KR920001630B1 - Work material for a watch band - Google Patents

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Description

Processing material for watch band

1 is a front view showing a workpiece material for a watch band of an embodiment of the present invention.

Figure 2 is a side view showing a workpiece material for a watch band of an embodiment of the present invention.

3 is a front view showing a state in which holes are formed by processing the embodiments shown in FIGS. 1 and 2.

4 is a side view showing a state in which holes are formed by processing the embodiments shown in FIGS. 1 and 2.

* Explanation of symbols for main parts of the drawings

1: Workpiece for watch band 2: Base member

3: material to be processed 5: hole

The present invention relates to a processed material used to form a band of the wrist watch.

Since the band of the wrist watch is a part which is easy to be scratched, it is preferable that it consists of a hard alloy. In particular, high-end wrist watches use cemented carbide as a material for watch bands.

However, when a very hard material such as cemented carbide is used as the material for the watch band, it is difficult to process into a desired shape. Such watch bands are connected to each other by pins or screws, so that they must form a hole for inserting or inserting the pins or screws. In the case of workpieces for watch bands made of cemented carbide, this punching process is performed by electric discharge machining, and therefore requires a long processing time.

On the other hand, in forming the wrist watch band part made of cemented carbide, the part may be molded so as to provide such a hole in advance. However, when molding into a shape having a hole having a desired diameter in advance, sufficient dimensional accuracy can be obtained.

Accordingly, it is an object of the present invention to provide a workpiece material for a watch band that can be manufactured inexpensively and inexpensively while using a cemented carbide that is not damaged.

The present invention is a processing material for the watch band to be finished by the watch band parts by processing the perforations, characterized in that the following. In other words, the processing portion is made of a workpiece having better workability with respect to perforation processing than the remaining base member, and the workpiece is joined to the base member by diffusion bonding. The material combination of the base member and the workpiece to be bonded to the base member is a combination of Wc-Co cemented carbide and Mo, a combination of Wc-Co cemented carbide and W, a combination of Wc-Co cemented carbide and Ta, and a TaC-Ni cemented carbide. And a combination of Mo and a combination of a TaC-Ni-based cemented carbide and a W-Ni-based alloy.

The base member of the workpiece material for a watch band of the present invention is made of a cemented carbide alloy. Since the processing part of the workpiece | work material for a watch band is made from the material which shows the favorable workability with respect to the punching | drilling process rather than a base member, the punching process is easy and can be processed with high precision. Therefore, it does not require long discharge processing work as in the prior art. In particular, the combination of materials of the base member and the workpiece to be bonded to the base member is limited to a specific one in consideration of workability such as bonding strength and perforation due to diffusion bonding.

The material showing good workability with respect to the drilling process does not mean that it is a soft metal. For example, when a soft material such as pure aluminum or pure iron is used as a workpiece of a work band for a watch band, it is difficult to perform screw hole processing and pin hole processing to a good degree. In other words, in the processing material for mechanical bands, it can be said that it is difficult to process soft materials such as pure aluminum and pure iron. In this way, the hardness and softness of the material and the workability for punching are not correlated.

The workpiece is joined to the base member by diffusion bonding. Therefore, when sintering the base member, joining of the workpiece to the base member can also be performed at the same time. Therefore, it does not complicate the manufacturing process of a raw material.

In the present invention, a material exhibiting better workability with respect to perforation processing than the base member of the workpiece is used. In the case where the base member is made of cemented carbide, a workpiece made of a metal of the periodic table IV, V or VI or an alloy of two or more metals thereof is preferable. Particularly, when the cemented carbide is a Wc-Co cemented carbide, Mo, W or Ta is preferred as the material of the workpiece, and Mo is most preferred in terms of bonding strength. In the case where the cemented carbide is a TaC-Ni-based cemented carbide, Mo or W-Ni-based alloys are preferable, and among them, W-Ni-based alloys are most preferable in terms of bonding strength.

In the diffusion bonding of the present invention, sinter diffusion bonding or hot hydrostatic press (HIP) diffusion bonding is preferable in terms of manufacturing process. Sintered diffusion bonding and HIP diffusion bonding may be used in combination. In the case of using together, after performing sinter diffusion bonding, HIP diffusion bonding may be performed or sinter diffusion bonding and HIP diffusion bonding may be performed simultaneously.

For example, the work material which has already been sintered is brought into close contact with the base member before sintering, and the base member can be sintered in this state, followed by HIP molding. Further, the base member and the workpiece can be sintered at the same time in a state in which the workpiece before sintering is brought into close contact with the base member before sintering, and then HIP molding can be performed. As another method, the already sintered workpiece can be brought into close contact with the already sintered base member, and then re-sintered, followed by HIP molding.

It is also conceivable that if carbides of the material of the workpiece are produced at the joining interface during diffusion bonding, the bond strength is increased by the formation of this carbide.

In the workpiece material of the watch band working material of the present invention, since the material having excellent punching workability is joined by diffusion bonding, the punching band is easy and therefore, the watch band part having excellent dimensional accuracy can be obtained. In addition, since it is not necessary to perform the electric discharge machining as in the prior art, the workpiece can be processed by the normal punching, so that the processing time can be significantly shortened.

In addition, since the workpiece is joined by diffusion bonding, the workpiece can be bonded to the base member when the base member is sintered or HIP molded. Therefore, the manufacturing process is not complicated.

1 and 2 are front and side views of a workpiece for a watch band according to an embodiment of the present invention. In the work band 1 for a watch band shown in the drawing, the workpiece 3 is embedded in a hole formed in the base member 2 made of cemented carbide. The work piece 1 for the watch band is obtained by embedding a workpiece 3 that has already been sintered into a hole in the base member 2 before sintering, sintering the base member 2 and then HIP molding.

The base member 2 and the to-be-processed material 3 produced the various combination of the material of Table 1. As shown in Figs. 3 and 4, the hole 5 was formed in the workpiece of the workpiece material 1 for the watch band, and the workability at that time was evaluated as an index. Evaluation was computed by the processing process and its processing capability. The machining process represented the average value of the machining capability of the punching | drilling process by drill cutting as an index.

In addition, in Table 1, as a comparative example, the workability dimension when the base member 2 itself, which is not bonded to the workpiece 3, that is not formed in the hole, was punched was evaluated. .

Evaluation was computed by the processing process and its processing capability similarly to the above. In the machining step, the average value of the hole formation by the electric discharge machining and the machining capability of the step was expressed as an index.

TABLE 1

Further, in the above-described embodiment, a hole is formed in the workpiece material 1 for the watch band, and the member 3 to be processed is filled in the hole, and the through hole is directed from the longitudinal ends of the workpiece 1 toward the center. The holes may be formed, the workpieces may be filled in the holes, the holes may be formed in the workpieces, and the pins may be inserted at both ends in the longitudinal direction. Similarly, the cross-sectional shape of the hole filled in the workpiece is not limited to a circle as shown in the figure, but may be any shape such as a quadrilateral.

As mentioned above, in the workpiece | work material for a watch band of this invention, it is made from the cemented carbide which does not damage a base member, and a process part is made as a to-be-processed material which shows more favorable workability with respect to a perforation process than a base member. The base member and the workpiece are joined by diffusion bonding.

In the present invention, in particular, in consideration of the bonding strength due to diffusion bonding between the base member and the workpiece and the punchability for the workpiece, the material combination of the base member and the workpiece is a combination of Wc-Co cemented carbide Mo, Wc-Co It is selected from the group consisting of a combination of cemented carbide and Mo, a combination of a Wc-Co cemented carbide and Ta, a combination of TaC-Ni cemented carbide and Mo, and a combination of TaC-Ni cemented carbide and W-Ni. Therefore, the punching part is easy and the joining strength is excellent, so that a watch band part excellent in dimensional accuracy can be obtained. It is not necessary to perform the electric discharge machining as in the prior art, and the machining portion can be processed by the normal punching, so that the machining time can be significantly shortened. Since the workpiece is joined to the base member by diffusion bonding, the workpiece can be bonded to the base member when the base member is sintered or HIP formed. Therefore, the manufacturing process can be simplified.

Claims (6)

In a work piece for a watch band (1), wherein the work piece is finished with a watch band component by punching out the work piece, the work part is made of a work piece (3) which exhibits better workability with respect to the punching work than the remaining base member (2). The workpiece 3 is joined by diffusion bonding of the base member 2, and the material combination of the base member 2 and the workpiece 3 bonded to the base member 2 is Wc-Co. Combination of cemented carbide and Mo, Wc-Co cemented carbide and W, Combination of Wc-Co cemented carbide and Ta, Combination of TaC-Ni cemented carbide and Mo and Combination of TaC-Ni cemented carbide and W-Ni alloy Watch band processing material, characterized in that selected from the group consisting of. The work piece for watch band according to claim 1, wherein the member to be processed (3) is a metal of the periodic table IV, V or VI or an alloy of two or more kinds thereof. The workpiece material for a watch band according to claim 1, wherein the diffusion bonding is a sinter diffusion bonding. The workpiece material for a watch band according to claim 1, wherein the diffusion bonding is a HIP diffusion bonding. The workpiece material for a watch band according to claim 1, wherein the diffusion bonding is a diffusion bonding formed by sequentially sintering and HIP. The workpiece material for a watch band according to claim 1, wherein the diffusion bonding is a diffusion bonding formed by simultaneously sintering and HIP.

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