The present invention is related to a method and device for supplying electrical power to a wafer. More specifically, the invention is related to a method and device for supplying electrical power to a wafer at least partially submerged in a liquid.
A device and method for exposing wafers to a liquid are described in GB patent application 0709619.1 filed on 18, May, 2007. This application is hereby incorporated by reference.
In some processes there is a need to supplying electrical power to the wafer while the wafer is at least partially submerged in the liquid. One example of such a process is electroplating, where for example Ni, Cu, Sn and/or Ag is applied to the wafer. A challenge in this process is to provide electrical contact to the wafer without applying strong mechanical forces to the wafer, which may cause breakage of the wafer. Another disadvantage in such processes is that the metal or other materials are deposited on other parts of the production equipment, and this has to be removed periodically, which increases the non-productive time for the equipment.
A solar cell wafer has normally a thickness between 160-180 μm, where there is a continuous development towards producing thinner wafers. These wafers are fragile, and must be handled very carefully to avoid breakage. At the same time there it is a desire to increase the throughput of cells in an industrial process.
The object of the invention is to provide a method and device for supplying electrical power to a wafer, where these disadvantages are avoided. Moreover, it is an object of the invention to improve the efficiency of this working operation, and hence the overall production capacity, while at the same time avoid breakage of wafers.
The present invention is defined in the enclosed independent claims. Further embodiments are described in the dependent claims.
In the following, embodiments of the invention will be described with reference to the enclosed drawings, where:
a and 6b illustrate two cross sectional views of the holding device.
In
The transportation device is further comprising a drive system (not shown) for moving the transportation bands and consequently also the wafer carrier devices 12 over the liquid container 2 as illustrated by arrows A.
Wafers 3 are picked up or are in other ways fastened to the wafer carrier device 12 near a first end of the container 2 (on the left in
In
Of course, it would be possible to transport only one wafer 3, or it would be possible to transport more than three wafers 3 in parallel.
The wafer carrier devices 12 comprises holding devices 18 with a cross section substantially formed as a dove tail joint (as shown in detail in
There are several ways of arranging and designing such a transportation device 10 and wafer carrier devices 12, and many such arrangements are shown in GB patent application 0709619.1 filed on 18, May, 2007 which is hereby incorporated by reference.
The holding device 18 further comprises electrical contacts 20 localized for example in or near the grooves 19 to provide electrical contact with the wafer while the wafer is being held by the holding device 18. The electrical contacts 20 are placed at intervals along the grooves 19, and can be applied either on the top side of the wafer, bottom side or both. It is also in principle possible to establish a different voltage on the two surfaces of the two wafers if desired from a process point of view, for example for plating. Further, the electrical contacts are connected to a power supply 32 by means of electrical wires 30, as illustrated in
In
It should be noted that since the transportation device rotates, means should be provided to avoid winding of the electrical wires 30 between the power supply and the holding devices. For example could bus bars connected to the negative terminal of the power supply be provided over the liquid. In this case, the holding devices 18 would be adapted to get in contact with the bus bars over the liquid for the desired contacting time, and consequently also provide electrical contact between the wire 30 and the electrical contacts 20.
It is important to achieve good electrical contact between the wafers and electrical contacts of the holding device. One possibility is to use spring loaded electrical contacts or electrical contacts comprising soft brushes inside or around the grooves in the holding device. Another possibility is to direct the liquid flows over and below the wafers so that the total flow pattern creates an automatic upward or downward pressure on the wafer. In the above-mentioned GB patent application 0709619 it is described how channels or carve-outs in the holding devices may be used to distribute liquid flows between the two sides of the wafer. Such channels are denoted with reference number 50 in
Another option for providing a downward acting force on the wafer could for instance be to provide a system where the liquid in the vessel is pumped from below the wafers and transferred via piping with outlets or nozzles above the wafers. Such an arrangement would create a small difference in pressure between the liquid on top of the wafers and the liquid below the wafers. The pressure difference will result in a net force on the wafers acting downwards. The required force for enabling a good mechanical and electrical contact to the wafers could then be adjusted by the velocity of the liquid flow.
Surface tensions may furthermore cause partially submerged wafers with dry top side to have an uplift relative to the holding devices while the same wafers with a wet top side will resist being lifted. Both mechanisms can be used to ensure a good electrical contact.
Moreover, it would be possible to provide several bus bars over the liquid, where the respective bus bars are having a different potential or voltage level in relation to the anode 36.
The electroplating process will now be described with reference to
Cathode Reaction: Mn++ne−→M(s) (1)
Anode reaction: M(s)→Mn++ne− (2)
Hence, the anode goes into solution into the electrolyte via an oxidation reaction while the same time metal ions are being reduced to solid metal at the cathode.
In the first embodiment, the holding devices are made of an insulating material e.g. PP, PVDF or PTFE or other suitable material. Inside the holding devices there are smaller pins of a conductive material e.g. stainless steel or titanium. Those pins are designed in such a way that they act as support to the wafer while at the same time providing an electrical contact to the side of the wafer facing downside towards the bottom of the vessel. The contacting devices could have the shape of needles, balls, rods, discs or any other geometrical dimension that enables a good contact interface and maintaining low mechanical impact on the wafer.
The contacting devices are via a conductive material such as copper connected to the negative terminal of a power supply (cathode). The positive terminal (anode) of the power supply is connected to a piece of metal that is submerged in the liquid vessel that contains the electrolyte. When switching on the power supply, there will be a circuit created where the wafer is the cathode (reaction 1).
In this way some relevant metals for solar cell manufacturing, including e.g. Ag, Cu, Sn and Ni, could be deposited in a cost efficient way from aqueous solutions commercially available. The wafer handling system can be designed in such a way that it would not be necessary to change to another transport system (no new holding device) for each metal that you want to deposit.
It should be mentioned that during the process, metal will deposit on the electrical contacts 20. The metal could be removed physically (for example by means of a brush) or chemically (for example by means of an acid), as previously known.
However, the present invention provides a novel way of improving this. The metal could be removed electrically for example by reversing the current direction or connecting the holding device to a bus bar with a suitable (opposite) potential, for example after the wafer has been removed from the holding device. The electrical contacts 20 would in this case be submerged into a suitable liquid (the same or a second liquid bath). The removal of the metal can then be integrated as part of the process, and consequently the non-productive time for the production equipment will be reduced.
Another embodiment of the invention would be to have a brush-like contacting arrangement 40 (shown in
In another embodiment of the invention, lights are providing situated either submerged in the liquid or above the wafers for enabling so called light induced plating.
The abovementioned detailed description is especially provided to illustrate and to describe embodiments of the invention. However, the description is by no means limiting the invention to the specific embodiments.
It would of course be possible to change the polarities of the power supply device 34, or to use a alternating current instead of a direct current power source.
In fact, in one application of the invention, it would be possible to use the above described configuration in a first liquid container, and thereafter use the reverse polarity in a second liquid container to remove metal remnants etc.
Number | Date | Country | Kind |
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0719805.4 | Oct 2007 | GB | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/NO2008/000359 | 10/9/2008 | WO | 00 | 8/11/2010 |
Number | Date | Country | |
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60960704 | Oct 2007 | US |