NL1004484C2 - PVIC module incorporating PV module with photo voltaic cells - Google Patents

Abstract

The conversion of the evoked capacity takes place under the influence of an external voltage. The module is a multi-terminal, multi-layer module, in which the absorption layers of the different superimposed layers of semiconductor transitions have different bandgaps. The different superimposed layers of semiconductor transitions are electrically insulated. The module has an interface coupled between the photosensitive cells and the output, such that the capacity converter is accommodated in the interface. The interface is arranged to permit the function of each separate layer of series-connected photo-voltaic cells in the maximum power point. The capacity converter is a DC/AC type.

Description

Title: PVIC module and PV module for use in a PVIC module

The invention relates to a PVIC module comprising a PV module with photovoltaic cells and a power converter for converting the power generated by the cells into an output power under the influence of an external voltage applied and provided with an output for supplying the external voltage and for delivering the generated power.

The invention also relates to a PV module.

A PV module is here understood to mean a module comprising semiconductor transitions connected in series for generating energy from sunlight using the photovoltaic effect.

A PVIC module is here understood to mean a PV module with an integrated converter for converting the power generated by the photovoltaic cells into an alternating voltage power suitable for supply to the public electricity grid, also referred to as an AC module or a DC voltage suitable for supply. to an appropriate storage facility.

Such an AC module is known from the article “feasiblity and development of PV modules with integrated inverter: AC modules” 12th European photovoltaic solar energy conference, 11-14 April 1994. It describes an AC module which photovoltaic cells and a DC / AC converter for converting the DC power into an AC power in the AC module 20 which can be directly supplied to, for example, the public electricity grid in, for example, a house.

A drawback of the known PV modules and AC modules is that the efficiency is relatively low, so that the costs, other than for the formation of semiconductor junctions, are relatively high.

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One of the objects of the invention is to obviate the above-mentioned drawbacks. For this purpose, a PVIC module according to the invention has the feature that the PV module is a multiterminal multilayer module in which the semiconductor junctions of different layers have a different band gap and the semiconductor junctions of the different layers are electrically insulated.

This achieves a much higher efficiency and therefore a much more cost-effective solution, which considerably increases the scope of application of such PVIC modules.

It should be noted here that it is known per se to manufacture multilayer PV modules, however, series-connected semiconductor junctions with little different band gap were used. As a result, the efficiency was not significantly improved compared to single-layer modules.

The invention is based, inter alia, on the insight that by giving the semiconductor transitions of the different layers a different band gap and by electrically insulating the semiconductor transitions of the different layers and including a power converter in the PVIC module, a much higher efficiency is obtained. which makes it possible to provide a PVIC module that is interesting from a technical and cost point of view.

An exemplary embodiment of a PVIC module according to the invention is characterized in that the PVIC module contains an interface coupled between the photovoltaic cells and the output, the power converter being included in the interface.

The interface controls the PVIC module as a whole and controls the conversion of input power to output power.

A further exemplary embodiment of a PVIC module according to the invention is characterized in that the interface is arranged for the functioning of each layer in the maximum power point.

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The maximum power point is the voltage found at the output of a layer in series-switched semiconductor transitions, whereby under the given (meteorological) conditions the greatest power can be extracted from these layer semiconductor transitions.

5 This results in a further improvement in yield. Because the different layers with semiconductor transitions are electrically separated, it is possible in the PVIC module according to the invention to operate each layer in the so-called maximum power point.

An exemplary embodiment of a PVIC module according to the invention is characterized in that of the different layers, the absorption layer of the first semiconductor transition achieved by the light is formed by Si, -xCx (0 <x <1) and the absorption layer of the as last semiconductor junction reached by light is Si, -xGex (0 <x <1).

This makes it possible to optimally distribute the available light spectrum over the different layers and thereby further increase the efficiency.

As indicated above, the invention also relates to a PV module for use in a PVIC module. It is possible to use such a PV module, for example, alone or with another PVIC module.

The PVIC module according to the invention will be explained in more detail below by way of example. Herein shows:

Figure 1 illustrative embodiments of known embodiments of semiconductor junctions for use in PVIC modules,

Figure 2 shows a schematic embodiment of a PVIC module according to the invention, 10 04 4 84 -4-

Figure 3 shows an exemplary embodiment of semiconductor junctions as used in a PVIC module according to the invention, and Figure 4 schematically shows an electrical embodiment of a part of a PVIC module according to the invention with a power converter.

Figure 1a shows a known structure of semiconductor junctions 3 for use in a PV module in which the semiconductor junctions are connected in series. The series-connected semiconductor transitions 3 are connected to each other by electrically conductive layers 1. As a whole, the semiconductor junctions and conductive layers are placed on a substrate 5. Finally, the semiconductor junctions 3 are electrically separated at the top by means of a non-conductive layer 7.

Figure 1b shows an electrical representation of n * series-connected semiconductor junctions for use in a known PV module.

Figure 2 shows a schematic embodiment of a PVIC module 20 according to the invention. The PVIC module in this example consists of a PV module 25 and an interface 27.

The PV module contains several layers of light voltaic cells 251 which generate a voltage under the influence of (sun) light 21. For the construction of the light voltaic cells, reference is made to figure 3 where the different semiconductor junctions are shown in more detail.

In this exemplary embodiment, the PV module is coupled to the interface for making the generated power suitable for delivery to, for instance, the electricity grid by means of an output 29. In this case it is then in any case necessary to convert the generated DC power. converting into an AC power by means of a power converter configured as a DC / AC converter 271. Such a PVIC module is therefore called an AC module.

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The interface also makes it possible to operate each layer of semiconductor transitions during operation in the so-called "maximum power point" (MPP). As a result, it is obtained that the PVIC module as a whole yields a much higher efficiency than hitherto known AC modules.

Figure 3a shows an exemplary embodiment of semiconductor junctions as applied in a PVIC module according to the invention and described schematically above with reference to Figure 2. In this exemplary embodiment, the photovoltaic cells consist of 4 layers, 100,200, 300 and 400, respectively. semiconductor junctions per layer and connected in series, respectively, while the semiconductor junctions are vertically separated electrically by non-conductive layers 137, 237, 337 and 437, respectively. The bottom layer, namely 400, is placed on a substrate 35. Figures 3b shows the associated electrical schematic representation.

Figure 4 schematically shows an electrical embodiment of a part of a PVIC module according to the invention with a power converter. For each layer 15, 100, 200, 300, and 400, respectively, a voltage Vml, ..., Vm4 is set such that the largest electrical power can be extracted (maximum power point) and output as a DC / AC converter via power converter. 271 is transferred to output 29.

The operation of the PVIC module according to the invention is as follows. One of the prerequisites for achieving the desired properties is that each layer of photovoltaic cells is electrically decoupled from both the (optional) parent and (optional) underlying layer (s). While the different layers should be optically linked as well as possible. Furthermore, preferably each subsequent layer of series-switched photovoltaic cells should have a lower band gap, making it possible to divide the available spectrum between the different layers, so that the PV module (and thus also the PVIC module) as a whole is much higher. returns. This also ensures that the PVIC module becomes more independent of meteorological variations in temperature, light intensity and 10 04 484-6 spectral composition, which of course also influences the efficiency of the PVIC module.

Because the layers with semiconductor transitions are electrically separated from each other, this yields 2 or more wires per layer, so that the number of wires also increases as the number of layers increases. It is therefore of great importance when using a multi-layer multi-terminal module to place the power converter as short as possible from the semiconductor junctions. This is achieved in the PVIC module according to the invention by coupling the interface to the PV module. This keeps energy losses to a minimum.

10 Furthermore, the interface ensures that each layer with semiconductor transitions operates in the so-called 'maximum power point', which further increases the efficiency of the PVIC module. The maximum power point is the voltage found at the output of a layer of semiconductor transitions connected in series, whereby under the given (meteorological) conditions the greatest power can be extracted from these layer of semiconductor transitions. Since the maximum power point of each layer also depends on the type of weather, temperature and light intensity, the interface must take this into account when optimizing.

It will be understood that a PVIC module can be adapted in a variety of ways without departing from the essence of the present invention. For example, the number of layers with semiconductor junctions can be selected depending on the specific application and required efficiencies, etc.

Furthermore, in an application of a multi-terminal multi-layer PV module, other forms of electrical converters can be used, for instance to make the generated power suitable for an appropriate electrical storage facility such as, for example, batteries.

1004484

Claims (6)

PVIC module comprising a PV module with photovoltaic cells and a power converter for converting the power generated in operation by the cells into an output power, under the influence of an externally applied voltage 5 and provided with an output for supplying the external voltage and for generating the generated power, characterized in that the module is a multiterminal multilayer module in which the absorption layers of different stacked layers of semiconductor junctions have different band gaps and the different stacked layers of semiconductor junctions of the different 10 layers are electrically insulated . PVIC module according to claim 1, characterized in that the module includes an interface coupled between the photosensitive cells and the output with the power converter included in the interface. PVIC module according to claim 2, characterized in that the interface is arranged for each individual layer of series-connected photovoltaic cells to function in the maximum power point. PVIC module according to any one of claims 1 to 3, characterized in that of the different layers, the absorption layer of the semiconductor junction first achieved by the light is formed by Si, .xCx (0 <x <1) and the absorption layer of the last semiconductor junction reached by the light is formed by Si.xGex (0 <x <1). PVIC module according to any one of claims 1 to 4, characterized in that the power converter is a DC / AC converter. PV module for use in a PVIC module according to any one of claims 25 1-4. 10 0 4 4 84