POWER SUPPLY SYSTEM

Abstract

A power supply system including a stack of fuel cells, a device for regulating the voltage at the poles of the stack which includes a resistive load connected between the poles of the stack for generating a voltage drop between them and a controlled switch inserted in series with the resistive load, which can be actuated between an open configuration and a closed configuration.

Claims

1. A power supply system comprising an electricity generating system comprising a stack of fuel cells comprising a plurality of fuel cells and having a positive pole and a negative pole a device for regulating the voltage between said positive pole and said negative pole, said power supply system being characterised in that said regulating device comprising at least one resistive load connected to said positive pole and negative pole to generate a voltage drop between said positive pole and negative pole; at least one controlled switch inserted in series with said resistive load between said positive pole and negative pole and which can be actuated between an open configuration and a closed configuration; a control device in communication with the controlled switch and comprising a comparator for calculating a voltage error as the difference between a voltage value measured between said positive pole and said negative pole at the terminals of the stack and a predetermined maximum voltage value, said control device being configured for actuating said controlled switch between said open configuration and said closed configuration and vice versa as a function of said voltage error.

2. The power supply system according to claim 1, wherein said predetermined maximum voltage value is a function of the number of fuel cells which make up said stack.

3. The power supply system according to claim 1, wherein said predetermined maximum voltage value is a function of the number of elements of a battery pack rechargeable by means of said power supply system.

4. The power supply system according to claim 1, wherein said comparator comprises a voltage sensor.

5. The power supply system according to claim 1, wherein said comparator comprises a current sensor.

6. The power supply system according to claim 1, wherein said control device comprises a computerised command and control unit in communication with said comparator and configured for generating a control signal as a function of said voltage error and actuating said controlled switch by means of said control signal.

7. The power supply system according to claim 1, wherein said controlled switch is defined by a voltage controlled relay in communication with said comparator, said relay being actuated, between the respective open and closed configurations, by said voltage error.

8. A technical system comprising a power supply system according to claim 1, a battery pack comprising a plurality of individual elements powered by the stack of fuel cells, an electrical load also powered by the stack of fuel cells and/or by the battery pack, said electrical load and said battery pack being connected to said stack of fuel cells in parallel with a series comprising said resistive load and said controlled switch.

9. The technical system according to claim 8, wherein said predetermined maximum value corresponds to a maximum voltage value permitted by the battery packer.

10. The technical system according to claim 8, wherein said computerised command and control unit is configured to generate said control signal as a function of the number of individual elements of the battery pack.

11. The technical system according to claim 8, wherein said computerised command and control unit is configured to generate said control signal as a function of the number of fuel cells of the stack of fuel cells.

12. The technical system according to claim 8, wherein said electrical load comprises a working load powered by said stack of fuel cells.

13. The technical system according to claim 8, wherein said electrical load comprises an auxiliary component in communication with the stack of fuel cells for the operation of the stack of fuel cells.

14. The technical system according to claim 8, wherein said battery pack is a lithium battery pack.

15. A method for controlling a technical system according to any claim 8, comprising the steps of: measuring the voltage value between the positive pole and the negative pole of the stack of fuel cells; calculating the voltage error between the voltage value measured between the positive pole and the negative pole of the stack of fuel cells and the predetermined maximum voltage value corresponding preferably to the maximum permissible voltage value of the battery pack; actuating said controlled switch to move it to the dosed configuration if said voltage error is positive.

16. The control method according to claim 15, comprising the following steps: actuating said controlled switch to move it to the open configuration if said voltage error is negative.

17. A method for recharging a battery pack from a stack of fuel cells, said recharging method comprising a step of directly powering the battery pack from the stack of fuel cells and a step of regulating the voltage of the positive pole the negative pole of the stack of fuel cells, said regulating step being performed exclusively by means of a regulating device comprising at least one resistive load connected to said positive pole and negative pole for generating a voltage drop between said positive pole and negative pole and at least one controlled switch inserted in series with said resistive load between said positive pole and negative pole and which can be actuated between and open configuration and a dosed configuration; said recharging method comprising a step of controlling the controlled switch as a function of a voltage error calculated as the difference between a voltage value measured between said positive pole and said negative pole at the terminals of the stack of fuel cells and a predetermined maximum voltage value.

Description

BRIEF DESCRIPTION OF DRAWINGS

[0032] Further features and advantages of this invention are more apparent in the following non-limiting description of a preferred but non-exclusive embodiment of a power supply, in which:

[0033] FIG. 1 illustrates a block diagram of a technical system of a first embodiment of a power supply system according to the invention;

[0034] FIG. 2 illustrates a block diagram of a technical system of a second embodiment of a power supply system according to the invention;

[0035] FIG. 3 illustrates an example of a polarization curve of a fuel cell.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS OF THE INVENTION

[0036] With particular reference to FIGS. 1 and 2, the numeral 100 denotes a technical system according to the invention.

[0037] The technical system 100 comprises a battery pack, schematically illustrated with a block 101 and an electrical load, schematically illustrated with a block 102, powered by the battery pack 101.

[0038] The battery pack 101 comprises a plurality of individual rechargeable and suitably connected basic elements of substantially known type, not illustrated; the battery pack 101 has a positive pole 101a and a negative pole 101b.

[0039] The number of elements inside the lithium battery pack 101 provides the maximum voltage applicable to the battery pack for example during charging or recharging of the battery pack.

[0040] Preferably, the individual basic elements and, therefore, also the battery pack, are of the lithium ions type.

[0041] The system 100 comprises a power supply system, generically labelled 1, for powering, that is, charging the battery pack 101 and/or for powering the electrical load 102.

[0042] The electrical load 102 is therefore preferably powered by the battery pack 101 and/or by the power supply system 1.

[0043] The supply system 1 comprises an electricity generating system comprising a stack of fuel cells, of substantially known type and schematically illustrated with a block 2, having a positive pole 2a and a negative pole 2b, also referred to as “terminals” of the stack, and forming a plurality of fuel cells not illustrated.

[0044] Schematically, the stack 2 allows a direct combination of hydrogen and oxygen which, flowing inside suitable flow channels, combine in such a way as to generate water vapour and a flow of electrons which determine a voltage V at the terminals of the stack, that is, between the positive pole 2a and the negative pole 2b.

[0045] The electricity generating system also comprises auxiliary components, schematically illustrated with a block 3, in communication with the stack 2 of fuel cells for the operation of the stack 2.

[0046] These auxiliary components constitute the so-called BOP (Balance of plant) of the stack 2 to which reference is made hereinafter.

[0047] The BOP of the stack 2 is substantially known and formed by the further devices necessary for the correct automatic operation of the fuel cells. The BOP, which absorbs a certain quantity of current generally supplied by the stack 2, that is, it is preferably powered by the stack itself, comprises, for example, a ventilation system for pumping air inside the stack 2 and a series of solenoid valves for the hydrogen and for a system for cooling fuel cells of the stack 2.

[0048] The electrical load 102 comprises both the BOP 3 and a working load, schematically illustrated with a block 103, which may be powered by the stack 2 and/or by the battery pack 101.

[0049] The type of working load depends on the type of technical system.

[0050] In a automotive application, the working load 103 may be, for example, defined by a motor for automotive transport.

[0051] In a preferred application according to the invention, the working load is defined by the traction system of a lift truck and by at least part of the relative actuators.

[0052] The supply system 1 comprises a device for regulating the voltage between the positive pole 2a and the negative pole 2b of the stack 2, generally labelled 4.

[0053] In other words, the regulating device 4 regulates, in practice, the voltage at the poles of the battery pack 101.

[0054] The regulating device 4 comprises a resistive load, schematically illustrated with a block 5, connected to the positive pole 2a and to the negative pole 2b of the stack 2 for generating a voltage drop between them.

[0055] The resistive load 5 comprises at least one electrical dissipating resistance designed to absorb and dissipate electric current.

[0056] The resistive load and/or the above-mentioned resistance is preferably sized according to the number of individual basic elements of the battery pack and/or the number of fuel cells constituting the stack 2.

[0057] With reference to the polarization curve of a fuel cell illustrated for example in FIG. 3, in which, as known, the X-axis shows the current density (mA/cm.sup.2) and the Y-axis shows the cell voltage (V), it should be noted that the application of a resistive load at the terminals of the cell, calling a current, causes a voltage drop at the terminals of the cell.

[0058] The regulating device 4 comprises at least one controlled switch, schematically represented as a block 6, inserted in series with the resistive load 5, which can be operated between an open configuration and a dosed configuration.

[0059] The resistive load 5 and the controlled switch 6 form a series defining a branch of the regulating device 4 positioned between the positive pole 2a and the negative pole 2b of the stack 2 and which is able to switch between the open configuration, at which the resistive load 5 is not powered by the stack 2, and the closed configuration, at which the resistive load 5 is powered by the stack 2 and, in practice, causes a drop in potential at the terminals.

[0060] The technical system 100 therefore comprises, schematically, the power supply system 1, the battery pack 101, comprising a plurality of individual elements powered by the stack 2, and an electrical load 102, also powered by the stack 2, wherein the electrical load 102 and the battery pack 101 are connected to the stack 2 in parallel with a series comprising the resistive load 5 and the controlled switch 6.

[0061] Preferably, the controlled switch 6 is powered by the battery pack 101.

[0062] The regulating device 4 comprises a control device 7, in communication with the controlled switch 6 and with the positive and negative poles 2a, 2b of the stack 2. The control device 7 comprises a comparator, schematically illustrated as a block 8, for calculating a voltage error ΔV as the difference between the voltage value V measured between the positive pole 2a and the negative pole 2b at the poles of the stack 2 and a predetermined maximum voltage value V.sub.max.

[0063] The predetermined maximum voltage V.sub.max is preferably a function of the number of fuel cells which make up the stack 2.

[0064] Considering the technical system 100, in accordance with an aspect of the invention, the predetermined maximum voltage value V.sub.max is preferably a function of the number of individual basic elements of the battery pack 101, that is, of the maximum voltage applicable to the battery pack 101 during the charging or recharging of the battery pack.

[0065] According to a preferred embodiment, the predetermined maximum voltage value V.sub.max corresponds to the maximum voltage value applicable to the battery pack 101 during charging or recharging of the battery pack.

[0066] The control device 7 is configured for actuating the controlled switch 6 between the open configuration and the closed configuration and vice versa as a function of the voltage error ΔV calculated by the comparator 8.

[0067] According to an embodiment, the comparator 8 may comprise a voltage sensor.

[0068] According to an embodiment, the comparator 8 may comprise a current sensor in combination with or as an alternative to a voltage sensor.

[0069] According to the invention, the regulating device 4 basically comprises the resistive load 5 connected to the positive pole 2a and to the negative pole 2b for generating a voltage drop between them, by the controlled switch 6 inserted in series with the resistive load 5, by the device 7 for controlling the controlled switch 6.

[0070] With reference to FIG. 1, according to the embodiment illustrated by way of example, the controlled switch 6 is preferably defined by a voltage controlled relay.

[0071] The relay 6 in communication with the comparator 8 and is actuated, between the respective open and closed configurations, directly by the voltage error ΔV which is, precisely, an analogue voltage signal.

[0072] With reference to FIG. 2, according to the embodiment illustrated by way of example, the control device 7 comprises a computerised command and control unit, schematically represented as a block 9, in communication with the comparator 8 to receive the voltage error ΔV as input.

[0073] The computerised unit 9 is configured for generating a digital control signal S, as a function of the voltage error ΔV, and actuating the controlled switch 6 by means of the signal S.

[0074] Advantageously, the regulating device 4 may comprise a plurality of voltage sensors in communication with the computerised unit 9 for determining the signal S for activating the controlled switch 6.

[0075] According to this embodiment, the controlled switch 6 may be a digitally controlled switch.

[0076] Preferably, the computerised unit 9 is configured for generating the control signal S as a function of the number of individual elements of the battery pack 101.

[0077] Preferably, the computerised unit 9 is configured for generating the control signal S as a function of the number of fuel cells of the stack 2.

[0078] A preferred application of a technical system 100 as described is in lift trucks.

[0079] A lift truck of substantially known type generally comprises a technical system 100 as described.

[0080] In fact, the lift truck generally comprises an electrical traction system and a plurality of electric actuators.

[0081] The electrical traction system and the electric actuators define the working load of the technical system 100.

[0082] The lift truck comprises a battery pack which corresponds to the battery pack 101 of the technical system 100.

[0083] The lift truck comprises a stack of fuel cells, corresponding to the stack 2, and the respective BOP, corresponding to the auxiliary components 3.

[0084] The BOP of the lift truck, the traction system and the actuators therefore define the electrical load for the stack and the battery pack of the lift truck.

[0085] A method for controlling the technical system 100, aimed, for example, at powering the electrical load 102 and maintaining the charge of the battery pack 101, comprising the steps of: [0086] measuring the voltage value V between the positive pole 2a and the negative pole 2b of the stack 2 of fuel cells; [0087] calculating the voltage error ΔV between the voltage value V measured and the predetermined maximum voltage Vmax value corresponding preferably to the maximum permissible voltage value of the battery pack 101; [0088] actuating the controlled switch 6 to move it to the closed configuration if the voltage error ΔV is positive; [0089] actuating the controlled switch 6 to move it to the open configuration if the voltage error ΔV is negative.

[0090] The output voltage from the stack 2 is supplied directly at the input to the battery pack 101 suitably modulated by the resistor 5.

[0091] The operation of the power supply system 1 can therefore be summarised with reference also to the polarization curve of FIG. 3. At the moment of a setting up of the system for generating electricity, comprising the stack 2 and the auxiliary components 3, during a transient step, until the working load 103 is active and the consumption of the BOP 3 is at a minimum value sufficient for activating the stack 2, the output voltage V of the fuel cell, measured by the comparator 8, will be the maximum possible and dose to the open circuit voltage value of the stack 2, typically, a volt per cell of the stack, that is, significantly greater than Vmax.

[0092] In these conditions, the comparator 8 measures, for example on the basis of an algorithm, a positive voltage error ΔV between the output voltage of the stack 2 and the predetermined maximum value Vmax, for simplicity corresponding to the maximum value Vmax permitted by the battery pack 102.

[0093] The comparator 8 sends this information to the control device 7 which requires a closing of the controlled switch 6 thus diverting a flow of current on the resistive load 5.

[0094] The regulating device 4 therefore allows the instantaneous absorption of a predetermined quantity of current which will have, as a result, an immediate reduction of the voltage V at the terminals of the stack 2 and therefore at the terminals of the battery pack 101.

[0095] The battery pack 101 is recharged directly, by transfer, from the stack 2 without the interposition of other connecting devices or electronic circuits, nor converters or battery chargers.

[0096] With reference to the prior art described in the above-mentioned patent document US2016159492A1, the solution according to the invention makes the battery charger 29 and the contactors 40 and 36 unnecessary and not even the diode fundamental for the system described.

[0097] As soon as the current starts to increase the working load 103 and whilst the BOP 3 moves to steady state, there is a further reduction in the voltage at the terminals of the stack 2 which may be again measured by the comparator 8.

[0098] As soon as the total electrical load 102 is such as to reduce the voltage V at the terminals of the stack 2 below the maximum value Vmax acceptable by the lithium battery 2, the control device 7 disconnects the resistive load 5 using the controlled switch 6.

[0099] As illustrated in FIGS. 1 and 2, the controlled switch 6 may be activated directly by the comparator 8 or by means of a computerised unit 9.

[0100] The power supply system 1 has important advantages.

[0101] The absence of active switching components avoids the generation of any electromagnetic noise, gives the system high efficiency and significantly reduces the costs.

[0102] The regulating device intervenes, in practice, only during the switching on transient and in those rare cases in which the working load tends to move towards zero.

[0103] These events are, in effect, marginal in almost all of the applications and in particular in the applications of lift trucks. On the other hand, the current systems are always active between the stack and the battery pack, adversely affecting efficiency continuously.

[0104] Cooling the additional resistive load is much easier or even unnecessary.

[0105] The power supply system as described above may be used to power any battery pack formed by an arbitrary and desired number of individual elements.

[0106] A suitable choice of the resistive load and of the comparator allows any combination between the number of fuel cells of the stack and the number of elements of the battery pack.

[0107] The cost of the regulating device is reduced to practically only the cost of the resistive load, of the relative command and of the voltage comparator as no other device is necessary.

[0108] The current which must be managed by the controlled switch is only a small fraction of the nominal current of the stack.

[0109] Another advantage is the simplification of the components which are not dimensioned over the entire plant but simply on the starting transient.

[0110] Moreover, since only some components are actually necessary with respect to or tens or hundreds constituting a DC/DC power converter or other devices such as a battery charger, the saving in terms of volume and weight is also evident.

[0111] The above-mentioned advantages are similarly achieved during operation with any type of battery.