BE1025985B1 - CAPTURE OF POWER IN A SOLAR PANEL INSTALLATION - Google Patents

Abstract

Among other things, a device for capturing power in a solar panel installation with one or more solar panels and an inverter is described. The device further comprises i) an input terminal connectable to one of the poles of the solar panels; and ii) an output terminal connectable to one of the poles of the inverter; and iii) an energy storage means; and iv) a switching circuit configured to switch the device into a charging state. In the charging state, the energy storage means is connected between the input terminal and the output terminal so that, during use, the energy storage means is in series between the solar panels and the inverter and so that, during use, the generated current of the solar panels flows through both the energy storage means and the inverter.

Description

Technical Field The present invention relates to an apparatus for capturing power generated by a solar panel installation in an energy storage means, e.g. a battery.

State of the art [02] A solar panel installation comprises one or more solar panels that are connected to an inverter. In operation, solar panels typically behave as a power source where the power supplied depends on the amount of converted light. The inverter has the purpose of converting the power supplied by the solar panels and supplying a stable voltage to the output, i.e. a stable AC or DC voltage.

[03] However, the dependence on sunlight makes sure that a solar panel installation cannot provide continuous power. That is why more and more solar panel installations are equipped with an energy storage device, for example a battery, which stores power during peak times and delivers power during off-peak moments, for example at night. The battery can thereby be placed between the solar panels and the inverter, i.e. for the inverter, in the inverter or at the output of the inverter. However, since the inverter has a certain maximum power, it is more advantageous to place the battery in front of the inverter. In this way, the maximum power of the inverter can be limited by storing part of the power in the battery at peak times and thereby saving the inverter. At off-peak times, the battery then returns energy that is supplied to the grid by the inverter.

-2BE2018 / 5071 [04] Various solutions that provide energy storage between the solar panels and the inverter are already known. For example, WO2017 / 187408A1 describes a method in which a battery is connected in parallel with the solar panels so that part of the power supplied by the solar panels is stored in the battery while the other part of the power is converted by the inverter and delivered to the just. The switching is also done in such a way that an optimal power output is achieved by the solar panels.

[05] A disadvantage of the above solution and other known solutions is that during charging the voltage of the solar panels and the battery must be matched. Due to the fluctuating voltage of the solar panels, it is therefore usually necessary to provide for a DCDC conversion at the input of the battery. This therefore ensures a complex and expensive circuit.

Summary of the Invention It is an object of the present invention to solve the aforementioned drawback by providing a solution that allows power storage in a solar panel installation without the need for a voltage converter between the solar panels and the battery.

This object is achieved, according to a first aspect of the invention, by providing an apparatus for capturing power in a solar panel installation with one or more solar panels and an inverter. The device further comprises:

- an entrance terminal can be connected to one of the poles of the solar panels; and

- an output terminal connectable to one of the poles of the inverter; and

- an energy storage device; and

-3BE2018 / 5071

- a switching circuit configured to switch the device into a charging state; and wherein in the charging state the energy storage means is connected between the input terminal and the output terminal so that, during use, the energy storage means is in series between the solar panels and the inverter and so that, in use, the generated current from the solar panels through both the energy storage means and the inverter flows.

[08] Solar panels in a solar panel installation are typically in series to achieve a specific output voltage across the output poles, eg 48 Volts. The poles of the solar panels can therefore refer to a positive or negative pole over which this output voltage stands. Analogously, the inverter also has a positive and negative pole over which the voltage supplied by the solar panels is put. The poles of the inverter can therefore refer to this positive or negative pole. The device can be placed between the solar panels and the inverter. More specifically, the device is placed between one of the poles of the solar panels and one of the poles of the inverter, e.g. between the positive pole of the solar panels and the positive pole of the inverter or between the negative pole of the solar panels and the negative pole of the inverter.

[09] The device can further be brought into a charging state. In this state the charging means, e.g. a battery, will be charged by the solar panels. The charging means is further configured such that in this charging state the storage means are in series between the solar panels and the inverter. By serial is meant that for example the positive pole of the storage means is connected to the positive pole of the solar panels, the negative pole of the storage means is connected to the positive pole of the inverter and the negative poles of the solar panels and the inverter are switched on. linked together. In this way, the current generated by the solar panels will first flow through the storage means and then to the inverter before flowing back to the solar panels or vice versa.

-4BE2018 / 5071 [10] Because the storage medium is in series with the solar panels, no voltage transformation has to be done. The advantage is therefore that an inverter is saved by the above device. Furthermore, in the charging state, the energy storage means will cause a voltage drop depending on the power consumption. However, an inverter typically has a circuit that adjusts the internal impedance so that the solar panels operate at their ideal operating point. It is therefore a further advantage that the difference in impedance by the energy storage means will be compensated by the inverter. As a result, no complex feedback circuits are required between the inverter and the device. The device can therefore easily be installed in existing solar panel installations.

[11] Preferably, the device further comprises a power measuring means and control unit; wherein the power measurement means is configured to measure a power release and / or potential power release from the solar panels; and wherein the control unit is configured to switch the device to the charging state as long as the power output is above a certain power lower limit and the charge level of the energy storage means is below a certain charge value upper limit.

[12] In this way, the energy storage means is only charged when it is not sufficiently charged, i.e. it is below a maximum charge value, and when the solar panels generate sufficient power to charge the storage means. Furthermore, the charge value upper limit ensures that the energy storage means is only charged if necessary.

[13] Preferably, the power lower limit corresponds to the maximum power of the inverter.

[14] In this way, the inverter can be under-dimensioned while the solar panels can continue to function optimally by supplying their over-power to the energy storage device. In this way

BE2018 / 5071 further prevented the inverter from limiting the power of the solar panels.

[15] According to an embodiment, the device further comprises:

- a second entrance terminal can be connected to the other pole of the solar panels; and

- a second output terminal connectable to the other pole of the inverter;

and wherein the switching circuit is further configured to switch the device to a discharge state; and wherein in the discharge state the energy storage means is connected between the output terminal and the second output terminal, and the solar panels are disconnected from the inverter, so that during use the energy storage means is in parallel with the inverter and the energy storage means supplies a power to the inverter.

[16] Thus, in the discharge state, the energy storage means delivers stored power to the inverter. Furthermore, the solar panels are disconnected from the energy storage device and the inverter so that they cannot be damaged by the power storage device power supplied.

[17] Preferably, the control unit is configured to switch the device to the discharge state as long as the power output is below a certain power upper limit and the charging level of the energy storage means is above a certain charging value lower limit.

[18] In this way the storage medium is only discharged when it is sufficiently charged and when the solar panels do not provide enough energy, for example at night.

[19] More preferably, the power upper limit is smaller than the power lower limit.

BE2018 / 5071 [20] According to an embodiment, the switching circuit is further configured to switch the device to a bypass state. In the bypass state, the input terminal is connected to the output terminal so that during use the energy storage means is bypassed and the power of the solar panels is completely absorbed by the inverter.

[21] Preferably, the control unit is further configured to switch the device to the bypass state when it cannot be switched to the discharge state or the charge state.

[22] According to a second aspect, the invention relates to a method for capturing power in a solar panel installation with one or more solar panels and an inverter by means of an energy storage means; wherein the method comprises the following steps:

- measuring a power output from the solar panels and the charge level of the energy storage device; and

- determining when the measured power output is above a certain power lower limit and the measured charging level of the energy storage means is below a certain charging value upper limit; and

when so, the energy storage means switches into a charging state by connecting the energy storage means in series between one of the poles of the solar panels and the inverter so that generated power from the solar panels both charges the energy storage means and flows to the inverter.

[23] According to an embodiment, the method further comprises the following steps:

- determining when the measured power output is below a certain power upper limit and the charging level of the energy storage means is above a certain charging value lower limit; and

-7BE2018 / 5071

when so, switching the energy storage means into a discharge state by disconnecting the solar panels from the inverter and coupling the energy storage means in parallel with the inverter so that the energy storage means supplies a power to the inverter.

[24] According to an embodiment, the method further comprises the following steps:

- in other cases, placing the energy storage means in a bypass state by coupling the solar panels to the inverter and disconnecting the energy storage means from the solar panels and the inverter so that the energy storage means is bypassed and the power of the solar panels is completely absorbed by the inverter.

According to a third aspect, the invention relates to a computer program product comprising computer-executable instructions for performing the method of the second aspect if this program is executed on a computer.

According to a fourth aspect, the invention relates to a computer-readable storage means containing the computer program product according to the third aspect.

Brief Description of the Drawings [1] Figure 1A shows a solar panel installation with one or more solar panels, an inverter and a power capture device according to an embodiment of the present invention; and [28] Figure 1B shows the device of Figure 1A in a bypass state according to an embodiment of the present invention; and

BE2018 / 5071 [29] Figure 1C shows the device of Figure 1A in a charging state according to an embodiment of the present invention; and [30] Figure 1D shows the device of Figure 1A in a discharge state according to an embodiment of the present invention; and [31] Figure 2 shows the various states of the device of Figure 1 according to an embodiment of the present invention.

Description of Embodiments [32] Figure 1A illustrates a solar panel installation with one or more solar panels 100, an inverter 110 and a device 150 for temporarily storing power supplied by the solar panels 100. The one or more solar panels may consist of solar panels that are connected in series, be placed in parallel or in a combination of both to obtain a certain peak power. The specific configuration is of less importance for the operation of the present invention and is therefore further illustrated in this description with reference to part 100. A configuration of installed solar panels is characterized by a positive pole 101 and negative pole 102 over which the voltage is generated by the solar panels will be shown.

[33] Inverter 110 converts the power supplied from the solar panels into a stable output voltage, eg into a fixed DC or AC voltage which can then be connected to a voltage network 120. For the conversion itself, the inverter 110 includes a DC-DC or DC-AC converter to convert the unstable DC voltage of the panels to the stable output voltage. The inverter 110 may further comprise an MPPT module 113 which is responsible for monitoring the maximum power point of the solar panels 100. MPPT stands for "Maximum Power Point Tracking". The MPPT will adjust the load as seen at the input poles 111 and 112 of the inverter

BE2018 / 5071 that the solar panels 100 always deliver the maximum power. The inverter 110 has a positive input pole 111 and a negative input pole 112 which can be coupled to the respective positive 101 and negative pole 102 of the solar panels.

The device 150 according to an embodiment of the present invention is placed between the solar panels 100 and inverter 110. To this end, device 150 comprises: i) a first input terminal 151 which can be coupled to the positive pole 101 of the solar panels 100, ii) a second input terminal 152 which can be coupled to the negative pole 102 of the solar panels 100, iii) a first output terminal 153 which can be coupled to the positive input pole 111 of the inverter and iv) a second output terminal 154 which can be coupled to the negative input pole 112 of the inverter.

Apparatus 150 further comprises an energy storage means 155 such as e.g. a battery and / or capacitor. The storage means 155 also has a positive and negative pole through which energy can be stored or released. Device 150 further comprises a switching circuit consisting of switches 161 to 165. The switches connect the energy storage means 155 to the input and output terminals 151 to 154 in various ways depending on whether the switches are open or closed. The electrical connections in the device 150 are indicated by the full connecting lines. The switches are controlled by a control unit 156 as indicated by the dotted lines in device 150. The device 150 further comprises means for measuring the power output from the solar panels and the storage means. Different ways of measuring power are known. In device 150, this is illustrated by voltage meters 171 and 172 and by current meter 170. The meters are also read by control unit 156 which can take the power supplied by taking the product of voltage and current. If the solar panels are disconnected (see below), the potential power of the solar panels can be supplied

BE2018 / 5071 are determined on the basis of a voltage measurement with voltage meter 171 across the poles 101, 102 of the solar panels 100.

The device 150 can be brought into three states by the control unit 156 by switching the switches 160 to 165 to a certain position. A first state is the charging state and is illustrated in Figure 1C. In the charging state, switches 161, 162, 164 and 165 are closed and switches 160 and 163 are open. As a result, the positive pole 101 is connected via the input terminal 151 to the positive pole of the energy storage means 155 and the negative pole of the energy storage means is connected via the output terminal 153 to the positive pole 111 of the inverter 110. In other words, the energy storage means 155 is in series connected between the solar panels 100 and the inverter 110. By closing switch 165 and opening switch 163, the negative pole 102 of the solar panels is directly connected to the negative input pole 112 of the inverter via the input and output terminals 152, 154 110. Due to the series connection, during use the battery, which can be seen as a voltage source, will cause a voltage drop between the solar panels 100 and the inverter 110. Because the solar panels behave as a power source, the energy storage means will be charged with the current which is generated by the solar panels and save a power corresponding to the product of the generated current and the voltage across the battery 155. The remaining power will then be absorbed by the inverter 110 and is determined by the same generated current from the solar panels and the impedance of the inverter 110. If the inverter has an MPPT module 113 The impedance of the inverter will be adjusted in such a way that the solar panels provide maximum power. An advantage of the series connection in the discharge state is therefore that the battery 155 can be charged without the need for an additional DC-DC converter.

[37] A second state of the device is the discharge state and is illustrated in Figure 1D. In the discharge state, switches are 161, 160

BE2018 / 5071 and 163 are closed and switches 162, 164 and 165 are open. As a result, the solar panels 100 are disconnected from the inverter and the energy storage means 155, so that the solar panels 100 do not provide any power. The energy storage means is then connected with the positive pole to the positive pole 111 of the inverter 110 via output terminal 153 and is then connected with the negative pole 112 to the negative pole of the inverter 110 via output terminal 154. In other words, the energy storage means is in parallel to the inverter 110. Thus, in the discharge state, the energy storage means 155 will supply a power to the inverter 110 which in turn delivers it to the rear network 120.

A third state of the device 150 is the bypass state and is illustrated in Figure 1B. In the discharge state, switches 160, 164 and 165 are closed and switches 161, 162 and 163 are open. As a result, the energy storage means is disconnected from the solar panels 100 and the inverter 110 and therefore cannot absorb or supply power. In the bypass state, the solar panels 100 are coupled directly to the inverter 110, i.e., in a state as if device 150 were not there. The positive pole 101 of the solar panels is thus directly connected to the positive pole 111 of the inverter and the negative pole 102 of the solar panels 100 is thus connected to the negative pole 112 of the inverter 110. In the bypass state the power is generated in the solar panels thus fully delivered to the inverter 110.

Figure 2 illustrates how the control unit 156 decides when the device 150 is in the discharge state 203, the charging state 201 and the bypass state 202 according to an embodiment of the present invention. For this purpose, the control unit checks the charge level of the storage means and the power output or potential power output of the solar panels (100) at regular intervals.

[40] The control unit keeps the device 150 in the charging state 201 as long as the following conditions are met:

BE2018 / 5071 ⁽ 1 ⁾ P _PV > PMi _N ⁽ 2 ⁾ CH _bat <CH _MAX where:

- P _{pv is} equal to the power that can be supplied by the solar panels 100; and

- P _{MlN is} a power _{lower limit} for the power P _pv ; and

- CH _bat corresponds to the charge level of the energy storage device

155, the higher CH _BAT, the more the energy storage device is charged;

and

- CH _max corresponds to an upper limit for the charge level of the energy storage device.

[41] The first condition ensures that the energy storage means 155 only charges when the solar panels 100 deliver sufficient power. Preferably, P _MlN is chosen such that charging takes place only when the solar panels supply more power than the maximum power that the inverter can take up. This may be the case, for example, when the inverter 110 is under-dimensioned with respect to the peak power of the solar panels. Under-dimensioning can, for example, be done for financial or tax reasons. In this case, P _{M1 N} equal to or slightly smaller than the power of the inverter can be selected. In addition, control unit 156 may also be in communication with the inverter 110 or with another external control unit. Control unit 156 is then equipped to receive a signal that instructs to switch to the charging state. This signal can be given, for example, because there is a surplus of energy on the network 120. This can only happen if the second condition is met.

[42] The second condition determines that the energy storage means 155 can only be charged as long as the loading value of the storage means is below a certain upper limit CH _MAX . Preferably CH _{MAX is} chosen around

BE2018 / 5071 the maximum capacity of the storage medium, eg between 95% and 100% of the maximum capacity of the storage medium. This prevents the storage medium from being overloaded and, as a result, the storage medium from being damaged or the solar panel installation from underperforming.

[43] The control unit keeps the device 150 in the discharge state

203 as long as the following conditions are met:

⁽ 1 ⁾ Pp _V <P _MAX ⁽ 2 ⁾ CH _bat > CH _M in which:

- Pmax is a power upper limit for the power or the potential power P _pv supplied by the solar panels; and

- CHmin corresponds to a lower limit for the charge level of the energy storage device.

[44] Since the solar panels were disconnected during the discharge, they cannot provide power in the discharge state. The first condition ensures that the solar panels are only disconnected when the power supplied falls below a certain lower limit P _MAX . P _MAX is preferably taken as small as possible so that the total yield of the solar panel installation remains optimal. Because the control unit can determine the open terminal voltage of the solar panels 100 on the basis of the voltage meter 171, the control unit is configured to derive therefrom the potential power of the solar panels, that is, the power that the solar panels would supply should they be reconnected.

[45] The second condition ensures that the energy storage device only discharges as long as there is sufficient stored energy. Preferably, CH _{M is} taken as small as possible, e.g. between 0% and 5% of the total capacity of the energy storage means.

BE2018 / 5071 [46] If the above conditions of the discharge or charging state are not met, the control unit 156 switches the device 150 into the bypass state and maintains this state as long as the conditions are met.

[47] The device 150 places the energy storage means 150 in series via the positive poles of the solar panels and the inverter. However, the components of device 150 can also be rearranged so that the energy storage means is in series with the solar panels and the inverter along the negative pole of the solar panels and the inverter, respectively.

[48] Although the present invention has been illustrated with reference to specific embodiments, it will be apparent to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be practiced with various modifications and modifications without leaving the scope of the invention. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being described by the appended claims and not by the foregoing description, and all modifications falling within the meaning and scope of the claims, are therefore included here. In other words, it is assumed that this covers all changes, variations or equivalents that fall within the scope of the underlying basic principles and whose essential attributes are claimed in this patent application. In addition, the reader of this patent application will understand that the words comprising or including other elements or steps do not exclude, that the word excludes a plural, and that a single element, such as a computer system, a processor or other integrated unit, functions different can fulfill the aids mentioned in the claims. Any references in the claims may not be construed as limiting the claims in

BE2018 / 5071 issue. The terms first, second, third, a, b

c and the like, when used in the description or in the claims, are used to distinguish between similar elements or steps and do not necessarily describe a sequential or chronological order. Similarly, the terms top, bottom, over, under and the like are used for the purposes of the description and do not necessarily refer to relative positions. It is to be understood that those terms are interchangeable under proper conditions and that embodiments of the invention are capable of functioning according to the present invention in sequences or orientations other than those described or illustrated in the above.

Claims (13)

An apparatus (150) for capturing power in a solar panel installation with one or more solar panels (100) and an inverter (110); the device comprising: - an entry terminal (151) connectable to one of the poles (101) of the solar panels; and - an output terminal (153) connectable to one of the poles (111) of the inverter; and - an energy storage means (155); and - a switching circuit (161-163) configured to switch the device into a charging state (201); and wherein in the charging state the energy storage means (155) is connected between the input terminal (151) and the output terminal (153) so that, during use, the energy storage means is in series between the solar panels and the inverter and so that the generated power of the solar panels is transmitted through the energy storage device when the inverter flows. The device (150) of claim 1 further comprising a power measurement means (170, 171 172) and control unit (156); wherein the power measurement means is configured to measure a power output from the solar panels (100); and wherein the control unit is configured to switch the device to the charging state (201) as long as the power output is above a certain power lower limit and the charging level of the energy storage means is below a certain charging value upper limit. The device (150) of claim 2 wherein the power lower limit corresponds to the maximum power of the inverter. The device (150) according to any of the preceding claims, further comprising: BE2018 / 5071 - a second input terminal (152) connectable to the other pole (102) of the solar panels (100); and - a second output terminal (154) connectable to the remaining pole (112) of the inverter (110); and wherein the switching circuit is further configured to switch the device to a discharge state (203); and wherein in the discharge state the energy storage means (155) is connected between the output terminal (153) and the second output terminal (154), and the solar panels are disconnected from the inverter, so that during use the energy storage means (155) in parallel with the inverter (110 ) and the energy storage means supplies power to the inverter. The device (150) of claims 4 and 2 wherein the control unit (156) is configured to switch the device to the discharge state as long as the power delivery or a potential power delivery is below a certain power upper limit and the charge level of the energy storage means is above a certain load value lower limit. The device (150) of claim 5 wherein the power upper limit is smaller than the power lower limit. The device (150) according to any of the preceding claims, wherein the switching circuit is further configured to switch the device to a bypass state (202); and wherein in the bypass state the input terminal (151) is connected to the output terminal (153) so that during use the energy storage means (155) is bypassed and the power of the solar panels (100) is completely absorbed by the inverter (110). The device (150) of claims 4 and 7 wherein the control unit (156) is configured to switch the device to the bypass state (202) when it cannot be switched to the discharge state (203) or the charge state (201) turn into. - 18BE2018 / 5071 A method for capturing power in a solar panel installation with one or more solar panels (100) and an inverter (110) by means of an energy storage means (155); wherein the method comprises the following steps: - measuring a power output of the solar panels (100) and the charge level of the energy storage means (155); and - determining when the measured power output is above a certain power lower limit and the measured charging level of the energy storage means is below a certain charging value upper limit; and - if so, switch the energy storage means into a charging state (201) by connecting the energy storage means (155) in series between one of the poles of the solar panels (101, 102) and the inverter (111, 112) so that generated power from the solar panels both charges the energy storage device and flows to the inverter. The method of claim 9 further comprising the following steps: - determining when the measured power output is below a certain power upper limit and the charging level of the energy storage means (155) is above a certain charging lower value limit; and - if so, to switch the energy storage means to a discharge state (203) by disconnecting the solar panels (100) from the inverter (110) and coupling the energy storage means (155) in parallel to the inverter so that the energy storage means supplies a power to the inverter supplies. The method of claim 10 further comprising the following steps: - in other cases, placing the energy storage means in a bypass state (202) by coupling the solar panels (100) to the inverter (110) and disconnecting the energy storage means (155) from the solar panels and the inverter so that the energy storage means becomes - 19BE2018 / 5071 bypasses and the power of the solar panels is completely absorbed by the inverter. 12. A computer program product comprising on a computer 5 executable instructions to perform the method according to any of claims 9 to 11 if this program is executed on a computer. A computer-readable storage means comprising the computer program product of claim 12.