EP2132744A1 - Modified optical data carrier having a clamping region - Google Patents

Abstract

The invention relates to a disk-shaped optical data carrier having a substrate containing plastic, and at least one light reflecting cover layer, and having a top and a base. The data carrier has an exterior region serving for receiving data, and an interior region having a clamping region, in which at least one elevation is disposed, which extends away from the top or base of the data carrier. A covering plane is defined by the elevations in the clamping region, the plane being substantially parallel to the top or to the base of the data carrier and having at least three contact points on the elevations.

Description

 Modified optical data carrier with clamping area

Description

The present invention relates to an optical data carrier. Such optical data carriers are e.g. known as Compact Disc (CD) or Digital Versatile Disc (DVD).

These known data carriers consist of a thin cylindrical disc of polycarbonate, on which a thin metal layer is vapor-deposited, which in turn is usually covered by a protective lacquer, etc.

According to the standard, such a CD or DVD has a thickness of 1, 2 mm, wherein the proportion of the reflective aluminum layer of the paint is only about 50 - 150 nm.

The production of such optical data carriers is relatively expensive. The present invention is therefore based on the object of specifying an optical data carrier which can be produced at lower costs. This object is achieved by the subject matter of claim 1. Preferred developments of the invention are the subject of the dependent claims.

The data carrier according to the invention has the advantage that it can be produced with a considerably smaller amount of plastic material than conventional data carriers. This is achieved in that the thickness of the data carrier, in particular and preferably the thickness of the plastic layer in the inner and outer regions is lower than the layer in the clamping region with the associated elevations.

The invention is based on the following considerations:

The plastic material is one of the decisive cost factors in the production of optical data carriers. Today's standards for CD and DVD prescribe a thickness of the disk of 1, 2 mm. However, there is a certain tolerance in the standard, so falling below or exceeding it by small amounts does not affect the readability of the CD. In addition, the focusability of the laser devices is not significantly impaired by the differences in thickness.

The loss of stability due to the decrease in thickness is counteracted by the reduction of the centrifugal forces during rotation of the data carrier, which decrease in proportion to the rotating mass and represent a substantial material load for the data carrier due to the high rotational speeds of current CD and DVD drives.

In the following description, "top" refers to the side of the disk-shaped recording medium which faces away from the laser during the reading and writing operation, and "down" to the side facing the laser.

The support area of the CD player on which the data carrier rests, is held and driven during operation is referred to in the specification as a clamping area. The standard defines the clamping area in the radial direction between an inner diameter of d ₂ = 26 mm and an outer diameter of d ₃ = 33 mm min. firmly. In the thickness direction, a flatness of 0.1 mm is required for the lower side and that this lies on the reference plane P. For the upper side, a parallelism to the reference plane P of 0.2 mm is required and this defines the reference plane Q.

As cross-sections, unless otherwise stated, referred to in the context of this invention, the perpendicular to the disk cross-sections.

The standard for CDs and DVDs provides that the data body is circular. This is also preferred for the data carrier according to the invention.

Deviating from this, the data medium can also have a different shape in its outer contour of the outer area, and be selected from a group of forms which are a triangle, a quadrangle, a pentagon, a hexagon or an N-shaped corner with an arbitrary number of N's having. Furthermore, this group of shapes may also have an elliptical, oval or otherwise formed with a curved outline.

The inner region is preferably cylindrical. He can, too

Have molds from the aforementioned mold group. Also, the intermediate region may have a shape of the aforementioned group of forms both in its inner contour facing the inner region and in its outer contour facing the outer region.

The outer region of the optical data carrier is preferably flat on its upper and lower sides for all embodiments.

Collisions of the read-write device of the drive with the elevations do not occur because the elevations are located in the clamping region of the data carrier, which is unaffected by the function of the read-write device of the drive.

The novelty of the invention, which saves on material, lies in the possibility of covering the thickness of both the inner and the outer region of the data carrier. - A -

compared to the conventional thickness formed, while continuing due to the existing surveys in the clamping area a defined, stable and secure recording of the disk in the clamping area of the drive is done, whereby the playback quality is not affected. For this purpose, at least one elevation in the clamping area is provided, which extends away from the top and / or bottom of the data carrier. The contour for the number of formed elevations may be rotationally symmetric or partially rotationally symmetrical, but also be subject to no symmetry. The existing elevations extend from the top and / or bottom of the disk to the maximum allowable thickness for an optical disk according to specification. The elevations in the clamping region define a clamping plane, which is substantially parallel to the top and / or bottom of the data carrier, and is defined by at least three points on the top and / or bottom facing away from end face of at least one survey.

The elevations may also have recesses which extend from the clamping plane in the direction of the data carrier. As a result, the support function of the clamping area must not be affected. The guiding function of the central hole of the data carrier is retained, since the elevations are set at a sufficient distance from the edge of the hole. The arrangement of the existing elevations in the circumferential direction is designed such that imbalances in the rotating data carrier are avoided, which would lead to a load on the data carrier and drive.

Between the inner region and the survey, an intermediate region may be provided. This intermediate region may include a gradual reduction in thickness between the above ranges. The intermediate region can be designed so that it can have a straight, concave or convex shape or a combination of shapes of this group of shapes in cross section.

It is also possible to provide an intermediate region between the inner region and the outer region or between the outer region and the edge region or both. This intermediate area can be a gradual one Include reduction in thickness between the areas of different thickness. The intermediate region can be designed so that it can have a straight, concave or convex shape or a combination of shapes of this group of shapes in cross section.

According to a first embodiment, the optical data carrier is designed so that the inner cylindrical region on its upper, on the writing and reading the laser side facing away, i. the side on which the metal layer is vapor-deposited and the outer, intended for data recording area on its upper side, preferably designed substantially flat. Within the clamping area preferably three elevations are arranged, which preferably extend away from the upper side of the data carrier. Each elevation is preferably rotationally symmetrical and has a transition region towards the inner region. In the circumferential direction, these elevations are preferably arranged offset by 120 ° degrees. This is explained by the resulting advantageous three-point storage, which spans a plane which serves as a support surface in the drive. The thickness of the inner and outer regions are preferably identical here and preferably have a smaller thickness than the maximum permissible thickness. The data carrier has a disk-shaped form.

In a second embodiment, the optical data carrier is designed such that the inner cylindrical region on its upper side facing away from the laser during writing and reading, i. the side on which the metal layer is vapor-deposited and the outer, intended for data recording area on its upper side, preferably designed substantially flat. In the clamping area, a survey is preferably arranged, which preferably extends in the entire clamping area of the upper side of the data carrier away. The thickness of the inner and outer regions are preferably identical and preferably have a smaller thickness than the maximum permissible thickness.

In a preferred embodiment of the data carrier according to the invention, the information-carrying structure is preferably received in the plastic material, preferably pressed. This is called a prerecorded Disk. Thus, this disk may preferably serve as a readable data storage. In particular data with audio information according to the usual CD audio standard or according to the MP3 standard are preferred as data, but also data with image information and data with image / audio information as well as data with video information and video / audio information as well as other data ,

In another preferred embodiment, the data carrier, for example, an additional functional layer, which is used for writing with an information structure by the drive. This information structure can be embodied, for example, as in the case of a standard CD-R data carrier, by inserting a dye layer between the plastic material and the reflection layer into which the drive burns an information structure with increased laser intensity compared to the reading process. Thus, this embodiment is characterized in that data can be written to the disk. In particular, data carriers that can be written to the CD standard (CD-R, CD-RW), but also data that can be written to the DVD standard (DVD + R, DVD-R, DVD + RW, DVD -RW).

The dimensions in the context of this invention are exemplary, but belong to the invention insofar as the current standards are concerned. Differing dimensions are possible when changing the standards or when agreeing on new standards.

Further advantages, features and possible applications of the present invention will become apparent from the following description of exemplary embodiments in conjunction with the figures. Show:

Figure 1 shows a bottom view of an optical disk according to the prior art, here a CD.

FIG. 2 shows a section through a disk-shaped optical data carrier with the dimensions of the clamping region according to the standard specification. FIG. 3 shows a plan view and a cross section through the optical data carrier according to the invention with elevations according to the first embodiment.

FIGS. 4 a to 4 f show variants of the contour shape of the transition from the inner region to the elevation of the optical data carrier according to the invention.

Figure 5 shows a plan view of an optical disk according to the invention with surveys according to the second embodiment.

FIG. 6 shows a plan view of an optical data carrier according to the invention with elevations according to a further embodiment.

The same reference numerals in the figures designate the same or similar parts.

Fig. 1 shows an optical data carrier, namely a conventional CD according to the prior art.

The CD 1 has a diameter of 120 mm and an inner opening 9 with a diameter of 15 mm. The CD is a disk-shaped component.

The innermost position of the laser in which data can be read is approximately 22 mm in radius and the recording layer begins at a radius of approximately 25 mm. The clamping region 10 is shown hatched.

Fig. 2 shows a section through a disk-shaped optical disk. The clamping area is defined in the radial direction by the inner diameter d ₂ and by the outer diameter d ₃ . The clamping region extends from the lower side (which forms the reference plane P) to the maximum permissible thickness of the data carrier, which has the reference plane Q on its upper side.

Fig. 3 shows a first embodiment according to the invention. Again, the optical disk is a substantially cylindrical disk and has a diameter of 120 mm. Within the clamping area 10, three elevations formed 30, each of which is limited in the radial direction according to the inner and outer diameter for the clamping portion 10. The contour of the elevations in a plan view is circular in each case. The elevations are arranged circumferentially offset by 120 °. The elevations extend in the direction away from the upper side 7 of the data carrier up to the maximum permissible extent of the specification from the CD standard for the thickness.

The inner region 2 has a first thickness Di, which is lower than specified in the CD standard. The outer region 3 has a second thickness D ₂ , which is identical to the first thickness D ₁ and in the exemplary embodiment is 0.63 mm. In this way, thus almost half of the plastic material required for the production, preferably polycarbonate can be saved. The elevations have a diameter of 4 mm in the clamping area and a diameter of 6 mm in the inner area. The elevations are mushroom-shaped elevations.

The cylindrical recess 9 serves to guide the data carrier and, like the inner region 2 and the outer region 3, is designed concentrically about an axis of symmetry 50. A reflection layer 6 is provided on the upper side of the data carrier over the outer region 3. The thickness of the reflective layer is typically 50-150 nm and is exaggerated in the present figures in favor of the clarity of the drawing, since the drawn ratio to the total thickness of the data carrier of 1, 25 mm is too large.

The height variations according to the invention between the inner region 2 and the existing elevations 30 of the data carrier require areas of the data carrier in which the height transitions take place. These may be in the form of a step or as an intermediate region.

FIGS. 4a-4f show various exemplary embodiments of the intermediate region 32 between an elevation 30 in the clamping region 10 and the inner region 2 of the data carrier in cross sections. Likewise representations represent any other intermediate areas than transitions of areas of different heights. FIG. 4a shows the exemplary embodiment of an intermediate region 32, which configures the transition between a base 31 to the elevation 30 such that the profile 35 has a straight shape.

FIG. 4b shows the exemplary embodiment of an intermediate region 32, which configures the transition between a base 31 to the elevation 30 in such a way that the profile 35 has a concave shape.

FIG. 4c shows the exemplary embodiment of an intermediate region 32, which configures the transition between a base 31 and the elevation 30 such that the profile 35 has a convex shape.

FIG. 4d shows the exemplary embodiment of an intermediate region 32, which configures the transition between the inner region 2 and the elevation 30 in such a way that the profile 35 has a straight shape, wherein the base 31 is omitted.

FIG. 4e shows the exemplary embodiment of an intermediate region 32 which configures the transition between a base 31 and the elevation 30 such that the profile 35 has a combination of a concave and a convex shape. The curves 35 can also have any combination of the above form groups.

FIG. 4f shows a course of an intermediate area according to the embodiment of FIG. 4c, wherein the elevation 30 has a recess 34, which extends in the direction of the data carrier.

In Fig. 5, a second embodiment with reference to FIG. 3 will now be described. In this embodiment, the inner region 2 also has a thickness D ₁ which is identical to the thickness D ₂ and also amounts to 0.63 mm. Both the inner regions 2 and the outer region 3 are made flat. The cylindrical recess around the symmetry axis 50 in turn serves to receive the data carrier. It is exactly one elevation 30 formed as an annular element, the inner diameter and the outer diameter of which are identical to the specifications for the respective diameter of the clamping region 10 (shown interrupted). The comments on the he elevation are substantially identical to the embodiments of Figure 3. The transition region between the inner region 3 and the elevation 30 is formed for the element 32 in the form of a triangle as shown in FIG. 4d. The data carrier has a disc-shaped form.

In Fig. 6, a further embodiment with reference to FIG. 3 will now be described. In this embodiment, the inner region 2 also has a thickness D ₁ , which is identical to the thickness D ₂ and is also 0.8 mm. Both the inner regions 2 and the outer region 3 are made flat. The cylindrical recess around the symmetry axis 50 in turn serves to receive the data carrier. Exactly two elevations are formed in the clamping region 10 (shown interrupted), which also extend in the radial direction between the inner and outer diameter according to the specification of the CD standard. Each elevation is formed in the circumferential direction in each case as an annular segment, which extends approximately along a quarter circle. The transition region between the inner region 3 and the elevation 30 is formed for the element 32 in the form of a triangle according to FIG. 4d. The data carrier has a disc-shaped form.

Claims

Patent claims

Anspruch [en] A disk-shaped optical data carrier (1) having a substrate which includes plastic material and at least one light-reflecting cover layer, and having an upper side and a lower side, characterized in that the data carrier (1) has an outer region (3) for receiving Data serves, and an inner region (2) with a clamping region (10), wherein in the clamping region (10) at least one elevation (30) is arranged, which extends from the top and / or bottom of the data carrier (1) away.

2. Optical data carrier according to claim 1, characterized in that a clamping plane (80) is defined by the elevations (30) in the clamping region (10), which is substantially parallel to the top and / or bottom of the data carrier (1), and has at least three touch points on the survey / elevations (30).

3. Optical data carrier according to at least one of the preceding claims, characterized in that the clamping region (10) of the data carrier has a plurality of elevations.

4. Optical data carrier according to at least one of the preceding claims, characterized in that the elevation (30) in the clamping region (10) has at least one recess which extends from the clamping plane (80) towards the data carrier.

5. Optical data carrier according to at least one of the preceding claims, characterized in that the shape of the survey (30) in the clamping region (10) of the data carrier in plan view has a contour whose course annular, circular, angular or a combination of designs from this Form group can be.

6. Optical data carrier according to at least one of the preceding claims, characterized in that at least one survey in the clamping area (10) with the data carrier (1) is formed integrally.

7. Optical data carrier according to at least one of the preceding claims, characterized in that the transition from the inner region (2) to the elevation (30) is formed as an intermediate region which in a sectional plane perpendicular to the data carrier (1) has a contour, the design of a straight or curved shape or is a combination of forms of this form group.

8. Optical data carrier according to at least one of the preceding claims, characterized in that the data carrier (1) has a contour in a plan view at the edge of the inner region and at the edge of the outer region, which is preferably circular but also a shape deviating therefrom can have, which is selected from a group of forms having a triangle, a quadrangle, a pentagon, a hexagon or an N-corner with any number of N, which form group also an elliptical, oval or otherwise as with a ge - Curved outline may have formed structure.

9. Optical data carrier according to at least one of the preceding claims, characterized in that a plurality of elevations in the clamping region (10) of the data carrier in the circumferential direction are arranged substantially equidistantly.

10. Optical data carrier according to at least one of the preceding claims, characterized in that the data carrier (1) has a data-carrying information structure, which is arranged in the plastic material, preferably pressed.

1 1. An optical disk according to claim 10, characterized in that the data carrier (1) has at least one recordable information layer.

12. Optical data carrier according to one of the preceding claims, characterized in that the data carrier (1) is designed so that the information layer with the information stored in the outer region (3), from the bottom is readable.

13. Optical data carrier according to one of the preceding claims, characterized in that in the clamping region (10) on the top and / or bottom three at an angle of 120 ° spaced elevations are arranged, which are substantially elevations, each with a diameter in the clamping area in a range from 3 mm to 5 mm, preferably 4 mm, and a distance in the range of 14 mm to 18 mm, preferably 16.5 mm, from the center of the data carrier to the center of the survey in the clamping area, and a diameter of the survey in the range of 5 mm 10 mm, preferably 6 mm, at their base.

14. Optical data carrier according to one of the preceding claims, characterized in that the disk-shaped data carrier has a total thickness in the range of 1.0 mm to 1.6 mm, preferably 1.25 mm, with a thickness of the data carrier in the outer region (3) in the range between 0.55 mm and 0.75 mm, preferably with a thickness of 0.63 mm, and a total thickness of the elevations in the range between 1.0 mm and 1, 1 mm, preferably of 1, 02 mm.