DE202008003205U1 - Wafer box for the transport of solar cell wafers - Google Patents

Abstract

Wafer box for the transport of solar cell wafers, comprising a base (1) and guide elements for the positioning of the solar cell wafer within the wafer box, characterized in that
- Is provided at the top of the bottom (1) coaxial with a central axis (3) four guide angle (8) consisting of an angle (9) with two centering webs (10), wherein the end faces of the centering webs (10) to the inserted Solar cell wafers are directed and the distance of the end faces of two opposite centering webs (10) corresponds to the width of the solar cell wafer,
- That the bottom (1) in the central axis (3) has an opening (4) and on a concentric circle (5) at the intersections with the diagonal (7) of the bottom (1) has four openings (6),
- That on two opposite sides of the bottom (1) each have a stack wall (12) each having a handle opening (13) is provided and
- That a support base (14) is present, whose outer configuration is designed such that ...

Description

The The invention relates to a transport container for the transport of solar cell wafers, hereafter referred to as Waferbox, consisting of a floor and guide elements for positioning the Solar cell wafer inside the wafer box.

State of the art

To In the prior art are a variety of transport containers known in which flat workpieces transported can be. Especially comes with solar cell wafers It's about it, a technologically predetermined amount thinner and to transport sensitive and sensitive solar cell wafers and gently in the wafer box or bring out.

The DE 20 2006 005 284 U1 indicates a dimensionally stable solar cell container with a rectangular or square-shaped container bottom, which has integrally formed side walls. At least two side walls have slot-shaped openings. The solar cell container is made such that it can directly accommodate the largest solar cells to be manufactured. Coordinated inserts are provided for smaller solar cells, which can be inserted into the solar cell containers and latched over lugs in recesses in the upper edge of the solar cell container. For each specific size of solar cell, a separate use is required. The inserts have equivalent slot-shaped apertures as the solar cell container.

in the Bottom of the solar cell container and the inserts are receiving openings for lifting body provided. To remove the solar cells penetrate the lifting body the receiving openings and act directly against the bottom solar cell, so that the solar cells are raised and out be removed from the solar cell container or the insert can.

task

Of the Invention is based on the object, a technically simple Waferbox for the transport of solar cell wafers, the has a relatively low weight and with which the solar cell wafer safely transported and gently introduced and deployed. The wafer box should be stackable and the attachment of separate Enable elements of modern logistics.

The Invention solves the problem by the specified in claim 1 Characteristics. Advantageous developments of the invention are in the Subclaims and are together below with the description of the preferred embodiment of the invention, including the drawing, shown in more detail.

The Wafer box according to the invention has a base Guide elements on its top for the Positioning of the solar cell wafer within the wafer box. Furthermore, a support floor is present, on which the solar cell wafer can be hung up. As guide elements are coaxial with a central axis four guide angles existing, consisting of an angle with two Zentrierstegen, where the end faces of the centering webs to the inserted solar cell wafers are directed.

there corresponds to the distance between the front sides of the parallel opposite Centering webs of the width of the inserted solar cell wafer. In the ground in the central axis, an opening is provided, the as large as possible, so that no air jams during insertion and removal of the solar cell wafers arise that complicate the handling of solar cell wafers. there This opening can also be formed multi-limbed in the form of several small openings be.

On a concentric to the centric axis circle and to the Intersections with the diagonals of the bottom are four breakthroughs available. Through these, well-known lifting elements for removing the solar cell wafer reach through. At two opposite Side of the floor is ever a stack wall, each with a handle opening intended.

Of the Support floor corresponds to a flat plate, the corresponding one having a central opening, such as the central opening in the bottom of the wafer box. The outer contour of the support floor essentially corresponds to that of the solar cell wafer. At least in an area between two parallel Zentrierstegen is on Support floor a guide bar formed in engages this area two anein other lying centering webs. It is advantageous, such guide bars in the corresponding areas to be provided between all parallel centering webs.

Appropriate Centering bars can also in the handle openings engage in the stack walls. The inventively configured Support floor is thus twist-proof inside the wafer box stored and can not fall out of the wafer box unhindered.

The parallel distances of the centering webs to each other depend on the technologically predetermined dimensions of the solar cell wafer. Currently, square or pseudo-transverse solar cell wafers are 125 × 125 mm, 156 × 156 mm and 210 × 210 mm Width in the application. On this basis, it is advantageous to uniformly equip the wafer box according to the invention with a bottom of approximately 240 × 240 mm, on which the guide angles are arranged in correspondingly different distances, ie. For each type of solar cell wafer, a special wafer box with specially arranged guide angles and associated support bottom is provided. In practice, it has proven to be sensible to mold the guide angles directly on the ground in the case of extraordinarily high quantities. But it is also possible to arrange the guide angle changeable in corresponding receptacles releasably.

The Guide angle for currently largest solar cell wafers with the dimensions 210 × 210 mm are in the area of the outer edges of the floor formed as an angle-like support columns.

Of the Diameter of the pitch circle on which the four breakthroughs for lifting elements is always smaller than a circle, the end faces of the centering webs for the smallest solar cell wafers to be transported in the wafer box (with the same bottom), d. H. with dimensions of 125 × 125 mm, connecting. In order to can be independent of the actual type of solar cell wafers always used the same lifting elements become. The lifting forces occur in the same way gently transfer the support plate to the stack of solar cell wafers.

The entire waferbox (without the support floor) becomes regular in one piece from an impact-resistant and dimensionally stable plastic produced. Such a wafer box can also be cleaned well since these in use, in particular by abrasion of the solar cell wafers pollute.

embodiments

The invention will be explained in more detail below with reference to two exemplary embodiments. Belonging to the embodiment I shows the 1 a perspective top view of a wafer box according to the invention for the wafer size of 125 × 125 mm. 2 shows a view of the bottom of the bottom of the wafer box.

Belonging to the embodiment II shows 3 a version for the currently maximum wafer size of 210 × 210 mm. The dimensions are adapted to the currently common solar cell wafer. Other dimensions may become actual in the future.

embodiment I

The wafer box consists of a floor 1 , the underside in a known manner to ensure a high dimensional stability a variety of ribs 2 having. Because of the currently common wafer sizes of 125 × 125 mm, 156 × 156 mm or 210 × 210 mm, the bottom has 1 uniformly an outer dimension of about 240 × 240 mm.

As in particular from 2 it can be seen is in the ground 1 centric to a central axis 3 an opening 4 and on a circle 5 at the intersections with the diagonals 7 of the soil 1 are four breakthroughs 6 intended.

On the top of the floor 1 are also on the diagonal 7 four guide angles 8th arranged. The guide angles 8th each consist of an angle 9 and at each of its ends a centering web 10 whose end face is directed to the inserted solar cell wafers. At the upper edges of the centering webs 10 are introductory slopes 11 educated.

The to the axis 3 radial position of the guide angles 8th depends on the size of the specific solar cell wafer used. In 1 By way of example, an embodiment for solar cell wafers having a size of 125 × 125 mm is shown. In an equivalent way, only with a slightly larger distance of the guide angle 8th would be a wafer box designed for 156 × 156 mm.

On two opposite sides of the floor 1 are two stack walls 12 provided, each one reaching to the bottom handle opening 13 exhibit. The pile walls 12 ensure safe stacking of several wafer boxes one above the other as well as good handling.

Essential to the invention, the wafer box has a support floor 14 on. The support floor 14 serves as a stable surface support for the solar cell wafers and at the same time to reduce the surface pressure of Hubstößeln that for lifting the on the support floor 14 lying solar cell wafer through the breakthroughs 6 in the ground 1 can protrude through. The lifting forces are from the support floor 14 taken up and act practically essentially over the entire surface of the support floor 14 evenly and gently on the solar cell wafers.

The support floor 14 is a stable flat plate with an exterior configuration that provides good guidance within the centering bars 10 the guide angle 8th guaranteed. In each case between two guide angles 8th is the outer contour of the support floor 14 enlarged, so that guide webs 18 be formed. The guide bars 18 ensure an additional torsion-proof guidance of the ground 14 and thus an overlying stack of solar cell wafers.

In the exemplary embodiment, the support floor 14 more guide bars 18 on that in the handle openings 12 the pile walls 12 intervention. This ensures a further guidance and in the unused state of the support floor 14 do not fall unhindered from the wafer box.

In a known manner are at the bottom in the ground 1 another three pin 15 for machine-readable coding of the type of solar cell wafer and control of the running direction of the wafer box in a mechanical transport device.

Furthermore, on one side is on the ground 1 a recording 16 provided, in which, for example, a visually readable nameplate with or without scannable information are introduced.

embodiment II

In the embodiment II with the associated 3 a wafer box is shown, which is suitable for the currently largest solar cell wafer with the dimensions 210 × 210 mm. The floor 1 is identical to the bottom of embodiment I. As guide angles are on the insides of the two stack walls 12 four centering bars 19 formed, of which the two inner Zentrierstege 19 at the same time the handle opening 13 define.

On the two sides between the pile walls 12 are centering webs 20 at support columns 17 educated. In 3 at the front are two support columns 17 connected to each other, such that a recording 16 is trained. On the opposite side of the wafferbox is exemplary on the ground 1 an RFID bag 21 for the installation of a RFID (Radio Frequency Identification) for automatic logistics systems.

In practice, the Waferboxen according to the embodiments I and II together belonging units, ie that the four Zentrierstege 19 on the pile walls 12 are also present on the wafer boxes for the solar cell wafers with the dimensions 125 × 125 mm and 156 × 156 mm, where they are the stack walls 12 additionally stabilize.

1

soil

2

ribs

3

center axis

4

opening

5

pitch circle

6

breakthroughs

7

diagonal

 8th

lead angle

8th

angle

 10

centering

11

insertion bevel

12

stacking wall

13

grip opening

14

support base

15

Pin code

16

admission

17

support column

18

guide web

19

centering

 20

centering

21

RFID bag

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - DE 202006005284 U1 [0003]

Claims (4)

Wafer box for the transport of solar cell wafers, consisting of a bottom ( 1 ) and guide elements for the positioning of the solar cell wafer within the wafer box, characterized in that - at the top of the bottom ( 1 ) coaxial with a centric axis ( 3 ) four guide angles ( 8th ), consisting of an angle ( 9 ) with two centering webs ( 10 ) is provided, wherein the end faces of the centering webs ( 10 ) are directed to the inserted solar cell wafers and the distance of the end faces of two opposing centering webs ( 10 ) corresponds to the width of the solar cell wafer, - that the bottom ( 1 ) in the centric axis ( 3 ) an opening ( 4 ) and on a concentric circle ( 5 ) at the intersections with the diagonals ( 7 ) of the soil ( 1 ) four breakthroughs ( 6 ), that - on two opposite sides of the floor ( 1 ) one stack wall each ( 12 ) each with a handle opening ( 13 ) is provided and - that a support floor ( 14 ) is present, whose outer configuration is formed such that the support floor ( 14 ) at least at the centering webs ( 10 ) to be led. Wafer box according to claim 1, characterized in that at least in the region of an outer edge of the bottom ( 1 ) two guide angles ( 8th ) as an angle-like support column ( 17 ) are formed. Wafer box according to claim 1 or 2, characterized in that the pitch circle ( 5 ) is within a circle, the front sides of the centering webs ( 10 ) connects. Wafer box according to one of the preceding claims, characterized in that on one side of the bottom ( 1 ) a recording ( 16 ), into which a rating plate or elements for logistics systems can be inserted.