The present invention relates to a method and machine for producing semiconductor units, notably photovoltaic cells, as well as to a semiconductor unit obtained by such a method.
The constant and increasing time-dependent change in present energy needs is expressed by an intention and a search for new resources capable of protecting the environment. Solar energy is part of the preferential responses to this subject. Confronted with the rise in the prices of fossil energy, solar technology appears as a cost-effective and competitive industrial alternative. Therefore a goal of the manufacturers of photovoltaic cells and solar panels producing electric current is to reduce the costs for producing and setting up these devices. One of the essential constitutive elements of a photovoltaic cell is silicon, which is also used for manufacturing other electronic components. Now, silicon represents roughly one third of the price of the photovoltaic cell as manufactured presently. This is notably explained by the fact that in order to produce a photovoltaic cell, a thickness of about 400 to 450 μm of silicon is generally required. Indeed, in the conventional manufacturing process, a silicon ingot or bar is taken, generally with a size of 30 cm wide by 130 cm long, and wafers or discs of silicon are cut by means of a wire, the diameter of which is generally comprised between 160 and 200 μm.
The object of the present invention is notably to provide such a semiconductor unit which is less costly to manufacture.
The object of the present invention is also to provide such a semiconductor unit, requiring less silicon for its making.
The object of the present invention is also to provide a method and a machine of this type, with which a semiconductor unit may be made, for which the yield is greater than that obtained by conventional manufacturing methods.
The object of the present invention is also to provide a manufacturing method and machine which are safe and reliable, while limiting the risks of breakage.
The object of the present invention is also to provide a method and a machine for manufacturing semiconductor units, allowing the use of both polycrystalline silicon and of single-crystal silicon.
The object of the present invention is a method for manufacturing semiconductor units, including the steps of providing a silicon bar, of cutting at least one silicon wafer in the cross-section of said silicon bar, of assembling a substrate on either side of said silicon wafer, and of cutting in the thickness in the middle of said silicon wafer, in order to form two semiconductor units each including a substrate and a thin silicon layer.
Advantageously, the silicon bar has a circular or square section, preferably with a width of about 300 mm and a length from about 500 mm to 1,300 mm.
Advantageously, the step for cutting at least one silicon wafer is carried out by sawing by means of a wire, notably a steel wire with an abrasive lubricant.
Advantageously, the step for cutting in the middle of the silicon wafer is carried out by sawing by means of a wire, notably a steel wire with an abrasive lubricant.
Advantageously, said wire has a diameter comprised between 80 μm and 130 μm, advantageously between 100 μm and 120 μm.
Advantageously, said at least one silicon wafer has a thickness comprised between 180 μm and 280 μm advantageously between 200 μm and 250 μm, and the thin silicon layer of each semiconductor unit has a thickness comprised between 40 μm and 80 μm, advantageously between 50 μm and 60 μm.
Advantageously, said substrate is a metal or insulating substrate preferably with a thickness comprised between 100 μm and 300 μm.
Advantageously, the substrate is in metal, notably in an iron and nickel alloy with an expansion coefficient close to that of silicon.
Advantageously, said substrate is an electrical insulator with an expansion coefficient close to that of silicon.
Advantageously, the step for assembling a substrate on each side of said silicon wafer is carried out by adhesive bonding.
Advantageously, said adhesive bonding is carried out with a conducting adhesive, such as a conducting ink or a silver film.
Advantageously, the step for assembling a substrate on each side of said silicon wafer is carried out at low temperature and/or in vacuo and/or under pressure.
Advantageously, before the step for assembling a substrate, the method includes the step for cleaning each silicon wafer, notably by rinsing and drying.
Advantageously, before the step for assembling a substrate, the method includes the step for doping each silicon wafer notably with N or P doping, notably by immersion in a bath containing boron or phosphorus.
Advantageously, the step for cutting in the thickness in the middle of the silicon wafer is carried out by applying positive and/or negative pressure, notably by means of electromagnetic and/or pneumatic and/or mechanical forces, on the assembled substrates on each side of the wafer.
Advantageously, after the step for cutting in the middle of the wafer, the method comprises carrying out at least one surface treatment of the silicon surface of each semiconductor unit, as well as a structuration and/or anti-reflective treatment.
Advantageously, a doping step, notably a P doping step, is carried out on the silicon surface of each semiconductor unit, after the step for cutting in the middle of said silicon wafer.
Advantageously, the step for providing a silicon bar comprises the doping of said bar in the core, notably by N or P doping.
Advantageously, said silicon is single-crystal or polycrystalline silicon.
Advantageously, the method is a method for manufacturing a photovoltaic cell, further including the step for applying electric connections on each semiconductor unit.
Advantageously, said step for applying electric connections is carried out by notably applying by screen printing, notably with conducting inks, conducting microcircuits on the silicon surface.
Advantageously, said step for applying electric connections comprises the piercing of a network of micro-perforations, notably by micro-sanding, in the silicon layer and the substrate, and inserting into each perforation a conductor suitable for collecting the current at the surface of the silicon and transmitting it to the rear of the substrate.
Advantageously, each connection includes an electrically conducting element inserted into an insulating frusto-conical sleeve.
Advantageously, the semiconductor unit is positioned in a chassis including a front face closed by a glass wall protecting the silicon surface, and an insulating rear face provided with ventilation orifices.
The object of the present invention is also a manufacturing machine in order to apply the method above, comprising means for providing a silicon bar, means for cutting at least one silicon wafer in the cross-section of said silicon bar, means for assembling a substrate on each side of said silicon wafer, and means for cutting in the thickness in the middle of said silicon wafer, in order to form two semiconductor units each including a substrate and a thin slice of silicon.
The object of the present invention is also a semiconductor unit made with the above manufacturing method, including a substrate, preferably a metal substrate, on which a thin silicon layer is applied.
Advantageously, said thin silicon layer has a thickness from 40 μm to 80 μm, preferably from 50 μm to 60 μm.
Advantageously, said unit is a photovoltaic cell for which the yield is greater than 15%, advantageously greater than 8%, preferably greater than 20%.
These features and advantages as well as other ones of the present invention will become more clearly apparent during the following detailed description, made with reference to the appended drawings, given as non-limiting examples, and wherein:
a and 6b are top views of two alternative embodiments of the electric connections on the silicon surface of a photovoltaic cell, according to the present invention.
With reference to the figures, the method of the invention which will be described hereafter, as well as the manufacturing machine for applying this method, will mainly be described with reference to the manufacturing of a photovoltaic cell. However, it is understood that the present technology may also be applied to the manufacturing of other electronic components, such as diodes for example.
The method of the present invention consists of using a silicon bar or ingot, which may be of a standard size, with a section of about 300 mm×300 mm and a length from 500 mm to 1,300 mm. This bar may have a circular or square cross-section, or even a cross-section of a different shape. The method then provides the cutting out of the silicon wafers or chips or discs from said bar, in its cross-section, with preferably a thickness from about 200 μm to 250 μm. A substrate is then assembled on each side of each wafer and the wafer is then cut in its thickness, preferably in its center, in order to thereby form two semiconductor units each consisting of a substrate and of a thin silicon layer.
Notably referring to
Performing a cut in the thickness of the silicon causes breakage of the surface layer of the initial doping and therefore of the electric conductivity between the rear portion of the substrate and the front surface of the silicon left free.
The structuration of the front surface of the silicon is accomplished by a suitable method, and it is then preceded with the application of an anti-reflective layer by a suitable method.
The setting into place of the collector circuit by screen printing, or by any other suitable method is accomplished as well as of the electric connections.
It should be noted that the silicon bar is preferably doped in the core, notably by N and/or P doping, before it is cut into a wafer.
Advantageously, the cutting of the wafers, as well as the cutting out of two semiconductor units, is achieved by means of a wire, notably a steel wire, preferably with addition of an abrasive lubricant, for which the diameter is advantageously of about 100 μm to 120 μm. Depending on the uses, a diameter slightly greater or slightly smaller may also be contemplated, for example from 80 μm to 130 μm. Advantageously, each cut-out wafer has a thickness of about 200 to 250 μm. Here also, depending on the needs, a greater or smaller thickness may be provided, for example from 180 μm to 280 μm. Thus, with a thickness from 200 to 250 μm for each wafer, and a thickness of the wire of about 100 μm, after cutting, two semiconductor units are obtained at the center of each wafer, each having a substrate and a thin silicon layer for which the thickness will be from about 50 to 60 μm. The most favorable thickness is thereby obtained for optimum yield of a photovoltaic cell. Because a substrate is attached on each side of the wafer and firmly held by a suitable method, during the cutting step, there is very little risk of the thin silicon layer breaking during this cutting step. With the present invention, it is therefore possible to provide a safer and more reliable manufacturing method, and to produce a semiconductor unit having optimum dimensions and features, so as to be made as a photovoltaic cell.
The substrate is preferably made as a strip which may have a thickness comprised for example between 100 μm and 200 μm. Preferably this strip is in metal, notably in an iron and nickel alloy, having an expansion coefficient close to that of silicon, for example FeN42. Other materials, notably other metals, may be contemplated for the substrate. The assembling of the substrate on each side of the silicon wafer may be achieved by adhesive bonding, notably by using a conducting adhesive such as a conducting ink or a silver film. In this application, because of the conducting nature of the adhesive, the substrate may even be made in an insulating material. Preferably, the assembling of the substrate on the silicon wafer is carried out at low temperature and/or in vacuo and/or under pressure.
The cleaning step which is preferably carried out on the wafer before assembling the substrate may include rinsing and drying. Also, the surfacing indicated in
Advantageously, the step for cutting the wafer is carried out by applying a positive and/or negative pressure, symbolized by the two arrows in
The present invention therefore allows a significant reduction in the consumption of silicon, since instead of using on average about 450 μm of silicon thickness per cell, less than the half of this is used for obtaining two cells with a higher yield since having a thickness close to or equal to the optimization of 50 μm to 60 μm.
Consequently, the present invention by the savings which it generates, makes the use possible of single-crystal silicon, known to be more performing, but also more costly than polycrystalline silicon. However, by the saving of silicon obtained by means of the present invention, the overcost of the single crystal is widely compensated. In fact, the use of single-crystal silicon again gives the possibility of further improving the yield of the photovoltaic cell obtained by the present invention.
Another advantage relatively to the method of the prior art is that in the conventional system, it is necessary to chamfer the edges of each silicon disc or wafer in order to avoid short circuits between the positive and negative terminals of the electric circuit. Because of the cutting of the wafer in its thickness, in order to create two separate semiconducting units, with the present invention, it is possible to avoid this phase for cutting the peripheral edge of the wafer, this tends to reduce the manufacturing costs.
In order to produce a photovoltaic cell from the semiconducting unit obtained as described above, electric connections are applied. In the example of
In order to combat the rise in temperature of the cell, which is a penalty factor since the yield of the cell decreases with the rise of its temperature, ventilation is advantageously provided, either by air or by a heat transfer circuit. To do this, the chassis in which the photovoltaic cells are assembled, advantageously includes ventilation orifices provided on its rear face, as visible in
Alternatively, step 16 provides micro-piercing of the micro-perforations in order to achieve the so-called rear connections as indicated in steps 16 and 17. Steps 18 and 19 consist in finishing and checking before transferring the cell to assembling in a panel.
With this application, the present invention gives the possibility of providing photovoltaic cells, for which the yield is comprised between 15% and 20%, or even more, which places this product among the most performing, with a manufacturing cost clearly less as compared with present cells.
It should be noted that the invention was described with reference to silicon, but it is clear that other materials having equivalent properties may also be used.
Although the present invention was described with reference to a particular embodiment thereof, it is understood that various modifications may be contemplated for one skilled in the art without departing from the scope of the present invention as defined by the appended claims.
Number | Date | Country | Kind |
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0951946 | Mar 2009 | FR | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/FR2010/050541 | 3/25/2010 | WO | 00 | 2/1/2013 |