WORK MACHINE

Abstract

The present invention relates to a work machine having a fuel cell drive comprising a fuel cell and determination means for determining the load demand of the fuel cell, wherein the work machine has a plurality of electrical consumers that are directly or indirectly connected to the fuel cell for the purpose of obtaining electrical energy, wherein the determination means are configured such that the power requirements of at least two of the electrical consumers enter into the determination of the load demand of the fuel cell.

Claims

1. A work machine having a fuel cell drive comprising a fuel cell and determination means for determining the load demand of the fuel cell, wherein the work machine has a plurality of electrical consumers directly or indirectly connected to the fuel cell for the purpose of obtaining electrical energy, and the determination means are configured such that the power requirements of at least two of the electrical consumers enter into the determination of the load demand of the fuel cell.

2. A work machine in accordance with claim 1, wherein first detection means are present that are configured to detect one or more pieces of machine data that have an influence on the fuel cell and/or on a battery electrically connected to the fuel cell; and the determination means are configured to allow the machine data to enter into the load demand of the fuel cell.

3. A work machine in accordance with claim 2, wherein the machine data have an influence on the service life, aging, degree of efficiency, or on the efficiency of the fuel cell and/or of the battery.

4. A work machine in accordance with claim 1, wherein filter means are present that are configured to filter the power demand of the at least two electrical consumers over time.

5. A work machine in accordance with claim 1, wherein second detection means are provided that are configured to detect previous data of the work machine; and the determination means are configured to allow the historical data to enter into the load demand of the fuel cell.

6. A work machine in accordance with claim 5, wherein the historical data comprise the past power requirements of the work machine or the historical power requirements of one or more consumers of the work machine.

7. A work machine in accordance with claim 5, wherein the second detection means are configured to prepare forecast data from the historical data; and the determination means are configured to allow the forecast data to enter into the determination of the load demand of the fuel cell.

8. A work machine in accordance with claim 1, wherein characterized in that the determination means are configured to process these supplied data in a cascade-like manner.

9. A work machine in accordance with claim 1, wherein at least two of the consumers are main drives of the work machine; and/or the consumer or consumers are individual consumers that are not main drives of the work machine.

10. A work machine in accordance with claim 1, wherein a vehicle control unit is present that has one or more of the aforesaid components, is outsourced, and is independent of standalone component control units of the fuel cell and/or of the battery and/or of the fuel cell system and/or of the voltage boost converter (DC-DC converter).

11. A method of determining the load demand of a fuel cell of a work machine, wherein the work machine has a plurality of electrical consumers that are directly or indirectly connected to the fuel cell for the purpose of obtaining electrical energy, and the power requirements of at least two of the electrical consumers enter into the determination of the load demand of the fuel cell.

12. A method in accordance with claim 11, wherein machine data that have an influence on the fuel cell and/or on a battery electrically connected to the fuel cell enter into the determination of the load demand.

13. A method in accordance with claim 11, wherein the determination of the load demand takes place by a cascade-like processing of data having an influence on the load demand.

14. A work machine in accordance with claim 3, wherein filter means are present that are configured to filter the power demand of the at least two electrical consumers over time.

15. A work machine in accordance with claim 2, wherein filter means are present that are configured to filter the power demand of the at least two electrical consumers over time.

16. A work machine in accordance with claim 15, wherein second detection means are provided that are configured to detect previous data of the work machine; and the determination means are configured to allow the historical data to enter into the load demand of the fuel cell.

17. A work machine in accordance with claim 14, wherein second detection means are provided that are configured to detect previous data of the work machine; and the determination means are configured to allow the historical data to enter into the load demand of the fuel cell.

18. A work machine in accordance with claim 4, wherein second detection means are provided that are configured to detect previous data of the work machine; and the determination means are configured to allow the historical data to enter into the load demand of the fuel cell.

19. A work machine in accordance with claim 3, wherein second detection means are provided that are configured to detect previous data of the work machine; and the determination means are configured to allow the historical data to enter into the load demand of the fuel cell.

20. A work machine in accordance with claim 2, wherein second detection means are provided that are configured to detect previous data of the work machine; and the determination means are configured to allow the historical data to enter into the load demand of the fuel cell.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0038] Further details and advantages of the invention will be explained in more detail with reference to an embodiment shown in the drawing.

[0039] The only FIGURE shows a schematic view of the control for determining the load demand of a fuel cell, not shown in the FIGURE, of a work machine.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0040] The work machine can, for example, be a wheeled loader or telescopic loader, an excavator having wheeled and crawler chassis, articulated joint dump trucks, and earthmovers and crawler mounted loaders, or any other earth-moving machine or construction machine.

[0041] The work machine is preferably a mobile work machine.

[0042] The determination of the load demand L of the fuel cell takes place in the determination unit B.

[0043] The power demand of all of the load consumers (component 1: K1, component 2: K2, component n: K) is determined in the first part of the control and a total power request 10 is calculated for the fuel cell with reference to the operating strategy. Influence is taken on the dynamics of the load request using the time filtering 20.

[0044] As can further be seen from the FIGURE, the tapping of main machine parameters such as the charge state of the battery and its change takes place in parallel therewith. Reference numeral 30 marks the state variables of the battery. To operate the battery in the permitted limits, a regulator 40 determines an additional power request for compensation that is added on the calculation of the power or load requirement L of the fuel cell, as can be seen from the FIGURE.

[0045] The value compensated in this manner is marked by W in the FIGURE. The value W is supplied to the determination means B.

[0046] The second part of the control influences the operating strategy. For this purpose, various machine and component data 50 that provide information on aging processes of the fuel cell and the battery are read or measured by means of the first detection means.

[0047] Reference numeral 60 marks the degree of efficiency or the efficiency of the total system of fuel cell and battery.

[0048] 70 marks the service life or aging of the total system of fuel cell and battery. As can be seen from the FIGURE, these values are combined and form a first part W1 of the correction 100 of the value W that is supplied to the determination means B and that is formed on the basis of the blocks 20, 40.

[0049] Depending on the operating strategy selected, a demand value is then determined for the power that is corrected with respect to the total load requirement L of the fuel cell. The correction value is marked by W1 in the FIGURE.

[0050] The vehicle use or its conditions of use are taken into account in the third part. It is possible to recognize recurring work patterns using historical data of the machine such as using the previous power demand of the work machine 80 that have been recorded by means of the second determination means over a defined period of time. The operating strategy can be influenced and the fuel cell power can be adapted to the required power requirements at an early point due to a corresponding prediction of work patterns (cf. reference numeral 90: prediction of the power requirements of the work machine).

[0051] As soon as work patterns have been recognized and predicted, the load requirement of the fuel cell can be adapted by a further correction in the third part of the control. The correction value is marked by W2.

[0052] Both correction values W1 and W2 are combined in the correction unit 100 and a final correction value W3 that is supplied to the determination means B is determined on the basis thereof.

[0053] A correction of the value W takes place by means of the correction value W3 in the calculation means B. On the basis of these two values (W and W3), the determination means B then ultimately determine the load requirement L at which the fuel cell is actually operated.

[0054] The aforesaid chronological listing of the individual control blocks is not mandatory. Every other sequence of said steps is also covered by the invention.

[0055] Advantages of a preferred embodiment are shown in the following:

[0056] The invention preferably relates to a method of determining the power request for the operation of a fuel cell drive in a vehicle, wherein the vehicle has a plurality of electrical main drives whose individual power requirements are determined and used to determine total vehicle power requirements in a vehicle control.

[0057] It is preferably a vehicle having a plurality of electrical main drives, wherein the vehicle is a mobile work machine.

[0058] The determination of the total vehicle power requirements preferably takes place from the data of the individual drives with a corresponding time filtering.

[0059] Battery state variables such as the charge state and its change are used in the correction of the power requirement.

[0060] The efficiency chain of the components of the fuel cell electric drive, preferably of the battery, of the fuel cell, and of the DC current converter, is taken into account to correct the power request.

[0061] The aging of the components of the fuel cell electric drive, preferably of the battery and of the fuel cell, is furthermore taken into account to correct the power request.

[0062] An optimization and refining of the fuel cell power request takes place by utilizing a load prediction process that evaluates the operating history of the vehicle with the aim of reducing energy consumption and aging.