阅读说明：本技术 用于压纹的方法及模具 (Method and mould for embossing ) 是由 简·耶德尔贝格 于 2019-07-01 设计创作，主要内容包括：本公开涉及一种对塑料片进行压纹的方法和相应的模具(1)。将塑料片在第一半模具和第二半模具(3、5)之间压制并同时加热,从而在塑料片的第一面和第二面(19、21)上压印图案。将参考标记(31、33)压印在塑料片的两个面上,并对有压纹的塑料片进行光学评估以基于第一参考标记和第二参考标记的相对位置确定误差数据。这允许基于误差数据来调整压纹模具,以用于随后的多个压纹操作。(The present disclosure relates to a method of embossing a plastic sheet and a corresponding mould (1). The plastic sheet is pressed between the first and second mold halves (3, 5) and simultaneously heated, thereby imprinting a pattern on the first and second sides (19, 21) of the plastic sheet. Reference marks (31, 33) are embossed on both sides of the plastic sheet and the embossed plastic sheet is optically evaluated to determine error data based on the relative positions of the first and second reference marks. This allows the embossing die to be adjusted based on the error data for a subsequent plurality of embossing operations.)

1. A method for embossing a plastic sheet between a first mold half and a second mold half, wherein the plastic sheet is pressed and heated between the mold halves while a pattern is imprinted on a first side and a second side of the plastic sheet, characterized by:

-embossing (51) at least one first reference mark on a first side of the plastic sheet and at least one second reference mark on a second side of the plastic sheet,

-evaluating (53) the embossed plastic sheet with optical means to determine error data based on the relative positions of the first and second reference marks, and

-adjusting (55) an embossing die for a subsequent plurality of embossing operations based on the error data.

2. A mould (1) for embossing a plastic sheet, the mould comprising a first half-mould (3) and a second half-mould (5), wherein the plastic sheet is pressed and heated between the half-moulds while a pattern is impressed on a first and a second side (19, 21) of the plastic sheet by means of a first and a second stamp (11, 13) associated with the first and the second half-mould, respectively, characterized in that:

-the first stamp and the second stamp are configured to imprint at least one first reference mark (31) on a first side of the plastic sheet and to imprint at least a second reference mark (33) on a second side of the plastic sheet,

-at least one camera (37, 35) for evaluating the embossed plastic sheet for determining error data based on the relative positions of the first and second reference marks, an

A control unit (39) for adjusting the embossing die for a subsequent plurality of embossing operations based on the error data.

3. Mould according to claim 2, wherein at least one of said first and second dies (11, 13) floats with respect to the respective half-mould (3, 5).

4. A mould according to claim 2 or 3, wherein the first half-mould (3) is moved by means of a plurality of servos (23, 25, 27) and the control unit (39) controls the servos so that the half-moulds (3, 5) are closed in an inclined manner so as to move the first stamp (11).

5. A mould according to any preceding claim, wherein the mould is configured to form four or more reference marks on the plastic sheet, and first and second cameras (35, 37) evaluate the reference marks at different positions on the plastic sheet.

6. A mould according to any preceding claim, wherein the mould is configured to separate the reference marks from the areas (29) embossed with the fine optical pattern.

7. A method for embossing a plastic sheet (7) between a first half-mould (3) and a second half-mould (5), wherein the plastic sheet is pressed and heated between the half-moulds while a pattern is impressed on a first and a second side (19, 21) of the plastic sheet by means of a first and a second stamp (11, 13) associated with the first and the second half-mould, respectively, characterized in that:

the first half-mould (3) is moved by a plurality of servos (23, 25, 27) and

the first half-mould (3) is moved in an inclined manner towards the second half-mould (5) so as to press the position of the mould (11) when the mould is closed.

8. An embossing die (1) comprising a first half-die (3) and a second half-die (5) for embossing a plastic sheet (7) between the first half-die and the second half-die, wherein the plastic sheet is pressed and heated between the half-dies while a pattern is embossed on a first side and a second side of the plastic sheet by means of a first stamp and a second stamp (11, 13) associated with the first half-die and the second half-die, respectively, characterized in that:

at least one of the half-moulds (11) is floating with respect to the respective half-mould (3),

the first mold half is configured to be moved by a plurality of servos (23, 25, 27), an

A control unit (39) configured to move the first half mould (3) in an inclined manner towards the second half mould (5) so as to press the position of the moulds when the moulds are closed.

Technical Field

The present disclosure relates to a method for embossing a plastic sheet between a first and a second mold half, wherein the plastic sheet is pressed and heated between the mold halves while a pattern is imprinted on a first and a second side of the plastic sheet.

Background

Such a method and mould are described for example in WO-2013/002703-a1, wherein a so-called Light Guide Plate (LGP) is produced by embossing a fine pattern on a thin transparent plastic sheet, for example using an actively heated mould.

One problem with this production method and mould is how to improve the yield in terms of finished products meeting quality requirements.

Disclosure of Invention

It is therefore an object of the present disclosure to provide an embossing method and a die providing improved throughput. This is achieved by the imprint method defined in claim 1. More specifically, in the method of the initially mentioned kind, at least a first reference mark is printed on a first side of the plastic sheet and at least a second reference mark is printed on a second side of the plastic sheet. The embossed plastic sheet is evaluated using an optical device to determine error data based on the relative positions of the first and second reference marks and to adjust the embossing die for a subsequent plurality of embossing operations based on the error data. This allows immediate detection of any misalignment between the stamps used on the top and bottom surfaces of the plastic sheet. This is particularly important if the dies used are floating relative to their respective die halves. If so, one of the dies may begin to drift and that can be easily detected.

Adjustment can be made by moving the first mold half by means of a plurality of servos (typically three servos) so that the mold halves close in a slanted manner, thereby moving the first die relative to the second die. This allows the relative position of the dies to be controlled during pressing so that misalignment between the dies can be maintained within an allowable range even without interrupting production.

The mold may be configured to form four or more reference marks on the plastic sheet, and the first camera and the second camera evaluate the reference marks at different locations on the plastic sheet. The spaced apart recording simplifies the detection of the condition under which one stamper starts to rotate.

Typically, the reference marks are separated from the areas (e.g., for light guide plates) that are imprinted with the fine optical pattern.

A method and a corresponding mold for embossing a plastic sheet between a first and a second half mold are also contemplated, wherein the plastic sheet is pressed and heated between the half molds while a pattern is impressed on a first and a second side of the plastic sheet by means of a first and a second stamp associated with the first and the second half mold, respectively. The first mold half is configured to be moved by a plurality of servos (typically three) and the first mold half is moved in a tilting manner toward the second mold half so that the position of one die is moved relative to the other die when the molds are closed.

Drawings

Figure 1 schematically depicts an embossing die.

Figure 2 schematically shows an embossing die modified to compensate for die drift.

Fig. 3 shows a detection method.

Fig. 4A-C show examples of reference marks.

Fig. 5 shows the offset of the stamp by means of the tilted half mould.

Detailed Description

The present disclosure relates to a method and a mould for embossing a plastic sheet. An example of an embossing die is shown in WO-2013/002703-a 1. Such a mold can be used, for example, for producing so-called Light Guide Plates (LGPs) for graphic display devices and televisions.

Fig. 1 schematically shows an embossing die 1. The mold has an upper mold half 3 and a lower mold half 5 and during a portion of the processing cycle, the plastic sheet blank 7 is pressed with great force and, by means of an upper die 11 and a lower die 13, a fine pattern can be impressed on one or both surfaces of the blank. The blanks may optionally be fed from a blank roll 9, as shown. Pressing can be made more efficient by heating the surfaces (i.e. the dies 11, 13) in contact with the blank 7 during pressing by means of a heating device comprising a coil 15. Furthermore, in a subsequent stage, the same surface may be cooled by cooling means 17, such as a pipe carrying a cooling medium. The mould is then opened and the embossed plastic sheet is removed to leave room for a new blank 7. The treatment cycle may end in, for example, 30 seconds.

The stampers 11, 13 provide fine patterns on the upper and lower surfaces 19, 21 of the plastic sheet 7 and may be composed of a thin flat plate structure in a ferromagnetic material. As described in the preceding document, the stamp can float with respect to the lower half-mould (as seen from the blank to be embossed). This allows the stamp to expand and contract freely during the heating and cooling phases of the embossing process. For example, if the press die is screwed to the lower half die, the press die may be deformed to some extent by screw-coupling with the half die when heated. Alternatively, the lower stamp 13 may simply be placed on the lower mold half 5 and the upper stamp 11 may be held on the upper mold half 3 using vacuum techniques.

The stamps 11, 13 may sometimes drift slightly relative to their half-moulds when pressure is applied, and the drift need not be uniform, i.e. the stamps may also drift relative to each other. This may represent a problem even though some misalignment between the patterns embossed in the upper and lower surfaces 19, 21 may be allowed. The drift may be small, only a fraction of a micron, but over multiple cycles, the cumulative misalignment may be unacceptable.

The present disclosure relates to a method for detecting such misalignment. The present disclosure also relates to a method for handling such misalignment.

Figure 2 schematically shows an embossing die modified to compensate for die drift. As previously described, the blank 7 is pressed between the first half-mould 3 and the second half-mould 5.

Here, the first mold half 3 can be moved up and down by means of three servos/actuators 23, 25, 27 while the second mold half 5 is fixed. The use of these three servos will be discussed further later.

When the blank 7 is embossed with a pattern 29, for example a light guide plate, reference marks are simultaneously embossed thereon. Typically, this is done outside of the pattern 29, although this is not required. At least one reference mark 31 (two in the case shown) is embossed on a first top surface of plastic sheet 7 and at least one reference mark 33 is embossed on a second bottom surface of plastic sheet 7.

Those reference marks are embossed using upper and lower stamps 11, 13. Thus, any misalignment between the upper and lower dies can be detected by optically recording the reference mark 31 on the top surface and the corresponding reference mark 33 on the bottom surface. One of which is recorded directly and the other through an at least partially transparent plastic sheet 7. As shown in the enlarged portion of fig. 2, misalignment may be detected as two slightly shifted patterns recorded by the camera 35. In the case shown, two cameras 35, 37 suitably spaced at least 70mm apart (e.g. 200mm apart) from each other are used. This allows not only the offset in the orthogonal direction (x, y) of the plane of the plastic sheet to be detected, but also one of the stampers rotating about an axis orthogonal to that plane and relative to the other stamper. However, as will be discussed, detection of rotational motion may also be detected using a single camera. The camera may be connected to a control unit 39 that regulates the operation of the mold, as will be discussed.

Thus, fig. 3 depicts a basic detection method in which the indicia are embossed 51 on the top and bottom surfaces. After embossing, the relative positions of those marks are evaluated 53 and, if necessary, the mould is adjusted 55 to cope with any detected misalignment, thereby improving alignment in a subsequent embossing operation on a new plastic sheet blank. As will be described, the adjustment may be performed using a multi-servo technique, but other options are possible.

Fig. 4A-4C show possible reference marks. Fig. 4A shows a possible topside marker 31 comprising a cross with a central circle. Fig. 4B shows a possible bottom side marker 33 comprising the same cross and a circle larger than the center of the circle on the top side. Fig. 4C shows a possible image recorded by the camera when the top and bottom reference marks are perfectly aligned. It should be noted that this configuration provides an option to detect the quadrature direction error (x, y) and any rotation that may occur even if the point is well aligned. However, a relatively large rotation may be required to make the cross of the bottom side markings 33 visible, and therefore it may be preferable to use a two camera solution to test the alignment between two locations on the plastic sheet 7, preferably 70mm apart, as described above.

In this way, any misalignment between the upper and lower dies can be determined. Although it is possible to temporarily stop production and adjust the position of the stamp, the present disclosure proposes another solution for adjusting the function.

Referring again to fig. 2, the upper mold half 3 is raised and lowered by three servos 23, 25, 27, which may be controlled separately. Thus, the upper mold half 3 can be lowered towards the lower mold half 5 in an inclined manner such that when the mold is closed, a wedge-shaped space is formed between the mold halves 3, 5.

This is shown in fig. 5, where the upper mould half 3 is slightly tilted by a clockwise rotation of about one degree. It should be noted that even if such a tilt is somewhat exaggerated, a tilt of about 0.1 degrees may be suitable to achieve the desired effect to be described. The inclination is such that the space between the mould half 3 and the plastic sheet 7 is slightly wedge-shaped. In the situation shown in fig. 5, the rightmost part of the upper die 11 will be pressed first. This causes some shear strain in the middle plastic sheet. This will cause the upper and lower dies to move slightly in opposite directions when the pressing is finished, as shown in the figure.

The floating dies 11, 13 can thus be moved relative to each other by closing the gap between the first and second half dies by individually controlling the servos 23, 25, 27. The use of three or more servos allows the upper mold half 3 to assume any inclination with respect to the lower mold half 5 within a wide range.

The control unit can thus generate a suitable servo control sequence based on the output from the camera and, for example, an internal look-up table, which allows the misalignment between the upper and lower dies 11, 13 to be kept within a range over a long set of production cycles. Any misalignment can also be handled using an algorithm that controls the servo, for example based on a PID controller.

By changing the wedge shape when the mold is closed, the upper die can be rotated slightly relative to the lower die to offset any rotational offset.

It should be understood that the multi-servo control scheme may be based on error data other than that produced by the camera of fig. 2, for example, using direct laser measurement of the stamper itself between pressing cycles.

The disclosure is not limited to the examples described above and may be varied in different ways within the scope of the appended claims.