JPWO2019172234A1 - Manufacturing method of metal thin tube - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a method for manufacturing a metal capillary having a surface layer portion roughened on the outer surface side, which can be used as an injection needle. A method for manufacturing a metal thin tube having an outer diameter of 0.2 mm to 3 mm and a thickness of 0.05 mm to 0.3 mm and having a surface layer portion roughened on the outer surface side, wherein the metal thin tube has a surface layer portion. While rotating the metal thin tube with the support rod inserted inside, the metal thin tube is continuously irradiated with continuous wave laser light along the length direction of the metal thin tube to coarsen the outer surface side of the metal thin tube. Manufacture of a metal thin tube having a step of forming a surfaced surface layer portion, the rotation speed of the metal thin tube is 50 to 1000 r / min, and the irradiation speed of the continuous wave laser is 2000 mm / sec or more. Method. [Selection diagram] Fig. 5

Description

The present invention relates to a method for producing a metal capillary having a roughened surface layer portion.

From the viewpoint of weight reduction of various parts, a resin molded body is used as a metal substitute, but it is often difficult to replace all metal parts with resin. In such a case, it is conceivable to manufacture a new composite part by joining and integrating the metal molded body and the resin molded body, and as the joining and integrating technology, the metal molded body and the metal molded body are used. A technique for joining resin molded bodies is known.

Japanese Unexamined Patent Publication No. 2016-78090 discloses an invention of a method for producing a metal molded product having a porous structure on a surface layer portion by using continuous wave laser light and cooling means, and a method for producing a composite molded product using the same. Have been described.

Metal moldings include flat plates, rectangular parallelepipeds, cubes, cones, pyramids, cylinders, rings, cylinders, tubes, boxes, hemispheres, spheres, solid lattices, tree branches and other complex shapes, needles and wires. Thin objects such as (paragraph number 0016) are also applicable.
Outline of the invention

An object of the present invention is to provide a method for producing a metal capillary having a roughened surface layer portion, which can be used as an injection needle of a syringe or the like.

The present invention is a method for manufacturing a metal capillary having an outer diameter of 0.2 mm to 3 mm and a thickness of 0.05 mm to 0.3 mm and having a surface layer portion roughened on the outer surface side.
While rotating the metal thin tube with the support rod inserted inside the metal thin tube, the metal thin tube is continuously irradiated with continuous wave laser light along the length direction of the metal thin tube to the outside of the metal thin tube. It has a step of forming a roughened surface layer portion on the surface side.
The rotation speed of the metal thin tube is 50 to 1000 r / min.
Provided is a method for manufacturing a metal capillary tube in which the irradiation speed of the continuous wave laser is 2000 mm / sec or more.

According to the manufacturing method of the present invention, a thin and thin metal thin tube having an outer diameter of 0.2 mm to 3 mm and a thickness of 0.05 mm to 0.3 mm is roughened to the outer surface side without changing the dimensions. A surface layer portion can be formed.

The perspective view of the metal thin tube used in the manufacturing method of this invention. The perspective view of the support rod used in the manufacturing method of this invention. The perspective view of the cooling tubular body used in the manufacturing method of this invention. An axial sectional view for explaining one embodiment of the manufacturing method of the present invention. A cross-sectional view in the axial direction for explaining another embodiment of the manufacturing method of the present invention. Explanatory drawing of irradiation form of continuous wave laser light. The perspective view of the metal thin tube which has the roughened surface layer part obtained by the manufacturing method of this invention. An SEM photograph of the roughened surface of the metal capillary tube obtained in Example 3. An SEM photograph of the roughened surface of the metal capillary tube obtained in Example 4.

Hereinafter, the production method of the present invention will be described with reference to the drawings.

FIG. 1 is a perspective view of a metal capillary tube 10 used in the manufacturing method of the present invention (for example, one embodiment shown in FIG. 4 and another embodiment shown in FIG. 5). The metal of the metal thin tube 10 is not particularly limited, and depends on the use of the metal thin tube (hereinafter referred to as "final metal thin tube") having a roughened surface layer portion on the outer surface side obtained by the production method of the present invention. Can be appropriately selected from known metals.

Examples of metals include those selected from iron, aluminum, zinc, titanium, copper, magnesium and alloys containing them; various stainless steels; cermets such as tungsten carbide and chromium carbide. The production method of the present invention can also be applied to those metals subjected to surface treatment such as alumite treatment and plating treatment. When the finally obtained metal capillary is for medical equipment, various stainless steel, iron, and titanium are preferable as the metal.

The metal thin tube 10 preferably has a uniform outer diameter and a uniform inner diameter, but may have a partial outer diameter, a partial inner diameter, or a partial outer diameter and an inner diameter different depending on the application. The outer diameter of the metal thin tube 10 is 0.2 mm to 3 mm. When some of the outer diameters are different, the maximum outer diameter is within the above range. The thickness of the metal capillary 10 is 0.05 mm to 0.3 mm. When the thickness of a part of the metal capillary is different, the maximum thickness can be within the above range.

FIG. 2 is a perspective view showing one example of the support rod 20 used in the manufacturing method of the present invention (one embodiment shown in FIG. 4 and another embodiment shown in FIG. 5). The support rod 20 can be made of metal, and is preferably made of a metal having a higher thermal conductivity than the metal of the metal thin tube 10, but it is also possible to use one made of the same metal as the metal thin tube 10. When the metal capillary is intended for medical devices, it is preferable to use stainless steel, iron, or titanium for the support rod 20.

The outer diameter of the support rod 20 is such that it can be inserted into the through hole 11 of the metal thin tube 10 and is lightly brought into contact with the inner peripheral surface of the metal thin tube 10 when the metal thin tube 10 is rotated. It is preferable to have. The inner diameter (D1) of the metal thin tube 10 and the outer diameter (D2) of the support rod 20 are preferably D2 / D1 ≧ 0.90, and more preferably in the range of D2 / D1 = 0.95 to 0.99.

FIG. 3 is a perspective view of a cooling tubular body 30 that can be used in the manufacturing method of the present invention (the embodiment shown in FIG. 5). The cooling tubular body 30 may be made of metal, and it is preferable to use one made of a metal having a higher thermal conductivity than the metal of the metal thin tube 10, but one made of the same metal as the metal thin tube 10 is used. It can also be used. When the metal capillary is intended for medical equipment, it is preferable to use stainless steel, iron, or titanium for the cooling tubular body 30.

The inner diameter of the cooling tubular body 30 and the outer diameter of the metal thin tube 10 are adjusted so that the inner surface of the through hole 31 of the cooling tubular body 30 can be fitted in close contact with the outer surface of the metal thin tube 10. Is preferable. For example, the inner diameter of the cooling tubular body 30 and the outer diameter of the metal thin tube 10 can be substantially the same.

The cooling tubular body 30 may be configured so that it can be divided into two along the length direction. In the case of such an embodiment, the mating surfaces of the two divided halves have corresponding irregularities, and the corresponding irregularities can be fitted together to form the embodiment shown in FIG. It can also be. Further, when a cooling tubular body 30 having a structure that can be divided into two is used, it can be used by fixing it with a band or the like from the outside.

An embodiment of the manufacturing method of the present invention will be described with reference to FIG. The support rod 20 has a state in which the first end portion 20a is located at the first end portion 10a of the metal thin tube 10 and the second end portion 20b is projected outward from the second end portion 10b of the metal thin tube 10. It is inserted into the through hole 11 (see FIG. 1) of the metal capillary 10.

In one example, the first end 10a side of the metal capillary 10 is connected to a rotating device (not shown), and the second end 20b of the support rod 20 is fixed by a jig (not shown). When fixing the support rod 20 in this way, it can be fixed by a jig such as a vise attached to a workbench, for example.

In this example, while rotating the metal thin tube 10 in the state shown in FIG. 4, the continuous wave laser light source 1 is operated to laser the outer surface of the metal thin tube 10 along the length direction of the metal thin tube 10. Light 2 is continuously irradiated. As a result, a roughened surface layer portion is formed on the outer surface side of the metal capillary tube 10.

The irradiation position and irradiation area of the laser beam on the metal thin tube 10 can be determined according to the application. The rotation direction of the metal thin tube 10 is preferably the same direction. By fixing the support rod 20 so as not to rotate when the metal thin tube 10 is rotated, it is possible to prevent the metal thin tube 10 from being deformed by both heat and rotation due to laser light irradiation, which is preferable.

Further, when the support rod 20 is made of a metal having a higher thermal conductivity than the metal of the metal thin tube 10 or the same metal as the metal thin tube 10, the metal thin tube 10 is compared with the case where it is not used (that is, in an air-cooled state). It is preferable because the heat dissipation effect from the inner surface side of the metal thin tube 10 can be obtained and the deformation prevention effect of the metal thin tube 10 can be enhanced.

Another embodiment of the manufacturing method of the present invention will be described with reference to FIG. The support rod 20 has a state in which the first end portion 20a is located at the first end portion 10a of the metal thin tube 10 and the second end portion 20b is projected outward from the second end portion 10b of the metal thin tube 10. It is inserted into the through hole 11 (see FIG. 1) of the metal capillary 10.

In one example, the second end 20b of the support rod 20 is fixed by a jig (not shown). When fixing the support rod 20 in this way, it can be fixed by a jig such as a vise attached to a workbench, for example.

A cooling tubular body 30 is fitted into the first end portion 10a side of the metal thin tube 10 from the first end surface 30a side. The second end surface 30b side of the cooling tubular body 30 is connected to a rotating device (not shown). The cooling tubular body 30 may be used in a pre-cooled state in order to enhance the cooling effect of the metal thin tube 10 and reduce the thermal effect at the time of laser light irradiation.

In this example, the continuous wave laser light source 1 is operated along the length direction of the metal thin tube 10 while rotating the metal thin tube 10 by rotating the cooling tubular body 30 in the state shown in FIG. , The outer surface of the metal capillary 10 is continuously irradiated with the laser beam 2. As a result, a roughened surface layer portion is formed on the outer surface side of the metal capillary tube 10. The rotation direction of the metal thin tube 10 is preferably the same direction.

When the cooling tubular body 30 is rotated to rotate the metal thin tube 10, the support rod 20 is fixed so as not to rotate, so that the metal thin tube 10 is deformed by both heat and rotation due to laser light irradiation. It is preferable because it can prevent.

When a metal having a higher thermal conductivity than the metal of the metal thin tube 10 or a metal made of the same metal as the metal thin tube 10 is used as the support rod 20 together with the cooling tubular body 30, when it is not used (that is, in an air-cooled state). As compared with the above, it is preferable because the heat dissipation effect from both the outer surface side and the inner surface side of the metal thin tube 10 can be obtained, and the deformation prevention effect of the metal thin tube 10 is further enhanced.

In any of the manufacturing methods of the embodiment shown in FIG. 4 and the embodiment shown in FIG. 5, the rotation speed of the metal capillary tube 10 is 50 r / min to 1000 r / min, preferably 50 r / min to 500 r / min. For example, when a metal thin tube 10 having an outer diameter of 2 mm (outer circumference 6.28 mm) rotates at 100 r / min, the rotational speed (peripheral speed) in the circumferential direction is 628 mm / min (= 10.47 mm / sec = 0.01047 mm / msec). ).

The continuous wave laser continuously irradiates at an irradiation speed of 2000 mm / sec or more. The irradiation speed of the continuous wave laser is preferably 2000 to 20,000 mm / sec, more preferably 2,000 to 18,000 mm / sec, and even more preferably 2,000 to 15,000 mm / sec. The irradiation speed of the continuous wave laser light is adjusted so as to be sufficiently higher than the rotation speed of the metal thin tube 10.

The continuous wave laser light can be irradiated linearly along the length direction of the metal thin tube 10. The distance between adjacent irradiation marks (grooves formed by adjacent linear irradiation) is preferably 0.01 to 0.2 mm, more preferably 0.03 to 0.15 mm.

The energy density at the time of irradiation with continuous wave laser light ^{is preferably 1 MW / cm 2} or more. The energy density at the time of irradiation with the laser beam is obtained from the output (W) of the laser beam and the spot area (cm ² ) (π · [spot diameter / 2] ² ) of the laser beam. The energy density at the time of irradiation with laser light ^{is preferably 2} to 1000 MW / cm ² , more preferably 10 to 800 MW / cm ² , and even more preferably 10 to 700 MW / cm 2.

The output of the laser light is preferably 4 to 4000 W, more preferably 50 to 2500 W, and even more preferably 150 to 2000 W. The wavelength is preferably 500 to 11,000 nm. The beam diameter (spot diameter) is preferably 5 to 80 μm.

The defocusing distance when irradiating the laser beam is preferably −5 to +5 mm, more preferably −1 to + 1 mm, and even more preferably −0.5 to +0.1 mm. The defocusing distance may be laser irradiation with a constant set value, or laser irradiation may be performed while changing the defocusing distance. For example, at the time of laser irradiation, the defocusing distance may be reduced, or may be periodically increased or decreased.

In the method for producing a metal thin tube of the present invention, when the surface of the metal thin tube to be roughened is irradiated with laser light, it can be irradiated so that the irradiated portion and the non-irradiated portion of the laser light are alternately generated. ..

Irradiating so that the irradiated portion of the laser light and the non-irradiated portion are alternately generated means that the non-irradiated portion of the laser light between the irradiated portion of the laser light and the irradiated portion of the adjacent laser light is alternately generated, and as a whole It shows the state of irradiation so as to be formed in a dotted line.

At this time, the same portion can be repeatedly irradiated to form a dotted line along a straight line in appearance. The number of repetitions can be, for example, 1 to 20 times. When irradiating multiple times, the laser beam irradiation portion may be the same, or the laser beam irradiation portion may be different (the laser light irradiation portion is shifted), so that the entire surface of the metal thin tube is roughened. You may do so.

When the irradiated part of the laser light is the same and irradiated multiple times, it is irradiated in a dotted line, but the irradiated part of the laser light is shifted, that is, the part that was initially the non-irradiated part of the laser light is irradiated with the laser light. It is preferable to repeat the irradiation by shifting the irradiation portions so as to overlap each other, because even if the irradiation is performed in a dotted line, the irradiation is finally performed in a solid line state.

When the metal thin tube is continuously irradiated with the laser beam, the temperature of the irradiated surface may rise, but when the laser irradiation is performed in a dotted line, the irradiated portion of the laser beam and the non-irradiated portion of the laser beam are alternately generated. Since the non-irradiated portion of the laser beam is cooled, it is preferable that the metal thin tube is less likely to be deformed such as warp when the laser beam irradiation is continued. At this time, the same effect can be obtained even when the laser beam irradiation portion is different (the laser light irradiation portion is shifted) as described above.

The length of the irradiated portion of the laser light (L1) and the length of the non-irradiated portion of the laser light (L2) can be adjusted so as to be in the range of L1 / L2 = 1/9 to 9/1. The length (L1) of the irradiated portion of the laser beam is preferably 0.05 mm or more, more preferably 0.1 to 10 mm in order to roughen the surface layer portion of the metal capillary into a complicated porous structure. 0.3 to 7 mm is more preferable.

In the method for manufacturing a thin metal tube of the present invention, the laser light irradiation step described above uses a fiber laser device in which a direct modulation type modulator that directly converts a laser drive current is connected to a laser power supply, and a duty ratio (duty). This can be done by adjusting the duty cycle) and irradiating with a laser.

There are two types of laser excitation, pulse excitation and continuous excitation, and a pulse wave laser by pulse excitation is generally called a normal pulse. It is possible to create a pulse wave laser even with continuous excitation. For example, a Q switch pulse oscillation method in which the pulse width (pulse ON time) is shorter than that of a normal pulse and a laser with a higher peak power is oscillated accordingly. A pulse wave laser is created by an external modulation method that generates a pulse wave laser by cutting out light in time with an AOM or LN light intensity modulator, and a direct modulation method that directly modulates the drive current of the laser to generate a pulse wave laser. be able to.

In a preferred embodiment of the present invention, a pulse wave laser can be produced by continuously exciting the laser by using a fiber laser device in which a direct modulation type modulation device that directly converts the driving current of the laser is connected to a laser power supply. it can.

The duty ratio is a ratio obtained by the following equation from the ON time and OFF time of the laser light output.
Duty ratio (%) = ON time / (ON time + OFF time) x 100

Since the duty ratio corresponds to the above L1 / (L1 + L2), it can be selected from the range of 10 to 90%. By adjusting the duty ratio and irradiating the laser beam, it is possible to irradiate in a dotted line. When the duty ratio is large, the efficiency of the roughening process is improved, but the cooling effect is low, and when the duty ratio is small, the cooling effect is good, but the roughening efficiency is poor. Adjust the duty ratio according to the purpose.

Known continuous wave lasers can be used, for example, YVO4 laser, fiber laser (preferably single mode fiber laser), excima laser, carbon dioxide gas laser, ultraviolet laser, YAG laser, semiconductor laser, glass laser, ruby. Lasers, He-Ne lasers, nitrogen lasers, chelate lasers, dye lasers can be used. Among these, a fiber laser is preferable, and a single mode fiber laser is particularly preferable because the energy density is increased.

The irradiation form of the continuous wave laser beam is not particularly limited, and the outer surface of the metal thin tube 10 is irradiated in only one direction (one direction) along the length direction of the metal thin tube 10. It is possible to carry out a form of irradiating a metal, a form of irradiating a combination of one direction and both directions.

FIG. 6 shows an example of a preferable irradiation form of continuous wave laser light. The laser light is such that the laser light oscillated from the laser oscillator irradiates the object to be irradiated (metal thin tube 10) through the mirror. At this time, the irradiation position and irradiation length of the laser beam are adjusted by changing the angle of the mirror.

In the first step, when irradiating the laser beam from the start point S1 to the end point F1 (L1 in FIG. 6), the head that does not irradiate the laser light before reaching the start point S1 before starting the irradiation of the laser light from the start point S1. There is a time (head time [head time]; time until the angle of the mirror is adjusted to the start point S1) (the position at the start of the head time is H1).

Further, in the first step, after irradiating the laser beam to the end point F1, the tail time (tail time [tail time]; the time until the mirror stops after the end point F1) (the tail time) (the time until the mirror stops after the end point F1). The position at the end of the tail time is T1) exists.

Therefore, for example, when the laser beam is irradiated from the start point S1 to the end point F1 by a length of 10 mm, the laser beam is irradiated for a length of, for example, about 5 mm until the start point S1 (0 mm) where the laser light irradiation is started. It is a time during which the laser beam is not irradiated (head time), and a length of about 4 mm from the end point F1 (10 mm) at which the laser beam irradiation is stopped requires a time during which the laser beam is not irradiated (tail time). The total time (msec) of the head time, the irradiation time of the laser beam from the start point S1 to the end point F1, and the tail time is the processing time of the first step.

The second step is a step of returning from the tail time end position T1 of the first step to H2 moved in the circumferential direction of the metal thin tube 10 from the head time start position H1 of the first step without irradiating the laser beam (FIG. It is L2) in 6. The change in position from H1 to H2 in the circumferential direction is due to the rotation of the metal capillary. The time (msec) for returning from T1 to H2 is the processing time of the second step.

With the first step and the second step as one cycle, the first cycle to the nth cycle (n is a positive integer of 2 or more) can be repeatedly carried out. At this time, the processing time of one cycle is the total processing time (msec) of the processing time (msec) of the first step and the processing time (msec) of the second step.

In FIG. 6, the second cycle is shown as H2 corresponding to H1, S2 corresponding to S1, L3 corresponding to L1, F2 corresponding to F1, and T2 corresponding to T1. The circumferential distance of the metal thin tube 10 from T1 to T2 and the circumferential distance of the metal thin tube 10 from H1 to H2 are the adjacent irradiation marks of the continuous wave laser beam (adjacent along the length direction of the metal thin tube 10). It corresponds to the distance between the grooves formed by the irradiation.

Although the metal thin tube 10 is rotating when irradiating the laser light, the irradiation speed of the laser light is significantly faster than the rotation speed of the metal thin tube 10. Therefore, in the first step L1, the laser light is the length of the metal thin tube 10. It will be irradiated almost linearly along the direction.

In the second step L2, the irradiation start position is slightly moved from S1 to S2 in the circumferential direction due to the rotation of the metal capillary tube 10 during the total time of the first step and the second step (easily understood in FIG. 6). (Indicated by diagonal lines). It should be noted that a positive stop time (delay time) (DT) for correcting the irradiation position of the laser beam (shifting the irradiation position) can be provided as needed.

The processing time of one cycle can be adjusted by satisfying all one, two, or three of the following requirements (a) to (c), and the requirements (a) and (b) can be adjusted. It is preferable to adjust by either or both.

(A) The processing time of one cycle is adjusted by adjusting the irradiation speed of the laser beam in the first step.
(B) The processing time of one cycle is adjusted by adjusting the return speed of the second step.
(C) The processing time of one cycle is adjusted by adjusting one or both of the head time and the tail time.

That is, in the exemplary continuous wave laser beam continuous irradiation step of the present invention, the laser beam is irradiated from the start point S1 to the end point F1 in one direction in the length direction of the metal capillary tube using a laser oscillator and a mirror. When
It has a first step of irradiating the laser beam from the start point S1 to the end point F1 and a second step of returning the laser beam irradiation position to the start point S1 direction without irradiating the laser beam by adjusting the mirror. And
The first step is
When irradiating the laser beam from the start point S1 to the end point F1 in the first step, the head time before starting the irradiation of the laser beam from the start point S1 and not irradiating the laser beam before reaching the start point S1 (the head time). The start position is H1), and after the laser beam is irradiated to the end point F, the tail time (the position at the end of the tail time is T1) in which the laser light is not irradiated from the end point F1 is set. Exists and
The total time (msec) of the head time, the irradiation time of the laser beam from the start point S1 to the end point F1, and the tail time is the processing time of the first step.
The second step is
This is a step of returning from the head time start position H1 of the first step to H2 moved in the circumferential direction without irradiating the laser beam from the tail time end position T1 of the first step.
The time (msec) for returning from T1 to H2 is the processing time of the second step.
When the first step and the second step are regarded as one cycle and the first cycle to the nth cycle (n is a positive integer of 2 or more) are repeatedly carried out.
The processing time of one cycle is the total time (msec) of the processing time of the first step and the processing time of the second step.
The processing time of the one cycle is adjusted to the range of 1 to 200 msec by satisfying all the requirements of any one, two, or three of the following (a) to (c).
(A) The processing time of one cycle is adjusted by adjusting the irradiation speed of the laser beam in the first step.
(B) The processing time of one cycle is adjusted by adjusting the return speed of the second step.
(C) The processing time of one cycle is adjusted by adjusting one or both of the head time and the tail time.

Further, when the DT is provided, as the requirement (d), the processing time of one cycle can be adjusted by adjusting the DT.

In the present invention, the laser beam can be irradiated even in the second step. When irradiating the laser beam in the second step as well, the processing time of one cycle can be adjusted by adjusting the irradiation speed of the laser beam in the second step.

By associating the total processing time of one cycle with the peripheral speed (mm / msec) when rotating the metal thin tube, which is obtained from the outer diameter of the metal thin tube and the rotation speed (rotation speed), the laser light irradiation process for the metal thin tube can be performed. It is preferable to control.

The processing time for one cycle is preferably 1 to 200 msec, more preferably 1 to 100 msec, and even more preferably 1 to 50 msec. The peripheral speed when rotating the metal capillary is preferably 0.001 to 0.3 mm / msec, more preferably 0.002 to 0.2 mm / msec, and even more preferably 0.01 to 0.018 mm / msec.

The distance (pitch) between the irradiation marks of the laser beam (grooves formed by the laser beam) can be obtained from one cycle time × peripheral speed. The total number of rotations (number of rotations) of the metal thin tube can be obtained from the processing time of one cycle × the number of irradiations × the peripheral speed.

After the embodiment shown in FIG. 4, the metal thin tube 10 and the support rod 20 are separated, or after the embodiment shown in FIG. 5, the metal thin tube 10 and the support rod 20, the metal thin tube 10 and the cooling tubular body 30 are separated. By separating, as shown in FIG. 7, a final metal capillary tube 10A having a roughened surface layer portion 12 on the outer surface side can be obtained. In one example, the surface layer portion 12 ranges from a roughened surface irradiated with continuous wave laser light to a depth of 30 μm to 300 μm.

The final metal capillary tube 10A manufactured by the manufacturing method of the present invention can be used for medical devices such as injection needles. When a syringe or the like is manufactured using the final metal capillary tube 10A manufactured by the manufacturing method of the present invention, the metal molded product (for example, the final metal) described in the invention described in Japanese Patent No. 5701414 It can be manufactured by applying a method (injection molding method) of joining and integrating a resin molded body (for example, a syringe body for inserting an injection solution) with an injection needle using a thin tube 10A.

Example and Comparative Example The metal capillary tube 10A as shown in FIG. 7 was obtained by carrying out by the example of the manufacturing method shown in FIG. The dimensions of the metal thin tube 10, the support rod 20, and the cooling tubular body 30 were as follows.
Metal thin tube 10: outer diameter 2.11 mm, inner diameter 1.69 mm, length 100 mm
Support rod: outer diameter 1.69 mm, length 120 mm
Cylindrical body for cooling: inner diameter 2.11 mm, length 30 mm
In Examples and Comparative Examples, the time required per cycle was about 4 msec.

The first end portion 20b of the support rod 20 was fixed with a vise, and the second end portion 30b side of the cooling tubular body 30 was connected to the rotating portion of the rotating device. SUS304 was used as the material for the metal thin tube 10, the support rod 20, and the cooling tubular body 30. The SEM photographs of the roughened surfaces of the metal thin tubes of Examples 3 and 4 are shown in FIGS. 8 and 9.

(Easy to pull out the support rod)
After irradiating the laser beam under the conditions shown in Table 1, the mixture was left in the state shown in FIG. 5 for 30 seconds. After releasing the fixing of the support rod 20, the deformation was evaluated by the resistance force when the support rod 20 was pulled out by hand.
○ I was able to pull out the support rod without any resistance.
△ The resistance was high, but I was able to pull it out.
× Could not be pulled out.
XX A through hole was formed in the metal capillary, or the metal capillary was cut.

(Easy to insert support rod)
After evaluating the ease of pulling out the support rod 20, the deformation was evaluated by the resistance force when the new support rod 20 was manually inserted into the thin metal tube 10.
○ The support rod could be inserted without resistance.
△ The resistance was high, but it could be inserted.
× Could not insert.

Comparative Example 2 in which the support rod was not used was evaluated by irradiating the laser beam under the conditions shown in Table 1 and then inserting the support rod after cooling for 30 seconds.

(Maximum groove depth)
The groove depth was measured by measuring the surface after laser irradiation with a digital microscope VHX-900 (manufactured by KEYENCE CORPORATION). For the maximum groove depth, a total of 10 groove depths were measured at equal intervals in the circumferential direction and the length direction, and the value of the deepest portion among them was used.

From the comparison between the examples and the comparative examples, it was not possible to obtain the desired metal thin tube having a roughened surface layer portion when there was no support rod and the rotation speed of the metal thin tube was slow.
Industrial applicability

The metal capillary tube having a surface layer portion roughened on the outer surface side produced by the production method of the present invention can be used for medical devices such as injection needles.
Code description

10 Metal thin tube 10A Metal thin tube with a roughened surface layer on the outer surface side 11 Through hole 12 Surface layer 20 Support rod 30 Cooling tubular body

Claims (6)

A method for manufacturing a metal capillary having an outer diameter of 0.2 mm to 3 mm and a thickness of 0.05 mm to 0.3 mm and having a surface layer portion roughened on the outer surface side.
While rotating the metal thin tube with the support rod inserted inside the metal thin tube, the metal thin tube is continuously irradiated with continuous wave laser light along the length direction of the metal thin tube to the outside of the metal thin tube. It has a step of forming a roughened surface layer portion on the surface side.
The rotation speed of the metal thin tube is 50 to 1000 r / min.
A method for manufacturing a metal thin tube in which the irradiation speed of the continuous wave laser is 2000 mm / sec or more. The method for manufacturing a metal thin tube according to claim 1, wherein when continuous wave laser light is continuously irradiated in the length direction of the metal thin tube, irradiation is performed so that an irradiated portion and a non-irradiated portion of the laser light are alternately generated. When the continuous wave laser beam continuous irradiation step irradiates the laser beam from the start point S1 to the end point F1 in one direction in the length direction of the metal capillary tube using a laser oscillator and a mirror.
It has a first step of irradiating the laser beam from the start point S1 to the end point F1 and a second step of returning the laser beam irradiation position to the start point S1 direction without irradiating the laser beam by adjusting the mirror. And
The first step is
When irradiating the laser beam from the start point S1 to the end point F1 in the first step, the head time before starting the irradiation of the laser beam from the start point S1 and not irradiating the laser beam before reaching the start point S1 (the head time). The start position is H1), and after the laser beam is irradiated to the end point F, the tail time (the position at the end of the tail time is T1) in which the laser light is not irradiated from the end point F1 is set. Exists and
The total time (msec) of the head time, the irradiation time of the laser beam from the start point S1 to the end point F1, and the tail time is the processing time of the first step.
The second step is
This is a step of returning from the head time start position H1 of the first step to H2 moved in the circumferential direction without irradiating the laser beam from the tail time end position T1 of the first step.
The time (msec) for returning from T1 to H2 is the processing time of the second step.
When the first step and the second step are regarded as one cycle and the first cycle to the nth cycle (n is a positive integer of 2 or more) are repeatedly carried out.
The processing time of one cycle is the total time (msec) of the processing time of the first step and the processing time of the second step.
The metal capillary according to claim 1 or 2, wherein the processing time of the one cycle is adjusted to the range of 1 to 200 msec by satisfying the requirements 1, 2 or 3 of (a) to (c) below. Production method.
(A) The processing time of one cycle is adjusted by adjusting the irradiation speed of the laser beam in the first step.
(B) The processing time of one cycle is adjusted by adjusting the return speed of the second step.
(C) The processing time of one cycle is adjusted by adjusting one or both of the head time and the tail time. A support rod is inserted inside the metal thin tube, and the metal thin tube is rotated by rotating the tubular cooling tubular body in a state where the cooling tubular body is fitted outside the metal thin tube. The method for producing a thin metal tube according to any one of claims 1 to 3. The method for manufacturing a metal thin tube according to any one of claims 1 to 4, wherein the support rod inserted inside the metal thin tube is fixed, and the support rod does not rotate when the metal thin tube is rotated. .. The method for producing a metal thin tube according to any one of claims 1 to 5, wherein the metal thin tube is used as a medical device.