KR100488165B1 - Device for making hole on hose - Google Patents

Abstract

SUMMARY OF THE INVENTION An object of the present invention is to provide a fountain hose fabricator which is capable of forming holes in various patterns in a fountain hose by focusing the laser beam irradiated from the laser oscillation device in the longitudinal and width directions of the fountain hose. Is in.

Therefore, the present invention is a fountain hose transfer unit for advancing the fountain hose at a constant speed, a laser beam oscillator for producing a laser beam, and located on one side of the fountain hose transfer unit is installed to be rotatable in the longitudinal direction of the fountain hose to reflect the laser beam X-axis reflector mirror, drive motor for rotating the x-axis reflector mirror at a speed synchronized with the fountain hose, and is located on one side of the fountain hose feeder to rotate in the width direction of the fountain hose. Y-axis reflection mirror for irradiating light reflected from the x-axis reflection mirror to the fountain hose surface and connected to the rotation axis of the y-axis reflection mirror to rotate the y-axis reflection mirror one by one according to the machining hole pattern Provides a fountain hose drilling device comprising a step motor for making.

Description

Fountain hose drilling device {Device for making hole on hose}

The present invention relates to a fountain hose drilling apparatus for processing a water jet hole in a fountain hose used to supply related water required for the cultivation of various crops, horticultural crops, and the like.

Fountain hose is a watering material that makes it possible to drill watering holes in soft plastic hoses tightly. It can reduce the labor required for fruiting and the usage is expanding rapidly as the plant area is increased recently.

In order to drill the hole in the hose, as a mechanical process, a roller embedded with a punching needle is pressed onto the hose to process the hole in the hose, and this structure is formed around the perforated hole due to the impact of the physical force generated by the mechanical processing. Fine tearing occurs, which causes the hose to withstand high water pressure and rupture, resulting in the loss of the function of the fountain hose.

Therefore, conventionally, a method of drilling using a laser beam has been proposed in order to prevent the above problems, and Patents 1991-1977 disclose a device for drilling a hole in a watering hose using a laser beam. According to the patent, the laser beam reflected from the polygonal reflecting mirror is processed by passing the laser beam through the connecting lens using one reflector and irradiating the beam through the connecting lens to the polygonal reflecting mirror using another reflecting mirror. It is focused on the hose to form a hole.

However, the conventional technique described above has a problem that holes 101 drilled in the fountain hose 100 are processed only in a line along the moving direction of the hose 100 as shown in FIG. 3.

Since the formation pattern of the hole drilled in the fountain hose varies greatly depending on the type of crops and horticultural crops or the installation location in the facility such as the house, the drilling should be performed not only in the direction of movement of the hose but also in the width direction of the hose. However, in order to drill a plurality of holes in the width direction in the conventional drilling apparatus as described above, it is necessary to branch the laser beam by the number of holes in the width direction and configure the same number of optical systems. Such a system requires a high laser power in proportion to the number of branches and lacks flexibility to cope with the change of the pattern, making it difficult to process holes in various patterns.

Accordingly, the present invention has been made to solve the above problems, by inducing the laser beam irradiated from the laser oscillation device in the longitudinal and width directions of the fountain hose to focus on the fountain hose in various patterns in the fountain hose The purpose is to provide a fountain hose fabricator that can be formed.

It is another object of the present invention to provide a fountain hose fabricator that can process a hole having a uniform size at all times regardless of the position of the hole to be drilled, and to make the shape of the hole to be machined circular.

In order to achieve the object as described above, the present invention, the laser beam irradiated from the laser oscillation device by using the optical system operating in two axes with respect to the fountain hose in the longitudinal direction and the width direction of the fountain hose, It is characterized in that the hole can be processed in a perforated pattern.

To this end, the present invention in the laser drilling device of the fountain hose, the x-axis moving unit for guiding the laser beam irradiated from the laser oscillation device along the moving direction of the fountain hose, and to guide the laser beam in the width direction of the fountain hose It includes a y-axis moving unit for.

The x-axis moving unit includes an x-axis reflecting mirror rotatably installed in the longitudinal direction of the fountain hose and reflecting the laser beam, and a driving motor for rotating the x-axis reflecting mirror in synchronization with the moving speed of the fountain hose. .

The y-axis moving part is rotatably installed in the width direction of the fountain hose so that the y-axis reflecting mirror and the y-axis reflecting mirror are used to irradiate the fountain hose surface with the laser beam reflected from the x-axis reflecting mirror. Therefore, it includes a step motor for rotating by one step.

In addition, the present invention further includes a telecentric scan lens for vertically injecting the laser beam irradiated onto the fountain hose to the fountain hose.

Accordingly, the laser beam is guided through the x-axis moving unit and the y-axis moving unit so that the hole can be processed in a spiral pattern on the fountain hose.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a schematic configuration diagram showing a fountain hose drilling plant according to the present invention, Figure 2 is a schematic diagram showing a pattern of holes drilled in the fountain hose by the drilling device according to the present invention.

According to the above-described drawings, the present invention provides a fountain hose transfer part for advancing the fountain hose 60 at a constant speed, a laser beam oscillator 10 in which a laser beam is produced, and a beam emitted from the laser beam oscillator 10. Telescope 20 for adjusting the diameter, the x-axis reflecting mirror for reflecting the laser beam passing through the telescope 20 is installed in the upper portion of the fountain hose transfer unit is rotatably installed in the longitudinal direction of the fountain hose ( 30), the drive motor 31, which is connected to the rotating shaft of the x-axis reflecting mirror 30 to rotate the x-axis reflecting mirror 30 at a speed synchronized with the fountain hose 60, the upper portion of the fountain hose transfer unit Located and rotatably installed in the width direction of the fountain hose 60, the y-axis reflection mirror 40, the y-axis reflection mirror for irradiating the light reflected from the x-axis reflection mirror 30 to the surface of the fountain hose (60) ( It is connected to the rotating shaft of 40) and according to the spray pattern The laser beam irradiated from the y-axis reflecting mirror 40 located between the step motor 41, the y-axis reflecting mirror 40, and the injection hose 60 for rotating the y-axis reflecting mirror 40 by one step. It includes a telecentric scan lens 50 for injecting the vertical to the surface of the injection hose (60).

The fountain hose transfer part is to advance the fountain hose 60 while maintaining a constant speed and uniform flatness. The fountain roll 60 and the hole 61 in which the wound fountain hose 60 is released are processed. Winding roll 71 for winding the hose 60, drive roll 72 is placed on one side of the fountain hose 60 to advance the fountain hose 60, the main motor 73 for rotation of the drive roll and the hole ( 61) a guide support member 74 for supporting both ends of the fountain hose 60 at the machining position to maintain the flatness uniformly.

The telescope 20 controls the diameter of the beam, that is, the focal size, to control the diameter of the beam according to the size of the hole 61 to be drilled in the fountain hose 60.

On the other hand, the x-axis reflecting mirror 30 is rotated along the xy plane with its rotational axis is located on the z-axis in the drawing, the y-axis reflecting mirror 40 is the rotational axis is located on the x-axis in the drawing yz rotates along the plane.

In addition, the drive motor 31 is operated to be precisely synchronized with the moving speed of the injection hose 60 in accordance with the signal of the control system to rotate the x-axis reflection mirror 30 continuously, the step motor 41 is controlled The y-axis reflection mirror 40 is rotated by one step in response to a cycle which is operated according to the control signal of the system and leads to the rotation and return of the x-axis reflection mirror 30.

Accordingly, the laser beam emitted is reflected and refracted through the x-axis reflecting mirror 30 and the y-axis reflecting mirror 40 to irradiate the fountain hose 60 to form a hole 61 in a predetermined pattern on the surface of the fountain hose 60. It is formed.

That is, when the fountain hose 60 moves for the continuous hole 61 processing, the x-axis reflecting mirror 30 synchronized with the rotating shaft rotates about the rotational axis, thereby continuously changing the reflection angle of the laser beam. By tracking the fountain hose 60 moving through the fixed y-axis reflection mirror 40 it is possible to continuously irradiate the laser beam in one place. In addition, the y-axis reflection mirror 40 varies the reflection angle by one step per cycle of the x-axis reflection mirror 30 so that the position of the hole 61 is formed along the outer circumferential surface with respect to the fountain hose 60. The angle is changed. Accordingly, the hole 61 may be formed in a spiral pattern rather than a longitudinal direction with respect to the fountain hose 60.

Here, one cycle of the x-axis reflection mirror 30 is preferably adapted to the pulse width of the laser beam.

As described above, the present invention may vary the pattern of the holes 61 processed in the injection hose 60 according to the number of rotation steps of the y-axis reflection mirror 40 and the rotation angle and the moving speed of the injection hose 60 during one rotation. As an example, when the number of staff is four and given a rotation angle, as shown in FIG. 2, a pattern of a hole 61 having a set of four holes 61 formed at different positions can be obtained. do.

Meanwhile, the operation of the x-axis reflecting mirror 30 and the y-axis reflecting mirror 40 causes a change in the incident angle of the laser beam incident on the fractional hose 60 and the y-axis reflecting mirror ( Telecentric scan lens 50 is installed between 40 and fountain hose 60. The telecentric scan lens 50 may change the incident angle of the laser beam, which varies according to the position of the hole 61 to be machined on the surface of the fountain hose 60, regardless of the position of the hole 61 to be machined. It is always to be irradiated perpendicularly to the surface to thereby obtain a constant focal size on the fountain hose 60 surface at all times. That is, regardless of the position of the hole 61 to be machined, it is possible to always process a hole 61 of a constant size.

Here, the control of the driving motor 31 and the step motor 41 for driving the laser pulse, the fractional hose 60, and the x and y axis reflection mirrors 40 should be integrated and controlled according to the shape of the pattern. It is possible to build a control and operation system so that the drilling operation can be easily performed by creating a control system and a user menu of the graphic to display the drilling pattern to be processed on the window screen.

Hereinafter, the operation of the present invention will be described.

The laser beam irradiated from the laser oscillator 10 is enlarged to the diameter of the beam that is optimal for the x-axis reflection mirror 30 while passing through the telescope 20. The beam passing through the telescope 20 is reflected by the scanner x-axis and the scanner y-axis and is focused on the surface of the fountain hose 60 while passing through the telecentric scan lens 50 that is the focusing lens 50.

The fountain hose 60 is wound around the unwinding roll 70 and is unwound from the unwinding roll 70 at a constant speed specified by the drive roll 72 operated by the main motor 73. It becomes.

At this time, the fountain hose 60 is supported by the left and right guide supporting members at the hole 61 forming position to maintain flatness, and is parallel to the telecentric scan lens 50 and maintains a constant distance while maintaining a uniform speed. The focal plane of the telecentric scan lens 50 is moved.

The x-axis reflection mirror 30 has a function of inducing a beam in the moving direction of the fountain hose 60 according to the operation of the drive motor 31, the rotational speed of the x-axis reflection mirror 30 is a fountain hose ( 60) The shape in which the laser beam is irradiated from the surface is adjusted to be completely synchronized with the moving speed of the fountain hose 60 so that the circular hole 61, not the elliptical shape, can be processed.

If the x-axis reflecting mirror 30 is fixed without this function, the fractional hose 60 moves during one laser beam irradiation time (laser beam pulse width), and the laser irradiation portion also appears elliptical in correspondence with the moving distance. . The y-axis reflection mirror 40 processes the hole 61 while moving the laser beam in the width direction of the fountain hose 60.

In addition, the y-axis reflection mirror 40 is moved by one step in accordance with the operation of the step motor 41 so that the laser beam is irradiated to the specified position by the number of holes 61 to be machined in the width direction during one period of the pattern. do.

If one pulse is irradiated from the laser beam oscillator 10 while the y-axis reflection mirror 40 is stopped as described above, the drive signal of the x-axis reflection mirror 30 is operated at the same time as the laser pulse ON signal, thereby driving the motor. (31) is operated so that the x-axis reflection mirror 30 is rotated and irradiated while moving the laser beam in the movement direction of the fountain hose 60 during the laser pulse time. Accordingly, one hole 61 is drilled on the surface of the fountain hose 60.

At the same time as the laser beam irradiation ends, the driving motor 31 is rotated in reverse to return the x-axis reflecting mirror 30 to its original position, and the y-axis reflecting mirror 40 is operated according to the operation of the step motor 41. The staff is rotated to move to the position of the hole 61 to be processed next.

When the hole 61 is prepared for the next step, as described above, one pulse is irradiated from the laser beam oscillator 10 and another hole 61 is injected according to the traced perforation of the x-axis reflector 30. It is drilled at another position of the hose 60.

And this process is repeated repeatedly for one period of the pattern to complete one pattern, after the completion of one pattern, the y-axis reflection mirror 40 is returned to its original position in accordance with the operation of the step motor 41 to the hole of the next period Ready for processing.

According to the fountain hose drilling apparatus according to the present invention as described above, by using a laser beam when drilling a fountain hose, it is possible to prevent the tearing of holes generated in conventional machining and to process finer holes.

In addition, two-axis reflective mirrors and telecentric scan lenses can be used to process a variety of perforation patterns, making them more useful in small batch production.

1 is a schematic configuration diagram showing a fountain hose cloth factory according to the present invention,

Figure 2 is a schematic diagram showing the pattern of the hole to be drilled in the fountain hose by the drilling device according to the invention,

3 is a view showing a fountain hose having a hole drilled according to the prior art.

Explanation of symbols on the main parts of the drawings

10: oscillator 20: telescope

30: x-axis reflection mirror 31: drive motor

40: y-axis reflection mirror 41: step motor

50: telecentric scan lens 60: fountain hose

61: hall

Claims (5)

In the fountain hose boring device, A fountain hose feeder for advancing the fountain hose at a constant speed, a laser beam oscillator for producing a laser beam, and installed at one side of the fountain hose feeder so as to be rotatable in the longitudinal direction of the fountain hose, An x-axis reflector for reflecting the laser beam, a drive motor for connecting to the pivot axis of the x-axis reflector to rotate the x-axis reflector at a speed synchronized with the movement speed of the fountain hose, located on one side of the fountain hose transfer unit Y-axis reflector for irradiating light reflected from the x-axis reflector to the surface of the fountain hose and connected to the pivot axis of the y-axis reflector Including a step motor for rotating the reflecting mirror by one step, the laser beam is directed in the longitudinal and width directions of the fountain hose. The fountain hose perforation device for machining hole by induction. delete The fountain hose drilling device of claim 1, wherein one cycle of the x-axis reflecting mirror is adapted to a pulse width of a laser beam. 4. The telescope according to claim 1 or 3, further comprising a telescope positioned between the oscillator and the x-axis reflection mirror to control the size of the hole to be drilled by adjusting the diameter of the laser beam produced from the oscillator. Fountain hose boring machine. The method of claim 4, further comprising a telecentric scan lens positioned between the y-axis reflection mirror and the fountain hose to adjust the incident angle of the laser beam to irradiate the laser beam perpendicularly to the fountain hose surface. Fountain hose boring machine.