KR101448845B1 - tube end expanding device - Google Patents

Abstract

The present invention relates to an expansion pipe expansion device for expanding the end portion of a fluid transfer pipe and improving the airtightness maintaining performance of the fluid transfer pipe by processing the inner and outer sides of the end portion of the fluid transfer pipe into a flat surface. According to the expansion pipe of the present invention, since the end portions of the fluid transfer pipe have the same thickness and the inner and outer side surfaces are processed in a planar state, the adhesion of the brake block to the periphery of the inflow hole can be improved and the airtightness maintenance performance of the pipe can be improved.

Description

Tube end expanding device

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an expansion pipe expansion device for expanding one end of a fluid transfer pipe for maintaining the hermeticity of a pipe for transferring a fluid used in a braking device of a vehicle.

The hydraulic brake device of a vehicle applies the principle of pushing the brake block using the fluid pressure.

In order to supply fluid to the block of the braking device, the fluid transferring pipe and the inflow hole of the block of the braking device must be connected. When connecting the inlet port of the block of the fluid transfer pipe and the brake unit, it is essential to maintain the airtightness of the connection point so that the fluid does not leak to the outside. If airtightness is not maintained, fluid moving through the fluid transfer pipe leaks out, causing malfunction of the brake device and contaminating peripheral parts.

Therefore, it is necessary to improve the airtightness maintenance of the connection portion by connecting the end portion of the tube by a certain degree so as to maintain the airtightness. However, conventional expansion pipes have had limitations in meeting these demands.

As an example of a device for expanding the inner diameter of a tube, there is a technique disclosed in Japanese Utility Model Laid-Open No. 20-2007-0000395.

SUMMARY OF THE INVENTION The present invention has been conceived in order to solve the problems of the prior art described above, and it is an object of the present invention to provide an apparatus and a method for expanding an end portion of a fluid transfer tube and processing the inner side surface of the end portion of the fluid transfer tube into a flat surface, And to provide an expansion pipe system for machining the end portion of the fluid transfer pipe so as to improve the flow rate.

The above object of the present invention can be achieved by providing an apparatus and a method for manufacturing a fluid communication device, which comprises a support groove formed in a straight line for supporting a fluid transfer tube on one side of each of the support grooves and an expansion groove having an inner diameter larger than an inner diameter of the support groove, Wherein the upper block and the lower block are coupled through a guide rod such that the upper block and the lower block are linearly elevated with respect to the lower block, An elevating portion for elevating and lowering the upper block of the tube fixing portion with respect to the lower block, and an expanding portion having a shape gradually increasing in outer diameter formed at one end thereof, And a conveying member for reciprocating the conveying rod on which the press block is mounted and a conveying member Lt; / RTI >

Preferably, the expansion pipe further comprises a positioning arm having a rotary arm for positioning the expansion groove of the tube-fixing unit in front of the expansion groove, and a contact portion provided on the rotary arm so that the end of the tube can contact the end Do.

In addition, it is preferable that the expanding protrusion is formed into a curved surface whose rear end gradually increases in outer diameter, and the curved surface is connected to the pressing surface.

Further, it is preferable that the feed rod is movable forward and backward and can be rotated by the motor.

According to the expansion pipe of the present invention, since the end portion of the fluid transfer pipe is expanded and at the same time, the end portion of the fluid transfer pipe is spread radially, the end portion of the expanded pipe surely covers the inflow hole of the brake block, So that the airtightness maintaining performance is improved.

In addition, when the end portion of the fluid transfer pipe is formed in a flat state so as to have the same thickness, the end portion of the fluid transfer pipe and the periphery of the inflow hole of the brake block are improved in adhering the end portion of the fluid transfer pipe to the brake block, It is possible to improve the airtightness maintaining performance of the air conditioner.

Further, since the compression surface of the compression block rotates and the inner side surface of the end portion of the fluid transfer pipe rubs against the compression surface after the compression is performed, even the minute irregularities on the inner surface can be removed. Thus, the connection between the fluid transfer pipe and the inflow hole The airtightness maintaining performance of the region can be further improved.

1 is a front view of the expansion pipe system according to the first embodiment of the present invention,
2 is a perspective view of the expansion pipe system according to the first embodiment of the present invention,
3 is a side cross-sectional view of the tube fixing part of the expansion pipe according to the first embodiment of the present invention,
FIG. 4 is a perspective view of a lower block of a pipe fitting portion of the expansion pipe system according to the first embodiment of the present invention,
5 is a side view showing a compression block of the expansion pipe system according to the first embodiment of the present invention,
6 is a perspective view of a compression block of the expansion pipe system according to the first embodiment of the present invention,
7 is a view showing a position setting unit and a peripheral configuration of the expansion pipe system according to the first embodiment of the present invention,
FIG. 8 is a side view of a pipe-fitting state of the expansion pipe system according to the first embodiment of the present invention,
9 is a side cross-sectional view showing a state in which an end portion of a pipe of the expansion pipe is formed according to the first embodiment of the present invention,
10 is a side sectional view showing a state in which a fluid transmission pipe formed by the expansion pipe according to the first embodiment of the present invention is coupled to a brake block,
11 is a partial cross-sectional view showing a transfer rod and a peripheral structure for transferring the compression block of the expansion pipe according to the second embodiment of the present invention,
12 is a view illustrating a process of changing the shape of an inner surface of an end portion of a pipe by the expansion pipe according to the second embodiment of the present invention.

Hereinafter, the configuration of the expansion pipe according to the first embodiment of the present invention will be described in detail with reference to the accompanying drawings.

The expansion pipe according to the first embodiment of the present invention includes a tube fixing part 10 for fixing the fluid transfer tube 1, a lifting part 20 for lifting the upper block of the tube fixing part 10, 10, and a conveying member 30 for conveying the pressing block 40. The conveying member 30 is provided with a positioning unit 50,

The tube fixing part 10 is for fixing the fluid transfer tube 1 to be expanded and includes a lower block 11 fixed to the base 5 and a lower block 11 from above the lower block 11 And an upper block 16 coupled to the upper block 16. The lower block 11 and the upper block 16 are connected to each other through the guide rod 6 and the guide hole 7 and can move up and down in a straight line.

The lower surface of the upper block 16 and the upper surface of the lower block 11 are respectively formed with support grooves 12 and 17 for inserting a part of the fluid transfer tube 1 to support the fluid transfer tube 1. [ The support grooves 12, 17 extend in a straight line and have a substantially semicircular cross-sectional shape. Extended grooves 13 and 18 are formed at one end of the support grooves 12 and 17 so as to be connected to the support grooves 12 and 17, respectively. The expansion grooves 13 and 18 are formed so that the inner diameter increases as the outer surface 14 and 19 of the upper block 16 and the lower block 11 become closer to each other. The outer side surfaces 14 and 19 of the upper block 16 and the lower block 11 adjacent to the extending grooves 13 and 18 are formed in a plane perpendicular to the extending direction of the supporting grooves 12 and 17. [

The elevating portion 20 is constituted by a lifting lever 21 and a lifting bar 23 and the lifting bar 23 is coupled to the upper block 16 to move up and down the upper block 16. When the upper block 16 and the lower block 11 come into close contact with each other, the fluid transfer tube 1 is fixed and the upper block 16 and the lower block 11 are separated from each other, the fixing of the fluid transfer tube 1 is released. The elevating rod 23 ascends and descends in accordance with the operation of the elevating lever 21.

The transfer member 30 is provided with a piston-cylinder mechanism that is actuated by hydraulic pressure or pneumatic pressure to advance and retract the transfer rod 32. The transfer member 32 is provided at the front end of the transfer rod 32 to extend the end portion of the fluid transfer tube 1 And a compression block 40 is mounted.

The compression block 40 is configured to compress the end portion of the fluid transfer tube 1 to expand the end portion of the fluid transfer tube 1. [ The pressing block 40 is formed at its front end with an expanding projection 42 and at the rear end of the expanding projection 42 with a flat pressing surface 45 perpendicular to the central axis of the expanding projection 42. The compression block 40 is detachably mounted to the transfer rod 32 through bolt fixing or the like. Therefore, the compression blocks 40 having different sizes and shapes can be used as needed.

The front end of the expanding projection 42 is formed into a conical shape whose outer diameter gradually increases, the middle portion extending from the front end has the same outer diameter and the rear end portion 43 extending beyond the middle portion is formed into a curved surface gradually increasing in outer diameter, The curved surface is connected to the pressing surface 45 and smoothly runs without a step.

The position setting unit 50 is provided on the side of the base 5 below the tube fixing unit 10 and is used to set a position at which the fluid transfer tube 1 is fixed. The position setting section 50 is constituted by a contact section 52 provided at the end of the rotary arm 51 and the rotary arm 51 and a stopper 55 for restricting the rotation of the rotary arm 51. The contact section 52 is rotated And is screwed to the arm 51 so as to be movable forward and backward with respect to the rotary arm 51. When the rotary arm 51 is rotated, the rotary arm 51 is rotated and then caught by the stopper 55. When the rotary arm 51 is caught by the stopper 55, the rotary arm 51 is raised vertically with respect to the base 5. The position at which the end of the fluid transfer tube 1 touches the abutting portion 52 of the positioning portion 50 by pushing the fluid transfer tube 1 in a state where the rotary arm 51 is erected perpendicularly to the base 5, So that it becomes a position for fixing the sending pipe 1.

When the contact portion 52 is advanced or retracted with respect to the rotary arm 51, the length of the fluid transfer tube 1 protruded from the tube fixing portion 10 can be adjusted, and when the length of the protrusion of the fluid transfer tube 1 is increased The expanded portion of the fluid transfer tube 1 becomes large, and if the protruded length is small, the expanded portion of the fluid transfer tube 1 becomes small.

Hereinafter, the use method and operation of the expansion pipe system according to the first embodiment of the present invention will be described.

The lifting lever 21 is lifted to raise the upper block 16 of the tube fixing part 10 and position the fluid transfer tube 1 in the support grooves 12 and 17 of the lower block 11. [

The fluid transfer tube 1 placed in the support grooves 12 and 17 is moved in a state where the rotary arm 51 of the position setting section 50 is vertically erected so that one end of the fluid transfer tube 1 is positioned at the position setting section 50 (Not shown). When the positioning of the fluid transfer tube 1 is completed, the rotary arm 51 of the position setting unit 50 is lowered.

The lifting lever 21 is lifted and the upper block 16 is lowered to fix the fluid transfer pipe 1 to the support grooves 12 and 17 of the upper block 16 and the lower block 11.

When the transfer rod 32 of the transfer member 30 is advanced in a state where the position of the fluid transfer tube 1 is fixed, the expanding projection 42 of the compression block 40 passes through the center of the fluid transfer tube 1 And the compression surface 45 of the compression block 40 is in a state of being in close contact with the upper surface 16 of the tube fixing part 10 and the outer surfaces 14 and 19 of the lower block 11. [ At this time, in the fluid transfer pipe 1, the portion adjacent to the upper block 16 and the enlarged grooves 13, 18 of the lower block 11 is expanded to a shape in which the inner diameter gradually increases by the expanding projections 42, The end of the fluid transfer pipe 1 is radially unfolded by the rounded rear end portion 43 of the expanding projection 42 and the pressing face 45. [

The ends of the radially expanded fluid transfer tube 1 are squeezed by the pressing surface 45 of the squeezing block 40 and the outer surfaces 14 and 19 of the upper block 16 and the lower block 11. [ The compressed portion of the fluid transfer tube 1 has the same thickness and the outer surface 14 of the upper block 16 and the lower block 11 , 19 are planes, the inner side surface 3 and the outer side surface 4 of the pressed portion of the end portion of the fluid transfer pipe 1 are formed close to the plane.

The pipe 1 having the above-described expansion is used as the fluid transfer pipe 1 for supplying the fluid to the hydraulic braking device of the vehicle.

FIG. 10 is a side cross-sectional view showing a state in which a fluid transmission pipe formed by the expansion pipe according to the first embodiment of the present invention is coupled to a brake block. 10, an inflow hole 101 is formed in the brake block 100 in which the fluid enters, so that the fluid communication pipe 1 is fixed to the block 100 so as to be connected to the inflow hole 101 . A coupling bolt 105 having a female thread formed on the inner wall of the groove around the inflow hole 101 of the block 100 is coupled to the groove so that the end of the fluid transfer tube 1 is inserted into the groove of the inflow hole 101 .

Since the ends of the fluid transfer pipe 1 processed through the expansion pipe according to the present invention have the same thickness and at the same time the inner side surface 3 and the outer side surface 4 are formed in a flat surface, So that the airtightness can be reliably maintained. In particular, since the inner surface 3 of the end of the pipe 1 is flat, it is completely brought into close contact with the surface adjacent to the inflow hole 101, so that the airtightness is reliably ensured.

Hereinafter, the expansion pipe system according to the second embodiment of the present invention will be described.

11 is a partial cross-sectional view showing a transfer rod and a peripheral structure for transferring a compression block of the expansion pipe according to the second embodiment of the present invention. 11, the expansion pipe according to the second embodiment of the present invention is structured such that the transfer rod 60, which is operated by the piston-cylinder mechanism for transferring the compression block 40, Can be rotated. A guide groove 61 is formed around the feed rod 60 and a protruding portion 66 inserted into the guide groove 61 is formed in the feed bar pre-portion 65. The feed bar pre- Teeth 67 may be formed and rotated by a driving gear 70 connected to a motor (not shown). The feed rods 60 can be slid and moved in the forward and backward directions relative to the feed rods 65 by the guide grooves 61 of the feed rods 60 and the projections 66 of the feed rods 65, When the front portion 65 is rotated, the feed rod 60 is rotated.

In addition to the above-described configuration, various known techniques known to those skilled in the art can be used for the configuration for rotating the transfer rod 60.

The expansion pipe according to the second embodiment of the present invention is the same as the expansion pipe according to the embodiment of the present invention shown in Figs. 1 to 7, except that the transfer rod 60 is rotatably installed.

The use method and operation of the expansion pipe system according to the second embodiment of the present invention are as follows.

When the transfer rod 60 of the transfer member 30 advances in a state where the fluid transfer tube 1 is fixed to the tube fixing unit 10 and the expanding projection 42 of the compression block 40 is inserted into the fluid transfer tube 1, And the pressing surface 45 of the pressing block 40 is in close contact with the upper surface 16 of the tube fixing part 10 and the outer surfaces 14 and 19 of the lower block 11. [ At this time, the end of the fluid delivery pipe 1 is expanded by the expanding protrusion 42 and the expanded end thereof is deflected radially by the rounded rear end portion 43 of the expanding protrusion 42 and the pressing face 45 The pressing face 45 of the pressing block 40 presses a portion of the end of the radially spreading fluid conveying pipe 1 and presses the side face of the upper block 16 and the lower block 11, The unfolded end of the sending pipe 1 is squeezed. The unfolded end of the fluid transfer tube 1 is compressed by the side surface of the upper block 16 and the side surface of the lower block 11 to the flat surface having the same thickness.

In a state where the pressing by the pressing block 40 is completed, the feeding rod 60 starts rotating. The compression block 40 maintains the compression of the end portion of the fluid transfer tube 1 even while the transfer rod 60 is rotating. The pressing surface 45 is rotated in a state in which the pressing face 45 of the pressing block 40 presses the inner side face 3 of the end portion of the fluid transfer pipe 1 so that the end face of the end portion of the fluid transfer pipe 1 The inner side surface 3 is smoothly processed by the friction with the pressing surface 45. Therefore, fine irregularities on the inner surface 3 of the end portion of the pipe 1 can also be removed.

According to the second embodiment of the present invention, as shown in Fig. 12, by primarily pressing the compression block 40 through the compression surface 45, the end portion of the fluid transfer pipe 1 The concave and convex portions of the inner side surface 3 are almost completely removed by rotating the pressing surface 45 in close contact with the inner side surface 3 and the inner side surface 3 is processed into a flat surface having the same thickness, The inner surface 3 of the end portion of the pipe 1 is in a smooth flat state with almost no irregularities.

Here, the rotation of the transfer rod 60 senses the position of the transfer rod 60, and the rotation of the transfer rod 60 can be started when the transfer rod 60 advances to a specific position. In addition, when the pressing block 40 is pressed, the pressure applied to the pressing block 40 increases, so that the pressure of the pressing block 40 is sensed to start the rotation of the feeding rod 60.

According to the second embodiment of the present invention, the end portion of the fluid transfer pipe 1 is a plane having the same thickness, and the inner side surface 3 of the end portion of the fluid transfer pipe 1 is smoothly flat It is possible to reliably maintain the airtightness of the connecting portion of the fluid transfer pipe 1 and the brake block when used in the brake device described above.

According to the second embodiment of the present invention, the compression surface 45 of the compression block 40 is rotated in close contact with the inner surface 3 of the fluid transfer pipe 1 while the fine unevenness of the inner surface 3 Lt; / RTI > In the case where the inner side surface 3 has fine irregularities, it is difficult to completely remove fine irregularities by only pressing by the pressing surface 45. Therefore, after the compression of the compression surface 45 of the present invention is performed, the compression surface 45 is further pressed against the inner surface 3 of the end of the pipe 10 to rotate the inner surface 3, The fine irregularities of the inner surface 3 can be almost completely removed to make the inner surface 3 smooth.

And the upper surface of the upper block is connected to the upper surface of the upper block so that the lower surface of the upper surface of the upper surface of the upper surface of the upper surface of the upper surface of the upper surface of the upper surface of the upper surface of the upper surface of the upper surface of the upper surface of the upper surface is connected to the lower surface. 50 position setting section, 51 rotary arm, 52 contact section

Claims (4)

Each of which has a straight support groove for supporting the fluid transfer tube and an extension groove having an inner diameter larger than the inner diameter of the support groove at one end of the support groove, Wherein the upper block and the lower block are coupled through a guide rod such that the upper block and the lower block can be linearly moved up and down with respect to the lower block;
An elevating part for elevating the upper block of the tube fixing part with respect to the lower block;
And a rear end portion of the expanding protrusion is formed into a curved surface gradually increasing in outer diameter, and the curved surface is formed on a pressing surface which is flat in a direction perpendicular to the extending direction of the expanding projection A compression block that is connected; And
And a conveying member for reciprocating the conveying rod on which the pressing block is mounted,
When the compression block is in close contact with the tube fixing portion, the expansion projecting portion of the compression block expands the fluid transfer tube, and at the same time, the rear end portion of the compression block and the compression surface radially expand the end portion of the fluidizing tube Plane,
And a positioning part having a rotary arm for positioning the expansion groove of the tube fixing part in front of the expansion groove and a contact part provided on the rotary arm so that an end of the tube can contact with the rotary arm. Expansion pipe. delete delete The expansion pipe system according to claim 1, wherein the feed rod is movable forward and backward and rotated by a motor.

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