1. Field of the Invention
The present disclosure relates to a method for processing a sheet of material. More particularly, it relates to a method of forming blind holes in a sheet of material
2. Description of the Related Art
A blind hole is a hollow projection opened at one end and closed at the opposite end. Blind holes have wide applications ranging from locking mechanisms to electronic devices. They are useful in situations where through holes would render a less refined appearance than desired.
Blind holes are also useful in applications requiring air-tightness, such as in hard disk drives where airflow may contaminate the interior of the hard drive. In such applications, blind holes may be formed in the casing for mounting printed circuit boards (PCB), motors, and semiconductor chips.
A conventional method of forming a blind hole begins by drilling a through hole in sheet material. One end of the through hole is then closed by placing a seal over that end. One problem arising from this method is that the depth of the hole is limited to the thickness of the sheet material. Using a thicker sheet of material will enable the construction of a deeper blind hole.
However, in portable devices, where weight and form factor are crucial, having a thick sheet of material is not practical. Another problem arises with the use of seals to close the through hole. The typical seals or plugs may not provide an air-tight seal, and hence the seal would not be an adequate seal for a blind hole of a hard disk drive casing.
Another method of forming a blind hole is by controlling the depth of drilling into a sheet material. Unfortunately, one of the problems arising from this method is that the depth of the hole is limited to the thickness of the sheet material. Further, drilled material bits may be trapped in the blind hole and requiring additional effort to remove. Removing the debris from the blind hole is usually accomplished by using compressed air, which may lodge fling debris on other parts of the sheet material.
Another conventional method of forming a blind hole begins by compressing the sheet material against a die having an orifice therein A portion of the sheet material is then extruded into the orifice by the compression to form an extruded portion by employing a ram press. A post is then forcibly inserted into the extruded portion of the sheet material so that the extruded portion forms a hollow projection around the post. The insertion of the post is controlled so that a through hole will not be formed. When the post is finally withdrawn, a blind hole or hollow projection having a closed end at the sheet material is formed. One problem with this compression method is that a recess or indentation may be formed at the side of the compressed sheet when the sheet material is forcibly extruded into the orifice. This deformation may be a thinned and weakened spot in the closed end of the blind hole. Another problem is that the sheet material experiences stretching and stress from the compression, which may weaken the sheet material or even cause failure.
In view of the foregoing, it is therefore desirable to provide an improved method of forming blind holes in a sheet material.
A method of forming a blind hole in a sheet material and a configuration of sheet material having a blind hole formed from this method are provided. The method includes punching the sheet material to define a hollow projection and shearing a layer of material from the sheet material to form a sealed end over an opening of the hollow projection to form the blind hole.
The method may also include enlarging the hollow projection to a predetermined desired diameter of the blind hole. An advantage of first forming a hollow projection and thereafter enlarging the diameter of the hollow projection to a desired diameter is to prevent excessive stretching and chipping of the sheet material.
Shearing a layer of material from the sheet material to form a sealed end over an opening of the hollow projection to form the blind hole includes the use of one or more tapered pins having progressively decreasing diameters to shear the sheet material and shift a mass of the sheared material towards a center of the opening of the hollow projection until a continuous layer seals the opening. To render a more refined appearance, the continuous layer or sealed end may be flattened by punching a flat pin over the sealed end.
A sheet material, formed according to the present method, includes a segment having a top surface and a bottom surface, and a blind hole segment coupled to the sheet material segment, wherein the blind hole segment includes a sidewall and a sealed end for defining the blind hole and wherein the sealed end is airtight.
The present method of forming blind holes is particularly advantageous as the closed end of the blind hole is rendered air-tight. Further, the maximum depth of the blind hole is no longer constrained by the thickness of the sheet material. Instead, the method allows the depth of the blind hole to be greater than the thickness of the sheet material if required by a user. Hence, cost and weight of materials can be reduced. With a deeper blind hole, screw threads can be made longer, resulting in a more secured fastening of the PCB, motor or other elements to a base plate made from the sheet material. This is especially desirable in portable devices, where form factor and secured fastening are of paramount importance.
The present disclosure will be readily understood by the following detailed description in conjunction wit the accompanying drawing. To facilitate this description, like reference numerals designate like structural elements.
A method of processing a sheet material to form blind holes is provided. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present disclosure. It will be understood, however, to one skilled in the art, that the present disclosure may be practiced without some or all of these specific details In other instances, well known process operations have not been described in detail in order not to unnecessarily obscure the present disclosure.
Depending on the requirements of sheet material 100, the hollow projection 104 at this stage may not have the desired internal diameter D3 (as shown in
After the first tapered pin 416 and additional tapered pins 516 and 616 have been used, a continuous layer 600 of sheet material forms a sealed end 600 over the hollow projection 104 (shown in
An advantage of the present invention is that the depth D2 of the blind hole can be greater than the thickness D1 of the sheet material 100. Further, by adjusting the internal diameter of the recessed segment D4 and the internal diameter D3 of the blind hole, a greater depth D2 of the blind hole can be achieved even though the thickness D1 of the sheet material 100 is unchanged. In addition, the blind hole formed in the present invention is air-tight, which is particularly important in applications where the leakage of air must be prevented.
The above-described method of forming blind holes is suitable for use in casing for hard disk drives, where PCBs and motors are mounted to the casing.
As an illustration, the sheet material 100 in a hard disk drive may have a thickness of between about 1 to about 3 mm. The resulting blind hole may have an internal diameter of about 2.6 mm and a depth of about 4 to about 5 mm. The sheet material 100 of the present disclosure is typically made of a malleable material, which may comprise a metallic element, such as, aluminum, iron and steel.
While the foregoing description refers to forming a blind hole with cylindrical configuration with circular cross-section, the described method is equally applicable to forming blind hole of other geometrical cross-sections, such as an ellipse, a rectangle and a polygon with a plurality of sides.
Other embodiments of the invention will be apparent to those skilled in the art from consideration of the specification and practice of the invention. Furthermore, certain terminology has been used for the purposes of descriptive clarity, and not to limit the present invention. The embodiments and preferred features described above should be considered exemplary, with the invention being defined by the appended claims.
Number | Date | Country | Kind |
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200407251-8 | Dec 2004 | SG | national |