JP3107592U - Tray used for optical disk drive - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a standard measuring means common to the front and back surfaces of a tray used in an optical disk drive.
Through holes and projections 30 serving as two or more measurement standards for measuring standard dimensions are formed on the front and back of a tray 20 integrally formed by injection molding of plastic.
When measuring standard accuracy from the front and back surfaces of the tray after injection molding of the tray, a reference line connecting these measurement reference portions is formed on the front and back surfaces, and the dimensional accuracy of each part of the tray is determined based on the reference line. By measuring and turning over and measuring in the same manner using the common measurement reference portion, the front and back sides can be measured with high accuracy using the common measurement reference.
[Selection] Figure 3

Description

  The present invention relates to a tray used for an optical disk drive. In particular, the present invention relates to a tray used for an optical disc drive that includes an aiming unit that is integrally formed with the tray and that uses a reference line formed through the aiming unit to accurately measure the size of each component installed on the front and back of the tray.

As shown in FIGS. 1 and 2, a known optical disc drive tray 10 manufactured by injection molding or the like performs accurate measurement after manufacturing, and determines the size of each component installed on the tray 10 and the distance between the components. It is necessary to determine the size of the mutual relationship. This is because if these sizes do not match the design standard, they cannot be installed in the optical disk drive.
The measurer needs to measure each component on the back of the tray 10 continuously after the measurement of each component on the front of the tray 10 is completed. Since no common measuring means is installed, when measuring the back surface of the tray 10 semi-finished product, the tray 10 semi-finished product needs to be turned over from the front to the back. However, once the tray 10 semi-finished product is moved, the metric is deviated, and the tray 10 also cannot accurately hold the metric used for the front and the metric used for the back. Therefore, it becomes difficult to perform accurate measurement on the tray 10.
Japanese Patent Laid-Open No. 10-30803

The known structure has the following drawbacks.
In other words, the optical disc drive tray cannot be installed in the optical disc drive unless the size of each component installed on the tray and the size of the interrelation between the components match the design standards. Therefore, these sizes must be confirmed. However, since there is no measuring means for both sides on the front and back of a known tray, when measuring the back of a tray semi-finished product, it is necessary to turn the tray semi-finished product upside down. Causes a deviation in the measurement standard due to the movement, making it difficult to perform accurate measurement on the tray.
The present invention provides a tray for use in an optical disk drive that solves the problems of the above structure.

In order to solve the above problems, the present invention provides a tray used for the following optical disk drive.
It includes at least two aiming parts that are installed on the tray and integrally molded with the tray;
A reference line is formed on each of the front and back surfaces of the tray by using the aiming part,
A tray used for an optical disc drive, which uses the reference line formed by the aiming portion to ensure the accuracy of the size of each component installed on the front and back of the tray.

As described above, since the tray of the present invention has an aiming part, the measurer uses the reference line A drawn on the front and back of the tray based on the aiming part, and the reference line B, the reference line C, A center point D can be drawn. The measurer uses them to check whether each component installed on the front surface of the tray and on the tray is completely matched to the size of the design standard, for example, the circumferential diameter of the optical disk loading portion on the front surface of the tray and the rear surface of the tray. It is possible to measure whether or not the splines are fully consistent with the design standard size. Since each aiming part of the present invention is installed at the same position both on the front and back of the tray, the reference line A drawn by the measurer on the front and back of the tray is also the same reference line. The center points D obtained on the front and back sides based on the same reference line are also the center points of the same point.

As shown in FIGS. 3 and 4, all components such as the optical disk stacking portion 201, the spline 203, and the aiming portion 30 installed on the front and back surfaces of the tray 20 of the present invention are formed simultaneously by integral molding. .
The tray 20 that is integrally molded by injection molding using a plastic material or the like needs to be measured after it is manufactured to determine whether or not the manufactured tray 20 completely meets the design standard size.
Since the tray 20 of the present invention includes the aiming unit 30, the measurer can use the reference line A drawn on the front surface of the tray 20 based on the aiming unit 30. Further, a reference line B, a reference line C, and a center point D are drawn on the reference line A shown in FIG.
The center point D is the center position of the optical disc loading unit 201, and then whether each component installed on the front surface of the tray 20 using the center point D completely matches the size of the design standard, For example, it is measured whether or not the circumferential diameter of the optical disk loading unit 201 in front of the tray 20 completely matches the size of the design standard.
Similarly, as shown in FIG. 4, the measurer uses the reference line A drawn through the aiming part 30 on the back surface of the tray 20 to obtain the reference line B, the reference line C, and the center point D, respectively.
The center point D is the center position of the optical disc loading unit 201, and whether each component installed on the back surface of the tray 20 using the center point D completely matches the size of the design standard, for example, the tray 20 Measure whether the spline 203 on the back completely matches the size of the design standard.

Since each aiming part 30 of the present invention is installed at the same position on both the front and back of the tray 20, the reference line A drawn by the measurer on the front and back of the tray 20 is also the same reference line. The center point D obtained by the measurer on the front and back sides based on the same reference line is also the center point of the same point.
Further, since the aiming part 30 of the present invention and the other components of the tray 20 are manufactured by integral molding, the aiming part 30 of the present invention can further improve the accuracy of measurement.
The aiming unit 30 shown in FIGS. 3 and 4 has a perforation 30 penetrating through the front and back surfaces of the tray 20 as an example.
Furthermore, in another embodiment of the sighting unit 30 of the present invention, a projection component such as a projection component that employs a projection column that protrudes outward from the front and back surfaces of the tray 20 is taken as an example.
Of course, the aiming part 30 of the present invention is not limited to the perforation 30 and the projection forming part, but may be another aiming part 30.

FIG. 3 is a structural diagram of the front surface of a known optical disc drive tray. FIG. 2 is a structural diagram of the back surface of the optical disk drive tray of FIG. 1. It is a sighting component installed in front of the tray of the present invention. FIG. 4 is a structural diagram illustrating a state in which the aiming component of FIG. 3 corresponds to the rear surface of the tray.

Explanation of symbols

10 trays
20 trays
30 Aiming section
201 Optical disc loading section
203 Spline

Claims (5)

Form two or more common measurement reference parts corresponding to the tray front and back sides,
A tray used for an optical disc drive, wherein the size accuracy of each component installed on the front and back of the tray can be measured based on a reference line formed by the aiming unit. 2. The tray for use in an optical disk drive according to claim 1, wherein the at least two aiming portions are perforations penetrating at least two front and back surfaces of the tray. 2. The tray for use in an optical disk drive according to claim 1, wherein the at least two aiming portions are protrusions that project outward from the front and back surfaces of at least two of the trays. 4. The tray for use in an optical disk drive according to claim 3, wherein the protruding component is a protruding column. The tray for use in an optical disk drive according to claim 1, wherein the tray is a single tray made of a plastic material.

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