1. Field of the Invention
This invention relates to a metal tube of irregular shape which has at least two inner diameters, and its production method. To be more specific, this invention relates to a small diameter, irregular shaped metal tube which can be used for a pin, injection needle, connector, electron gun for TV liquid crystal, and the like, and its production method.
2. Prior Art
Metal tubes of small diameter such as those having, for example, an outer diameter of up to 2 mm and used for a medical pin, injection needle, connector, electron gun for TV, or the like are typically produced by curling a metal thin plate having a thickness of up to 0.2 mm simultaneously with the drawing, welding the abutting edges of the thin plate just before its entrance into a drawing die, drawing the welded member through the drawing die to form a tube having an outer diameter of about 4 to 6 mm, and repeating the drawing process to thereby produce a final tube product having a tapered or stepped side profile with at least two inner diameters.
However, when the diameter of the tube 1 becomes reduced after repeated drawings, insertion of the plug 3 in the tube 1 becomes impossible, and such drawing with no plug 3 is inevitable. When the tube 1 is drawn with no plug 3 inserted in the tube 1, the inner surface of the tube 1 becomes creased and the inner surface will suffer from an increased surface roughness which results in the increase in the resistance of a fluid passing through the tube 1. Increase in the surface roughness also results in the increase in the surface area which invites adhesion of dirt and foreign matters. This is a serious problem when the tube is used for a medical application where hygiene is of serious interest. In spite of such situation, there has so far been no small diameter tube which is free from the problem of the rough inner surface.
As described above, there is a strong demand for a small diameter metal tube with a smooth inner surface having at least two inner diameters and which can be used for an injection needle, as well as its production method.
An object of the present invention is to obviate the problems of the prior art technology as described above by providing a small diameter metal tube which has at least two inner diameters.
Another object of the invention is to provide its production method.
In order to attain the object as described above, the present invention provides a metal tube which has at least two inner diameters, wherein the inner surface of the tube has a maximum height difference (Rf) in the surface roughness of up to 3 μm, and the tube has a minimum inner diameter of up to 2 mm and a maximum inner diameter of up to 5 mm.
Also provided by the present invention is a method for producing a metal tube having at least two inner diameters, comprising the steps of:
blanking a plate member having a development shape of the metal tube from a metal thin plate such that the plate member is left partly tied to the metal thin plate;
press forming the plate member into a tubular body having the at least two inner diameters; and
cutting apart the plate member partly tied to the metal thin plate to produce the metal tube having the at least two inner diameters.
In the metal tube producing method of the present invention, the plate member, after having been press formed into a tubular body having the at least two inner diameters, is preferably welded at a seam thereon to produce the metal tube having the at least two inner diameters.
In the metal tube producing method of the present invention, in the step of press forming, a part in the plate member corresponding to the distal or proximal end of the tube obtained by the press forming is preferably moved either upward or downward from the plane of the metal thin plate so that the central axis of the tube during the press forming will be parallel to the plane of the metal thin plate.
This invention also provides a metal tube produced by the method of the present invention.
Next, the method for producing the metal tube of the present invention as well as the metal tube produced by such method are described with reference to the preferred embodiments shown in the accompanying drawings.
The metal tube of the present invention is characterized by its irregular shape having at least two inner diameters. Typical such tubes include a hollow tube 8 having a circular cross section as shown in
Typical application of such metal tube having at least two inner diameters is an injection needle used in epidural injection. In the case of inserting the injection needle for use in epidural injection, the tapered or stepped profile of the needle functions as a sensor or indicator for the location of the needle tip, thereby preventing nerve and other fine tissues from being damaged by the needle which had gone too far.
In the present invention, the tube may also have a cross section other than circle, as exemplified by polygonal such as quadrilateral or hexagon, or ellipsoid as shown in
In the present invention, the tube typically has an outer diameter of up to 8 mm, and preferably up to 5 mm. When the tube is used for an injection needle, the tube may have an outer diameter of up to 2 mm, preferably up to 1 mm, and more preferably up to 0.4 mm. When the outer diameter is within such range, the tube used as an injection needle will experience reduced resistance in its insertion into the skin, and pain associated with the injection will be reduced.
In the present invention, the tube has at least two inner diameters, and of the at least two inner diameters, the maximum inner diameter is up to 5 mm, preferably up to 1.5 mm, and more preferably up to 0.8 mm.
Of the at least two inner diameters of the tube, the minimum inner diameter is up to 2 mm, preferably up to 1 mm, and more preferably up to 0.5 mm.
When the tube has an inner diameter within such range, the tube will enjoy sufficient strength required for the tube when the tube has an outer diameter within the above-specified range.
In the present invention, the tube inner surface has a maximum height difference (Rf) in the surface roughness as defined by JIS-B-0601-1994 of up to 3 μm, preferably up to 2 μm, and more preferably up to 1 μm. When the tube inner surface has an Rf within the above-specified range, the entire inner surface of the tube will be smooth with no major scratch, and the tube will be quite suitable for use as a medical device.
The metal constituting the tube is not limited to any particular metal, and the metals which may be used include a steel material such as stainless steel, a nonferrous structural material such as aluminum, copper, or titanium, a heat-resistant material such as nickel, cobalt, or molybdenum, a low melting point metal material such as lead or tin, a noble metal material such as gold, silver or platinum, and an alloy thereof.
The tube is not limited for its length. When the tube is used for an injection needle, however, the length of the tube which inevitably has a thin wall thickness must be appropriately selected in accordance with the strength required for the tube. For example, when the tube is used for an injection needle, the tube having a diameter corresponding to the injection needle of gage 25 to 33 should have a Vickers hardness of at least 200.
Next, the method for producing a metal tube according to the present invention is described.
In the method of the present invention, a plate member 5 having a development shape of a tube is blanked from a metal thin plate 4 having a thickness of up to 0.25 mm as shown in
It is to be noted that the method used in the blanking of the plate member 5 from the metal thin plate 4 is not limited to mechanical blanking, and the plate member 5 may be thermally blanked from the metal thin plate 4 by using laser or the like.
Next, the plate member 5 is press formed as shown in
In the press forming, the part of the plate member 5 corresponding to the distal or proximal end of the resulting tube 8 is preferably moved upward or downward in relation to the plane of the metal thin plate 4 so that the central axis of the tube 8 will extend parallel to the plane of the metal thin plate 4 in the course of the press forming.
Although the tube 8 obtained by the press forming has at least two inner diameters, the central axis of the tube 8 is maintained parallel to the plane of the metal thin plate 4 by the upward or downward movement of the part of the plate member 5 corresponding to the distal or proximal end of the resulting tube 8 in relation to the metal thin plate 4 since the parts in the plate member 5 corresponding to the distal and proximal ends of the tube 8 are tied to the metal thin plate 4.
More preferably, the central axis of the tube 8 in the course of the press forming after the upward or downward movement of the part of the plate member 5 corresponding to the distal or proximal end of the resulting tube 8 in relation to the metal thin plate 4 is located at a position remote from the plane of the metal thin plate 4.
In
In order to uplift from the plane of the metal thin plate 4 the distal end of the tube 8 into which the plate member 5 is being press formed, the plate member 5 which is tied to the metal thin plate 4 through the tie strips 6 may be press formed by using a mold of adequate configuration. For example, when the tube 8 formed is a tapered hollow tube with a circular cross section having the distal end of a smaller diameter and the proximal end of a larger diameter as shown in
The method for placing the central axis 9 of the tube 8 in the course of the press forming at a position parallel to the plane of the metal thin plate 4 and also, at a position remote from the metal thin plate 4 has been described in the case in which the part of the plate member 5 corresponding to the distal end (the end with the smaller inner diameter) of the tube 8 is uplifted from the metal thin plate 4 to thereby place the central axis 9 of the resulting tube 8 parallel to and above the plane of the metal thin plate 4 by referring to
It is to be noted that, while the central axis 9 of the tube 8 in the course of press forming is preferably kept at a position remote from the metal thin plate 4, also included within the scope of the invention is the method wherein the tube formation by the press forming is accomplished with the central axis 9 of the tube 8 maintained in the same plane as the plane of the metal thin plate 4. In such a case, a mold of an adequate configuration may be used so that the distal end (the end with the smaller inner diameter) and the proximal end (the end with the larger inner diameter) of the tube 8 have different amounts of displacement. For example, the plate member 5 may be press formed into the tube 8 having at least two inner diameters by adequately regulating the amount of displacement of the lower mold under the plate member so that the central axis 9 of the tube 8 will be in the same plane as the plane of the metal thin plate 4, and at the same time, parallel to the plane of the metal thin plate 4.
In the preferred embodiment of the method of the present invention, the central axis 9 of the tube 8 extends at a position remote from the plane of the metal thin plate 4, and therefore, the tie strips 6 tying the plate member 5 to the metal thin plate 4 should be longer than the length corresponding to the distance between the central axis 9 of the tube 8 and the plane of the metal thin plate 4. While the length of the tie strips 6 may be appropriately selected according to the tube size (outer diameter and length), it is preferable that the length X (mm) of the tie strips and the outer diameter R (mm) of the tube 8 meet the following relation:
X≧R/2
wherein R is the outer diameter of the tube 8 at the distal or proximal end whose displacement from the plane of the metal thin plate 4 is larger than the other.
The above defined relation is preferable since the tube production is facilitated when the length of the tie strips 6 and the outer diameter of the tube 8 fulfill the relation as defined above.
The method of the present invention is capable of producing not only the tapered tube as described above but also a hollow tube of circular cross section as shown in
The seam of the tube formed by the press forming should be fluid tightly joined in some applications, for example, when the tube is used by passing a fluid therethrough as in the case of injection needle. The seam may be joined by using an adhesive. It is, however, preferable to weld the tube along its seam since the tube is made of a metal and is as thin as 1 mm or less in its outer diameter. The welding of the seam is preferably accomplished by melting the matrix of the tube, for example, by laser welding such as carbon dioxide laser welding, YAG laser welding, eximer laser welding, or the like among which the carbon dioxide laser welding and the YAG laser welding being preferred in view of their wide availability, low cost, and adaptability to micromachining.
The tube of the present invention can be obtained by cutting the tie strips 6 between the thin plate 4 and the plate member 5 after the welding of the seam. When used in an application which does not particularly require fluid-tight joining, the tube is not welded. In this case, the tube can be obtained by cutting the tie strips 6 between the thin plate 4 and the plate member 5 after formation of the tube 8 by the press forming of the plate member 5.
The thus produced tube 8 may be further processed depending on the intended use of the tube 8. For example, when the tube 8 is to be used as an injection needle, the tube 8 should be further processed, for example, to thereby provide the tube with an edge by a suitable conventional method.
Next, the present invention is described in further detail by referring to the following Examples.
A hollow tube as shown in
Maximum diameter section
Minimum diameter section
Length: 20 mm
Rmax: 0.8 μm
A hollow tube as shown in
Maximum diameter section
Intermediate diameter section
Minimum diameter section
Length: 20 mm
Rmax: 1.1 μm
A hollow tube as shown in
Maximum diameter section
Minimum diameter section
Length: 20 mm
Rmax: 1.7 μm
The tube of the present invention has a smooth inner surface despite the presence of at least two inner diameters, and this tube is well adapted for use in such application as injection needle used for epidural injection.
The method of the present invention is capable of producing a small diameter metal tube which has at least two inner diameters and which has a tapered, stepped, or other side profile.
Number | Date | Country | Kind |
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2001-396766 | Dec 2001 | JP | national |
This application is a division of application Ser. No. 10/329,478, filed Dec. 27, 2002 now U.S. Pat. No. 6,883,552.
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Number | Date | Country | |
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20050126241 A1 | Jun 2005 | US |
Number | Date | Country | |
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Parent | 10329478 | Dec 2002 | US |
Child | 11036156 | US |