thereinto and a heat generating unit 450 installed at an outer surface of the expanding shaft 420 to generate heat generated from the expanding pin 450, And a heat dissipation member (440) for preventing the heat from being transmitted to the expansion shaft (420).
The method according to claim 1,
A plurality of sensor units 500 are installed at one side of the conveyance unit 300 to sense the position of the expansion unit 400 in the forward and backward directions. A shift distance limiting sensor 510 is provided between the shift distance limiting sensor 510 and the shift distance limiting sensor 510. The shift distance limiting sensor 510 detects the shift speed during a time period during which the expansion unit 400 is moved to the fixed unit 200, And a sensing sensor (520) is installed.
delete The method according to claim 1,
The guide unit 600 includes a guide block 610 provided at one side of the expansion unit 400 and having a sloped surface inclined at a predetermined angle and a horizontal surface inclined to the inclined surface, A guide bar 630 provided at an end of a guide roller 620 moving along a slope and a horizontal plane of the guide block 610 by a guide roller 620 and a guide roller 620 installed on the guide bar 630, A guide shaft 640 formed on the guide shaft 640 so as to rotate in the forward and reverse directions as the inclined plane and the horizontal plane of the block 610 reciprocate; And a guide plate 650 formed to contact the end surface of the capillary C fixed to the guide 200 and to be pivoted upward or downward together with the guide shaft 640 when the expanded portion 400 is advanced A capillary expansion device characterized by.

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