DE19958516C1 - Unit for storing and transporting plate shaped components made of brittle materials and provided with one structured surface comprises means allowing such components to be bent in a specific manner - Google Patents

Abstract

The unit - for storing and transporting plate shaped components made of brittle materials and provided on one side with a structured surface in the form of parallel grooves, for example - comprises means allowing such components to be subjected to flexure so that the structured surface is under compressive stress and the resulting line of deflection runs perpendicular to the parallel grooves.

Description

The invention relates to a device for storing and transporting in essential plate-shaped components made of brittle material, the egg ne one-sided structured surface in the form of parallel channels.

Furthermore, the invention relates to a device for storage and for trans port of essentially plate-shaped components made of brittle Material that has a one-sided structured surface of any structure exhibit.

For the production of flat screens (displays) are plate-shaped construction parts made of brittle material, especially glass, used a surface structured on one side in the form of parallel channels sen.

These so-called channel plates preferably have a length of 400 to 1000 mm, a width of 300 to 600 mm and a thickness of, for example about 1.9 mm.

The one-sided structuring of the surface of such a channel plate can be done in a variety of ways. So the parallel channels be applied, for example by means of screen printing, in such a way that 10 to 20 Glass solder layers arranged one above the other on a thin glass plate become.

Furthermore, the channels can also be formed, for example, by means of hot forming, etching, Grinding (mechanical machining) or abrasive blasting in a glass plate are introduced. In general, the manufacture of channel plates very time and cost intensive.

A typical channel geometry and arrangement has the following dimensions: Channel height: 190 µm; Channel width: 240 µm; Distance between channels: 110 µm.  

Especially when the channels are worked out of the full glass plate high notch results when the duct plate is subjected to external bending stress tensions in the very small transition radii of the channels. Because through the Machining the glass plate often cause microcracks, it can already cause slight bending of the duct plate due to excessive voltage come to break the channel plate.

Suitable brackets and clamping devices can be used to make such critical Avoid bending while structuring the surface the. This can occur during later storage and especially when transporting the surface-structured plates can no longer be easily guaranteed the. In addition to static loads, they occur particularly during transport increased dynamic loads, e.g. B. bumps, to vibrate lead towards the plates.

It is therefore an object of the invention to provide a device for storage and Transport of essentially plate-shaped components from brittle Material that has a one-sided structured surface in the form of parallel Have channels to be found that effectively critical critical component bending prevented and thus safe storage and transport possible.

Furthermore, it is an object of the invention to provide a device for storage and for the transport of essentially plate-shaped components from brittle broth material, which has a one-sided structured surface of any structure have to find, which also effec critical bending of the components tiv prevented.

According to claim 1, the object is achieved by a device for storage and for the transport of essentially plate-shaped components from brittle broth material that has a one-sided structured surface in the form of pa have parallel channels, solved, with means for exercising a bending chip on the respective component in such a way that the structured surface of a Is subjected to compressive stress and the resulting bending line of the textured th surface runs transversely to the parallel channels.

Critical bending can occur due to the measures according to the invention of the components, which could otherwise lead to the components breaking, effectively  be prevented. The device according to the invention allows safe La storage and the safe transport of the components.

For example, the maximum tensile stress for a corresponding bend loading of an unprocessed glass plate that is articulated on both sides (Length: 1000 mm, thickness: 1.9 mm, maximum deflection 2.7 mm) about 1.6 MPa, the tensile stress is correspondingly structured ten glass plate, which has an above-mentioned geometry and arrangement of paral lelen channels, more than 5 MPa. The amount of tension depends it essentially depends on the size of the transition radii in the channels. The stated tensile stress of more than 5 MPa results for transitional ra serve around 6 µm. However, if there is a corresponding bending load, it is open tensile stress occurring even with larger transition radii greater than that of raw glass plate.

According to the invention, care is taken in storage and transportation wear that a critical bend that leads to the occurrence of high tension could ultimately lead to breakage. About that it is also advantageous if the structured surface, especially in the loading range of transition radii during storage and transportation pace is exposed to compressive stresses.

The means for exerting the bending stress preferably allow the setting development of a predetermined bending line and thus the targeted exercise of the bending tension on the component.

The means for exerting the bending stress particularly preferably allow the Setting a predetermined bending line that follows the course of the bending line never of the component articulated on both sides under constant, even would correspond to surface stress.

For a non-structured component, for example a glass pane, the stress distribution can be calculated analytically using the equations of the linear beam theory (Bernoulli beam). For a beam articulated on both sides under constant line loading q ₀ (ie dead weight), the greatest bending stress occurs in the middle at x = 1/2 (see Fig. 4).

The bending line w (x) for the system is:

where El is the bending stiffness.

And for the maximum bending stress τ _max at x = 1/2:

where E is the modulus of elasticity and h is the bar thickness.

Table 1 shows the maximum bending stresses for different lengths depending on the deflection in the middle (w _max ).

Table 1

Tensile stresses on unprocessed plates as a function of the deflection

It is advantageous if the means for exerting the bending stress are the setting of a defined bending line of the form:

allow.

The maximum deflection of the component is preferably chosen so that that on the side opposite the structured surface one in front  given tension is set, this tension a Should not exceed a maximum of 3 MPa, in particular 2 MPa.

The means for exerting the bending stress preferably allow the on position of the specified tension on the opposite side the structured surface.

In a particularly preferred embodiment of the invention, the means exist to exert the bending stress from at least two molded parts between which can be arranged at least one component, the exercise of bending tension on the molded parts on the intermediate component.

A molded part and a component are always superimposed arranged; beginning and ending with one molding each. In this way se can with a device according to the invention several components la like and transport.

The molded parts protrude to protect the fragile components all round preferably laterally beyond the components.

So during transport and storage in case of a possible relative shift between the components and the molded parts no abrasive Ver wear occurs, the molded parts, at least on those with the components in Contact standing side, made of a material with a low shear modulus, eg. B. Styrofoam.

The molded parts are preferably put together by an outer holder hold.

Furthermore, at least the outer top or bottom of the form parts protected against external influences, such as rough force.

The device according to the invention is preferably used for storage and for the transport of essentially plate-shaped components made of glass, Ceramics or glass ceramics that have a one-sided structured surface in shape of parallel channels, for example channel plates, in particular those for the production of flat screens (displays).  

The components can be in the raw state or in a modified form for example provided with electrodes or with coatings.

To essentially plate-shaped components made of brittle material, which have a one-sided structured surface of any structure, To protect against critical bending, it is essential that the device for storing and transporting such components Has bending stress on the respective component, so that the structured Surface is exposed to compressive stress. Exercising the bend voltage should be chosen so that in particular due to the structure ration of the surface weakened areas of a compressive stress sets are.

The invention is illustrated by the following examples and drawings to be refined.

Show it:

Fig. 1 is a channel plate in cross-section,

Fig. 2 shows a device according to the invention in cross section, and

Fig. 3 shows a further device according to the invention in cross section.

Fig. 4 is a bilaterally articulated beam (z. B. a component) under constant line loading

Fig. 2 shows an inventive device for storing and transporting a substantially plate-shaped component ( 3 ) made of brittle material, which has a one-sided structured surface in the form of parallel channels ( 4 ), with means for exerting a bending stress on the component such that the structured surface, in particular the region of the transition radii of the channels, is exposed to compressive stress and the resultant bending line of the structured surface extends transversely to the parallel channels.

The means for exercising the bending stress consist of a lower part ( 1 ) and an upper part ( 2 ), which are preferably made of polystyrene or a similar material with a low shear modulus.

The lower molded part ( 1 ) has a slightly inwardly curved, channel-shaped surface ( 1 a) and the upper molded part ( 2 ) has a correspondingly designed outwardly curved surface ( 2 a).

The component ( 3 ), e.g. B. a channel plate according to FIG. 1, arranged between the two molded parts ( 1 , 2 ) in such a way that the non-structured surface of the component comes to rest on the surface ( 1 a) and the structured surface on the surface ( 2 a). Make sure that the parallel channels ( 4 ) run parallel to the trough-shaped curvature of the molded parts ( 1 , 2 ).

By joining the two molded parts ( 1 , 2 ), the component ( 3 ) essentially adjusts to the curvature of the molded parts, with a bending stress being exerted on the component in such a way that the structured surface is exposed to compressive stress and the resulting bending line of the structured parts Surface runs across the parallel channels.

Characterized in that the component ( 3 ) of the curvature of the molded parts ( 1 , 2 ) adapts in wesent union, the resulting bending line can be specified and adjusted by a corresponding design of the curvature.

At the same time, the resulting bending stress and thus the resulting compressive stress on the structured surface and the tensile stress on the unstructured upper surface of the component can be adjusted via the depth of the curvature of the molded parts ( 1 , 2 ). The deeper the curvature, the higher the resulting bending stress.

The curvature of the molded parts preferably has a shape course:

on the corresponding course of the resulting bending line of the form partly corresponds.

The two molded parts are held together by means of an outer holder ( 5 ) consisting of an upper and a lower cover plate made of aluminum and at the same time protected against external influences.

Fig. 3 shows an inventive device for storing and transporting two components ( 3 ), the central molded part ( 6 ) both an inwardly curved, channel-shaped surface ( 6 a) and a correspondingly outwardly curved surface ( 6 b ) having.

Starting with a lower molded part ( 1 ) and ending with an upper molded part ( 2 ), a component ( 3 ) and a molded part ( 6 ) can always be arranged one above the other, so that the device according to the invention is suitable for storing and transporting several components is.

Reference list

1

lower molding

1

a inwardly curved, trough-shaped surface of the lower molding

2nd

upper molding

2nd

a correspondingly outwardly curved surface of the upper molded part

3rd

plate-shaped component (e.g. duct plate)

4th

parallel channels

5

outer bracket

6

middle molding

6

a inwardly curved, trough-shaped surface of the middle molding

6

b correspondingly curved surface of the middle molded part

Claims (13)

1. Device for storing and transporting essentially plates shaped components made of brittle-brittle material, which one-sided structure Show turured surface in the form of parallel channels with means to exert a bending stress on the respective component in such a way that the structured surface is exposed to compressive stress and the right resulting bending line of the structured surface transverse to the parallel Channels runs. 2. Device according to claim 1, characterized, that the means of exerting the bending stress hiring one before allow given bending line. 3. Apparatus according to claim 2, characterized in that means for exercising the bending stress, the setting of a defined th bending line of the shape
allow. 4. The device according to at least one of claims 1 to 3, characterized, that the means of exerting the bending stress hiring one before given tension on the opposite side of the struktu allow surface. 5. The device according to claim 4, characterized, that the means of exerting the bending stress hiring one before given tensile stress of maximum 3 MPa on the opposite Allow side of the textured surface. 6. The device according to at least one of claims 1 to 5, characterized,  that the means for exerting the bending stress consist of at least two Molded parts exist between which at least one component can be arranged is, the exercise of the bending stress on the molded parts depending on the because there is intermediate component. 7. The device according to claim 6, characterized, that alternately always a molded part and a component superimposed are arranged. 8. The device according to claim 6 or 7, characterized, that the molded parts protrude laterally beyond the components. 9. The device according to at least one of claims 6 to 8, characterized, that the molded parts are made of a material with a small shear modulus. 10. The device according to claim 9, characterized, that the molded parts are made of styrofoam. 11. The device according to at least one of claims 6 to 10, characterized, that the molded parts together by at least one outer bracket are held. 12. The device according to at least one of claims 6 to 11, characterized, that at least the outer top or bottom of the molded parts against outer is protected from external influences. 13. Device for storing and transporting essentially plates shaped components made of brittle-brittle material, which one-sided structure tured surface of any structure, with means for Exercise a bending stress on the respective component such that the structured surface is exposed to compressive stress.