DE102018214708A1 - Fuel cell arrangement with several fuel cell systems and motor vehicle with such a fuel cell arrangement - Google Patents

Abstract

The invention relates to a fuel cell arrangement (100) with an electrically controllable first fuel cell system (102) and at least one electrically controllable second fuel cell system (104), as well as with a control unit (106), which is connected to the first fuel cell system (102) with a signal transmission line (108). is in communication connection. A transmission signal conversion device (110) is integrated in the signal transmission line (108), and the signal transmission line (108) is also connected to the at least one second fuel cell system (104), such that the control device (106) is also connected to the at least one second fuel cell system (104 ) is in communication connection. The invention also relates to a motor vehicle with such a fuel cell arrangement.

Description

The invention relates to a fuel cell arrangement with an electrically controllable first fuel cell system and with at least one electrically controllable second fuel cell system, as well as with a control device which is in communication with a signal transmission line with the first fuel cell system. The invention further relates to a motor vehicle with such a fuel cell arrangement.

From the US 2005/0112428 A1 a fuel cell arrangement is known which has a plurality of fuel cell stacks or fuel cell systems, each of which is equipped with its own control unit, which are in a communication connection by means of a control unit master. In the DE 10 2012 010 173 A1 A fuel cell arrangement for a vehicle and a method for operating a fuel cell arrangement are specified, with each individual fuel cell system of the fuel cell arrangement also being assigned or assigned its own control unit. One of the control units is designed as a control unit master, which forwards the control signals received from the vehicle control unit to the local subordinate control units.

Thus, in known fuel cell arrangements, each individual fuel cell system or each individual fuel cell stack of the respective system is assigned an independent control device. In the technological advancement, which provides for a reduction in the fuel cell stack of individual fuel cell systems, but in which there are a plurality of smaller fuel cell systems, there has hitherto been no sensible solution for actuation with parallel replication of the fuel cell systems in a vehicle.

It is therefore the object of the present invention to provide a fuel cell arrangement and a motor vehicle which take into account the disadvantages mentioned above.

This object is achieved with a fuel cell arrangement with the features of claim 1 and with a motor vehicle with the features of claim 10. Advantageous refinements with expedient developments of the invention are specified in the dependent claims.

The fuel cell arrangement is characterized in particular by the fact that a transmission signal conversion device is integrated in the signal transmission line and that the signal transmission line is also connected to the at least one second fuel cell system, such that the control unit is also in communication connection with the at least one second fuel cell system.

Such a fuel cell arrangement has the advantage that, owing to the use of a transmission signal conversion device, only a single control device is necessary in order to control a large number of individual fuel cell systems. The identical signal can be transmitted to the individual fuel cell stacks of the individual fuel cell systems. This also creates a modularity of the fuel cell systems, as a result of which further fuel cell systems can be integrated into or removed from the fuel cell arrangement in a simple manner.

For example, the fuel cell systems include one or more actuators and / or actuators which can be controlled by means of the control unit via the signal transmission line. The first fuel cell stack and all further fuel cell stacks can comprise the same actuators and actuators, so that a single signal, possibly amplified, sent by the control device can be sent to the different fuel cell systems in order to control their actuators and / or their actuators.

In this context, it has proven to be advantageous if the actuators are selected from an actuator group that includes valves, in particular pressure control valves for reactant flow, and flaps. As an alternative or in addition, the actuators are selected from an actuator group which comprise a compressor, a recirculation fan, a jet pump and a coolant pump. All of these actuators and all of these actuators are suitable for adapting or adjusting the fuel cell system to the required operating conditions. Due to the use of only a single control device, installation space can also be saved when using the fuel cell arrangement in a motor vehicle.

It has also proven to be useful if the control unit is in communication with a signal reception line both with the first fuel cell system and with the at least one second fuel cell system, and when a reception signal conversion device is integrated in the signal reception line. This also enables the different or the same signals emitted by the fuel cell systems to be “processed” accordingly by means of the received signal conversion device so that the control device can reliably detect them.

In the first fuel cell system and / or in the at least one second fuel cell system, there is preferably at least one sensor for measuring an operating parameter of the fuel cell system, the control device then being designed to receive values detected by the at least one sensor via the signal reception line. This means that feedback or information about the status of individual or all fuel cell systems of the fuel cell arrangement can be made on the basis of the values detected by the sensors.

In this context, it has proven to be useful if the sensor is selected from a sensor group that includes a pressure sensor, a temperature sensor, a mass flow sensor and a voltage sensor. With the pressure sensor, for example, the reactant pressures present in the fuel cell stacks can be measured. However, an axial force of a clamping system for bracing the fuel cell stack can also be detected by means of a pressure sensor. In addition, the temperature of individual components of the fuel cell systems can be detected and monitored by means of a temperature sensor in order to prevent the fuel cell system from being operated in a temperature range which has a damaging effect. The same applies to the detection of a mass flow, for example a mass flow of the reactants. In order to be able to detect the currently available power of individual fuel cell systems of the fuel cell arrangement, it has also proven to be advantageous if a voltage sensor is provided for measuring the voltages generated by the fuel cell stacks, but alternatively or additionally also for detecting an individual cell voltage.

In a particularly advantageous refinement of the invention, the first fuel cell system is formed as a master system and the at least one second fuel cell system as a slave system. This thus opens up the possibility that the control device only controls the first fuel cell system formed as a master, the at least one slave system emulating the mode of operation of the master. In this context, it has therefore proven to be advantageous if the at least one slave system can be operated in an operating mode which simulates the operating mode of the master system.

The manufacture of the fuel cell arrangement is facilitated if the first fuel cell system and the at least one second fuel cell system have an identical structure. In addition, due to an identical construction, a modular construction can be realized, in which more than just two fuel cell systems can be integrated in a common fuel cell arrangement.

In the case of an increase in the number of individual modules in fuel cell systems, it has also proven to be useful if the transmission signal conversion device and / or the reception signal conversion device integrated in the signal reception line is designed as a signal amplifier. This ensures that even more remote fuel cell systems can be reliably controlled by means of the control unit, which are also integrated in the fuel cell arrangement.

The advantages and preferred embodiments explained in connection with the fuel cell arrangement also apply to the motor vehicle according to the invention. It is characterized by a space-saving design and easy expandability (modularity).

• 1 eine schematisiert dargestellte Brennstoffzellenanordnung mit mehreren Brennstoffzellensystemen.

Further advantages, features and details of the invention emerge from the claims, the following description of a preferred embodiment and with reference to the drawing. It shows:

• 1 a schematically shown fuel cell arrangement with several fuel cell systems.

In 1 is a highly schematic fuel cell assembly 100 with an electrically controllable first fuel cell system 102 and at least one electrically controllable second fuel cell system 104 shown. The three horizontal points between the first fuel cell system 102 and the second fuel cell system 104 the modular integration of further second fuel cell systems 104 imply that more than two of the fuel cell systems 102 . 104 can be present. The fuel cell assembly 100 includes a single control unit 106 , This control unit 106 stands by means of a signal transmission line 108 with the first fuel cell system 102 in communication connection. There is also a signal reception line 112 present, which is also the control unit 106 with the first fuel cell system 102 couples in a communication link.

The fuel cell assembly 100 is characterized by the fact that the second fuel cell system 104 in a communication link with the control unit 106 stands. This is in the signal transmission line 108 a transmission signal converter 110 involved, so that of the control unit 106 emitted control signals from the transmission signal converter 110 like that be prepared for both the first fuel cell system 102 as well as the second fuel cell system 104 can be used for control. The signal transmission line is therefore present 108 starting from an output, ie starting from the output terminal 118 with one input, ie one input terminal 116 the transmission signal converter 110 connected. The output or the output terminal 118 of the control unit 106 the transmission signal converter 110 is again with the inputs or the input terminals 116 both the first fuel cell system 102 as well as the second fuel cell system 104 connected. The signal converter device is in a simplified version 110 formed only as a signal amplifier, so that the control unit 106 emitted signal amplifies the majority of fuel cell systems 102 . 104 is sent.

The signal reception line 112 is based on the control unit 106 , ie with the input or the input terminal 116 of the control unit 106 connected. At the other end is the signal reception line 112 with an output terminal 118 or an output of the received signal converter 114 connected, their input or their input terminal 116 with outputs or output terminals 118 of fuel cell systems 102 . 104 is coupled. Here too, the received signal conversion device is in a particularly simple embodiment 114 formed as a signal amplifier.

Via the signal reception line 112 For example, data may be sent from one or more of the fuel cell systems 102 . 104 assigned sensors, for example pressure sensors, temperature sensors, mass flow sensors, voltage sensors and the like. Via the signal transmission line 108 can control signals to actuators and / or actuators of the fuel cell systems 102 . 104 are sent, actuators in the form of valves, in particular pressure regulating valves, and flaps can be provided. Possible actuators are, for example, a compressor that draws in the cathode gas, a recirculation blower that recirculates the fuel, a jet pump that serves to circulate reactants, and a coolant pump that circulates coolant in a cooling circuit.

In this context, it should be noted that every fuel cell system 102 . 104 can be an autonomous system that is modularly expandable. Alternatively, however, a common reactant supply and / or a common supply of coolant can also be used in the fuel cell systems 102 . 104 available.

The fuel cell arrangement shown 100 is characterized in particular by the fact that the first fuel cell system 102 is formed as a master, and that the at least one second fuel cell system 104 represents a slave. So this is the first fuel cell system 102 hierarchically the second fuel cell system 104 parent, the second fuel cell system 104 only a mirror of the mode of operation of the first fuel cell system 104 represents. In other words, it forms the second fuel cell system 104 the mode of operation of the first fuel cell system 102 to. It is therefore sufficient if the control unit 106 the first fuel cell system 102 controls. Nevertheless, it makes sense to determine the operating parameters of the at least one second fuel cell system 102 (e.g. pressure, reactant flow, temperature etc.) via the signal reception line 112 to monitor.

It should be noted that the transmission signal conversion device 110 and the received signal conversion device 114 can be integrated into a common component. This component can comprise, for example, a processor in order to form an average value of the sensor data and for minimum, maximum values or the like that of the fuel cell systems 102 . 104 extract or calculate the data collected. Of course there is also the possibility of a fusion of the individual signals from the sensors of the fuel cell systems 102 . 104 to carry out, that is to say instead of simply averaging an extreme value, for example the maximum of all individual signals or the like.

The fuel cell arrangement described above 100 is characterized by an improved modularity and the resulting simplified manufacturing. In addition, the use of only a single control unit 106 necessary, which also favors the easy expandability. This allows a larger number of smaller fuel cell stacks or smaller fuel cell systems 102 . 104 will be realized.

Reference list

100

Fuel cell arrangement

102

first fuel cell system

104

second fuel cell system

106

control unit

108

Signal transmission line

110

Transmit signal converter

112

Signal reception line

114

Receive signal conversion device

116

Input terminal

118

Output terminal

QUOTES INCLUDE IN THE DESCRIPTION

This list of documents listed by the applicant has been generated automatically and is only included for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent literature cited

• US 2005/0112428 A1 [0002]
• DE 102012010173 A1 [0002]

Claims (10)

Fuel cell arrangement (100) with an electrically controllable first fuel cell system (102) and at least one electrically controllable second fuel cell system (104), as well as with a control unit (106) which is in communication with a signal transmission line (108) with the first fuel cell system (102), characterized in that a transmission signal conversion device (110) is integrated in the signal transmission line (108), and that the signal transmission line (108) is also connected to the at least one second fuel cell system (104), such that the control device (106) also connects to the at least one a second fuel cell system (104) is in communication connection. Fuel cell arrangement (100) according to Claim 1 , characterized in that the fuel cell systems (102, 104) comprise one or more actuators and / or actuators which can be controlled by means of the control device (106) via the signal transmission line (108). Fuel cell arrangement (100) according to Claim 2 , characterized in that the actuators are selected from an actuator group comprising valves and flaps and / or in that the actuators are selected from an actuator group comprising a compressor, a recirculation fan, a jet pump and a coolant pump. Fuel cell arrangement (100) according to one of the Claims 1 to 3 , characterized in that the control unit (106) is in communication with a signal reception line (112) both with the first fuel cell system (102) and with the at least one second fuel cell system (104), and in the signal reception line (112) with a reception signal conversion device ( 114) is involved. Fuel cell arrangement (100) according to Claim 4 , characterized in that in the first fuel cell system (102) and / or in the at least one second fuel cell system (104) there is at least one sensor for measuring an operating parameter of the fuel cell system (102, 104), and in that the control device (106) is designed, to receive values detected by the at least one sensor via the signal reception line (112). Fuel cell arrangement (100) according to Claim 5 , characterized in that the sensor is selected from a sensor group comprising a pressure sensor, a temperature sensor, a mass flow sensor and a voltage sensor. Fuel cell arrangement (100) according to one of the Claims 1 to 6 , characterized in that the first fuel cell system (102) is formed as a master system and the at least one second fuel cell system (104) is formed as a slave system. Fuel cell arrangement (100) according to one of the Claims 1 to 7 , characterized in that the first fuel cell system (102) and the at least one second fuel cell system (104) have an identical structure. Fuel cell arrangement (100) according to one of the Claims 1 to 8th , characterized in that the transmission signal conversion device (110) and / or a reception signal conversion device (114) integrated in a signal reception line (112) is formed as a signal amplifier. Motor vehicle with a fuel cell arrangement (100) according to one of the Claims 1 to 9 ,

Images