DE102010016188A1 - Method for operating an electric vehicle - Google Patents

Abstract

The invention relates to a method for operating an electric vehicle, which has at least one electric drive machine, at least one electrical energy store, and at least one power generating device, wherein the power generating device is activated from a defined state of charge (SOC) of the electrical energy store. In order to reduce the cost of the electric vehicle and save space is provided that the power generating device is designed for a mean power demand of the electric drive machine at a defined continuous speed of the electric vehicle in the plane and that the power generation device even before reaching a lower technical operating limit of the state of charge of the electric energy storage is activated at a defined switch-on state of charge (SOC1), wherein the switch-on state of charge (SOC1) defines an energy reserve (R) of the electrical energy store with respect to the lower technical operating limit (SOC2) whose size is dimensioned such that in number, size and / or Permanently defined peak performances, preferably vehicle accelerations and / or gradients, can be covered.

Description

The Invention relates to a method for operating an electric vehicle, which at least one electric drive machine, at least one electrical Energy storage, as well as at least one power generation device has, wherein the power generating device from a defined state of charge of the electrical energy storage is activated.

From the EP 1 225 074 A2 is a series hybrid vehicle with an electric motor, a generator and a generator driving the internal combustion engine known. In this case, the vehicle is operated purely electrically with deactivated internal combustion engine within a zero-emission zone. In this case, the electric energy storage is charged by the internal combustion engine both shortly before entering the emission-free zone and when leaving the emission-free zone.

The WO 2005/082663 A1 discloses a portable power unit for electric vehicles, which is designed to extend the range of the electric vehicle.

From the US 2009/015202 A a method for charge control in a hybrid vehicle is known, wherein a nominal state of charge is defined as the mean value of the charging area. The energy flow is controlled so that the nominal state of charge is maintained. By operating the electric drive motor of the hybrid vehicle, the state of charge is lowered from this desired value and raised again by generating electrical energy with the internal combustion engine.

The WO 2008/128416 A1 discloses a hybrid vehicle energy management system having a load prediction system that calculates a future load level based on input parameters and a self-learning system to determine optimal future output power, battery state of charge, and vehicle speed based on the load request. On the basis of this optimum future power estimation, the internal combustion engine, the generator and the electrical energy store of the hybrid vehicle are coordinated.

at the known serial hybrid vehicles is generally the Internal combustion engine and the generator so dimensioned that the maximum power requirement can be covered.

task The invention is with the least possible technical Expenditure temporary load requirements for electric vehicles cover.

According to the invention this is achieved in that the power generating device for an average power requirement of the electric drive machine at a defined continuous speed of the electric vehicle is designed in the plane and that the power generating device even before reaching a lower technical operating limit of State of charge of the electrical energy store at a defined Power-on state is activated, the power-on state an energy reserve in relation to the lower technical operating limit of the electric energy storage defines its size is sized so that in number, size and / or Duration defined peak performances, preferably vehicle accelerations and / or Slopes can be covered. Preferably, the Start-up state set so that at least 10%, preferably at least 30% of the energy storage capacity as an energy reserve remains. In this way, all operating ranges of the Cover the vehicle.

In a particularly advantageous embodiment of the invention is provided that the switch-on state in a self-learning Process based on completed journeys of the electric vehicle is set.

alternative or additionally, it may be provided that the switch-on charge state depending on a destination and / or a planned Route is set, and it is particularly advantageous if for at least two travel sections of a planned route different Einschaltladezustände be defined. As a result, the track character in the definition of Einschaltladezustandes to be taken into account.

Thereby, that the power generation device for a medium Power requirement of the electric drive machine at defined Rated speed is designed in the plane leaves to achieve a very compact design.

The The invention will be explained in more detail below with reference to FIGS. Show it:

1 the state of charge of the electrical energy storage over the operating time; and

2 a design diagram for the power generation device.

In 1 the state of charge SOC of the electric energy storage of the electrically driven vehicle is plotted over the time t. In conventional electric vehicles, the electrical energy storage are emptied while driving to the technically possible minimum charge state, which represents a technical lower limit SOC2 for the drivability of the electric vehicle. After reaching this state, the available driving performance is directly dependent on the power supply of the power generation device (Range Extender) and thus limited.

According to the presented method is not the power generation facility only at the lower technical limit SOC2 of the electrical energy storage, but in the range of a middle first state of charge - the Charge state SOC1 - activated, leaving a residual Energy reserve R remains in the energy store. By definition the Einschaltladezustandes SOC1 above the lower technical limit SOC2, which triggers the charging process by the power generation device after reaching, can limit the retrieved driving performance by buffering over the energy reserve R can be extended to the system limits. In order to can temporary top performances, such as accelerations or slopes are covered, without the power of the power generation facility for the peak load, but only for a medium To dimension the power.

In 1 is with the dashed line 1 the driving operation with a conventional electrically driven electric vehicle and with 2 the driving operation according to the method described here. If the state of charge SOC reaches the switch-on charge state SOC1 (point 3 ), the power generating device is connected, with only more energy requirements, which go beyond the power of the power generating device, are taken from the energy reserve R of the electrical energy storage.

2 shows a design diagram for the power generation device (Range Extender), the power P is plotted against the vehicle speed v. For the design, the requirement is that the electric vehicle during operation with the range extender should not have any loss of performance compared to purely electrical operation. The electric vehicle is designed for a specific driving performance (dynamics, climbing ability, maximum speed, etc.). The power of the power generation device can be significantly lower than the power of the drive motor of the electric vehicle. The power generation device is designed so that it covers the maximum speed of the electric vehicle in the plane, including auxiliary consumers. The additional dynamic requirements are covered by a specified electrical reserve R of the electrical energy storage unit (vehicle battery).

Calculations have shown that, for example, in an electric vehicle with 1450 kg total weight with an electrical energy reserve R of about 2 kWh, the driving dynamics can be covered. In 2 are the resistance curves 4 . 5 . 6 . 7 entered for different gradients, with the dashed curves 4 ' . 5 ' . 6 ' . 7 ' the energy requirement is shown using additional benaggregaten. Looking at an example of an aggregate with 15 kW of electrical power, which would correspond to a wheel power of about 13 kW, then you realize that with this selected vehicle (1475 kg fully occupied) could reach a constant speed of 100 km / h. If one uses an electrical energy reserve R of 2 kWh, then you can drive this speed of 100 km / h even with a slope of 2% 21 km far with the range extender and the battery (see point 11 ). Alternatively, it could be accelerated 22 times from 100 km / h to 120 km / h. For comparison, at 80 km / h with a 2% gradient, a distance of 66 km can be covered or 28 acceleration events can be driven from 80 km / h to 100 km / h (see point 12 ). With a gradient of 5%, the energy reserve R can be used for a distance of 9 km or 19 acceleration cycles from 100 km / h to 120 km / h, as with point 13 is indicated. The reference number 14 denotes an operating point at 80 km / h at a gradient of 5%, at which 12 km can be carried out with the energy reserve R or 25 acceleration processes from 80 km / h to 100 km / h. Point 15 marks an operating point for a driving speed of 60 km / h, in which a distance of 22 km can be covered, or in which 34 acceleration operations from 60 km / h to 80 km / h can be performed. With a gradient of 10% and a driving speed of 60 km / h, with the energy reserve R only a distance of about 6 km can be covered or 28 acceleration processes from 60 km / h to 80 km / h can be carried out (point 16 ).

The switch-on charge state SOC1 or the energy reserve R can be set by the vehicle manufacturer on the basis of the estimated usage profile of the electric vehicle. Alternatively, it is also possible to determine the switch-on state of charge SOC1 flexibly during operation of the electric vehicle by means of a self-learning system. In this case, past journeys of the electric vehicle in the past can form the basis for a re-establishment of the start-up charge state SOC1, so that a factory-preset setting can be readjusted downwards or upwards on the basis of the actual travel distances. For example, it may be useful in a large number of vehicle accelerations and above-average steep sections to provide a larger reserve of energy R, whereby the power generating device is activated earlier in electric driving. On the other hand it can at even rides on flat roads with average speed may be quite useful to reduce the electrical energy reserve R and to delay the activation of the power generation device, thereby saving fuel and unnecessary emissions can be prevented.

Especially It is advantageous if, due to the input in a navigation system Destination data and traffic information the energy needs for overcoming the ones ahead Driving distance taking into account obstacles, such as Gradients, traffic jams or the like, is estimated and the optimal Energy reserve and thus the location of the activation of the Power generating device authoritative Einschaltladezustandes SOC1 is calculated. This optimization can be done by weighting the Driving time or the fuel consumption or emissions take place. Furthermore, it is also possible for certain Driving sections different energy reserves R flexibly defined become. This is particularly advantageous when the overwhelming track character (Steepness, curviness, traffic) changes in the course of a route.

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - EP 1225074 A2 [0002]
• WO 2005/082663 A1 [0003]
• - US 2009/015202 A [0004]
• WO 2008/128416 A1 [0005]

Claims (5)

Method for operating an electric vehicle, which has at least one electric drive machine, at least one electrical energy store, and at least one power generating device, wherein the power generating device is activated from a defined state of charge (SOC) of the electrical energy store, characterized in that the power generating device for an average power requirement of electric drive machine is designed at a defined continuous speed of the electric vehicle in the plane and that the power generating device is activated before reaching a lower technical operating limit of the state of charge of the electric energy storage at a defined Einschaltladezustand (SOC1), the Einschaltladezustand (SOC1) with respect to the lower technical operating limit (SOC2) defines an energy reserve (R) of the electrical energy store, the size of which is calculated so that in number, size and / or duration defined peak performance, preferably vehicle accelerations and / or gradients can be covered. Method according to claim 1, characterized in that that the switch-on state of charge (SOC1) is set so that at least 10%, preferably at least 30% of the capacity of the energy storage as Energy reserve (R) remains. Method according to claim 1 or 2, characterized That is, the start-up charge state (SOC1) in a self-learning process on the basis of completed journeys of the electric vehicle becomes. Method according to one of claims 1 to 3, characterized in that the switch-on state of charge (SOC1) depending on a destination and / or a planned Driving route is set. Method according to one of claims 3 or 4, characterized in that for at least two driving sections a planned route different Einschaltladezustände (SOC1).