DE102006059030A1 - Leakage test in a fuel cell system - Google Patents

Abstract

The invention relates to a method for detecting leaks in the anode circuit of a fuel cell system, wherein the anode circuit is closed in the presence of a predetermined minimum pressure by closing all inlets and outlets and determined by a pressure sensor at least two times the pressure in the anode circuit and the pressure difference to these two Measuring points is compared with a reference value without the presence of leakage.

Description

The The invention relates to a method for leakage testing of the anode circuit in one Fuel cell system with a fuel cell stack, in the the fuel in the operation of the fuel cell system in the circulation guided and over a valve fuel from a supply is supplied to the circuit.

Fuel cell systems For example, in automobiles are an emission-free alternative to combustion engines using fossil fuels.

One Leakage of fuel from the anode circuit of a fuel cell system is in addition to the loss of raw materials, especially a safety-related Problem, since this fuel is oxidizable and leaking fuel to undesirable, exothermic to explosive reactions may result.

It is therefore useful to devices or procedures for testing the Tightness of the anode circuit in the operation of a fuel cell system provided.

The JP 2004-108809 discloses an ultrasound-based flowmeter in a fuel cell system wherein the ultrasonic sensors are used to detect the typical flow noise when a leak occurs.

The WO 2004/112179 A2 shows a fuel cell system and a method to detect leaks in the hydrogen cycle. For this purpose, valves for closing the circuit as well as pressure measuring devices are provided in the circuit, wherein the rate of pressure change in the circuit is determined and analyzed against a predetermined curve to identify leaks.

Of the present invention is based on the object, a simple and also usable during operation of the fuel cell system Forming a method for detecting a leakage in the anode circuit.

to solution This object is achieved in a conventional fuel cell system proposed a method in which the supply and discharge of the Fuel cycle in its filled state when present a minimum pressure and the pressure in the circuit is determined at least two different times, where determines the pressure difference at the at least two measuring times and at least one reference value without the presence of a leak is compared.

Of the Pressure loss in the fuel cycle without presence of a Leakage, for example, by fuel passage through the membrane in the cathode circuit, for example, in a calibration process for each Fuel cell system determined and deposited, for example, in a processor unit become. Actually measured values are compared with the reference values, wherein a corresponding deviation to the presence of a leak shut down leaves.

In a first embodiment The invention is the minimum pressure when filling the fuel cell cycle set before starting the fuel cell reaction. The leak test is thus integrated into the starting process of the fuel cell system, being the possibility If there is leakage detection, the starting process of the fuel cell reaction exists to stop.

For this will be advantageous a threshold for the difference between the measured pressure difference in the fuel circuit and the at least one Defined reference value, and when exceeding this threshold the fuel cell reaction is not started.

The corresponding data are thereby in a central processing unit saved and processed.

In an alternative embodiment of the invention is the minimum pressure during operation of the fuel cell system in the course of the fuel cell reaction set when the reference value and the Pressure loss through the fuel cell reaction during the Measuring interval considered becomes. During ongoing operation of the fuel cell system leads the Consumption of fuel in the fuel cell reaction, at the gaseous one Educt in a liquid Product is automatically converted to a pressure drop in the product Anodenkreis, which at the reference value for detecting a leakage considered have to be.

In Another alternative is during operation of the fuel cell system the pressure in the cathode compartment first increased, the pressure in the anode compartment via a one-sided control system automatically to the desired Differential pressure is tracked to the cathode space, then the pressure in Reduced cathode space and re-adjusting the pressure in the anode room over the Determination of the pressure value over at least one period of time is detected.

While the pressure increase in the cathode compartment by the one-sided control system auto is tracked in the anode compartment, carried out in the return of the pressure in the cathode compartment, the adjustment of the now too high anode pressure on the consumption of fuel by the fuel cell reaction or by diffusion to the membrane. Since the fuel circuit is closed, no further fuel is supplied while performing the method for detecting a leak. If there is a leak in the anode circuit, the pressure reduction is faster than expected.

With Advantage is the one-sided control system a pneumatic Pressure control valve with which the pressure in the anode compartment directly and without an electronic signal generator can be set.

Further Features, advantages and effects of the invention will become apparent the following description, preferred embodiments of the invention and the attached Characters.

there shows:

1 a fuel cell system in a schematic representation,

2 a scheme of a test procedure.

This in 1 schematically illustrated fuel cell system 10 shows a fuel cell stack 20 comprising a plurality of individual fuel cells each having an anode 22a and a cathode 24a have, where the power-generating fuel cell reaction takes place. In this fuel cell reaction, hydrogen supplied as fuel is oxidized at the anode and oxygen is simultaneously reduced at the cathode, with the resulting ions combining to form water molecules. The anode 22a is adjacent to an anode gas room 22 on, over a line 30 Hydrogen is supplied while the cathode 24a to a cathode gas room 24 adjoining, via a pipe 40 is supplied with ambient air and thus with oxygen.

The unused oxygen as well as the inert parts of the air are transmitted via a pipe 42 executed from the cathode compartment and a humidifier and / or heat exchanger 44 delivered to the environment. Ambient air is via a blower 46 and the humidifier / heat exchanger 44 and the line 40 fed to the cathode compartment.

The hydrogen in the anode circuit is circulated primarily for safety reasons, but also for cost reasons, so that the hydrogen from the anode compartment 22 laxative line 32 over a fan 38 again into the line opening into the anode room 30 is guided. Hydrogen consumed by the fuel cell reaction is taken from a storage tank 50 via a valve 52 fed back to the hydrogen cycle. Since a leakage of hydrogen from the anode circuit can pose a safety problem due to the high reactivity of hydrogen with ambient air, it is important in the operation of a fuel cell system to be able to control the tightness of the hydrogen circuit.

For this purpose, in a first alternative according to the invention in 2 illustrated method proposed with which the tightness of the anode circuit can be tested before starting the fuel cell reaction. For this purpose, in a first step S1, the anode, that is, the hydrogen circuit with the lines 30 . 32 and the anode compartment 22 filled with hydrogen to the desired pressure. This is done via the valve 52 ( 1 ). After filling the hydrogen circuit this is closed in a second step S2, by the valves 52 . 36 and all other valves in the hydrogen circuit are closed. About a pressure sensor 34 the pressure in the hydrogen circuit is determined. The data of the pressure sensor 34 are forwarded to a central processing unit, not shown.

in the next Step S3 is entered in the processor unit, not shown Differential pressure Δp determined, that of the difference from two to different, defined Times t1 and t2 by the pressure sensor certain pressure values in the hydrogen circle corresponds. In the processor unit is as a reference value, the value of the pressure loss in the Hydrogen circuit assumes no leakage. Without too Hydrogen exists, in particular over the Membrane of the individual fuel cells from the hydrogen cycle out.

In the processor unit is in a further step S4 in the Test method specific differential pressure compared with the stored reference value and if the pressure loss is less than or equal to the reference value, For example, the fuel cell system may be started in the next step S5a become. If, on the other hand, the pressure loss is greater than the stored reference value either the test can be repeated beginning at step S1 or the fuel cell system becomes suspect in step S5b on the presence of a leak has not started.

The basically same method is used in an alternative embodiment during operation of the fuel cell system. Due to the operation, the hydrogen circuit is already filled (S1). The difference with this alternative embodiment is the pressure loss in the closed hydrogen loop due to the ongoing fuel cell reaction. This one by the Fuel consumption caused by fuel cell reaction, which leads to additional pressure loss in the circuit, must be taken into account when determining the reference value in the pressure measurement. Furthermore, it is important to make sure that there is no undersupply of the fuel cell with hydrogen due to the closed supply of fresh hydrogen into the system, as this would be harmful for the fuel cell.

In a further alternative embodiment, the method for checking for leaks in the hydrogen circuit is likewise carried out during operation of the fuel cell system. After closing the hydrogen circuit, the pressure in the cathode circuit is increased by increasing the blower power 46 ( 1 ), wherein the cathode circuit is connected to the anode circuit via a non-shown, one-way control valve so that the pressure increase in the lines 40 and 42 and the anode compartment 24 to a corresponding pressure increase in the anode circuit with the lines 30 . 32 and the anode compartment 22 leads. In the next step, the pressure within the cathode circuit is lowered in as short a time as possible, whereby an adaptation of the anode pressure via this control valve is not possible due to the single-acting control valve. The reduction of the pressure in the anode also takes place in this embodiment of the invention regularly only via the consumption of hydrogen in the fuel cell reaction or the normally occurring diffusion, especially through the membrane. For this purpose, the corresponding reference values are stored over time in the processor unit (not shown). If the differential pressure measured at two points in time t1 and t2 is greater than the stored reference value (step 4 in FIG 2 ), this is an indication of a leak in the hydrogen cycle, since hydrogen apparently escapes from the hydrogen cycle not only in the fuel cell reaction or by the normal diffusion in the system.

With Thus, according to the present invention, it is possible to provide a method of detection leaks in the hydrogen cycle of a fuel cell system both when starting the fuel cell system and in the operation of the Fuel cell system apply.

Claims (6)

Method for leakage testing of the anode circuit ( 30 . 22 . 32 ) in a fuel cell system ( 10 ) with a fuel cell stack ( 20 ), in which the fuel is circulated during operation of the fuel cell system and the circuit via a valve ( 52 ) Fuel from a supply ( 50 ), the leak test comprising the following steps: - closing the supply and discharge lines ( 52 . 34 ) of the anode circuit ( 30 . 22 . 32 ) in the presence of a minimum pressure (S2) - determining the pressure in the circuit at least two different times - determining the pressure difference to the at least two measuring times (S3) - comparing the pressure difference with at least one reference value in the absence of leakage (S4). A method according to claim 1, characterized in that the minimum pressure during filling of the anode circuit ( 30 . 22 . 32 ) is set before starting the fuel cell reaction. Method according to claim 1 or 2, characterized that a threshold for the difference between the measured pressure difference in the anode circuit and the at least one reference value is defined when it is exceeded the fuel cell reaction is not started. A method according to claim 1, characterized in that the minimum pressure on the operation of the fuel cell system ( 10 ) is adjusted while the fuel cell reaction is in progress and the pressure drop through the fuel cell reaction during the measurement interval is taken into account in the determination of the reference value. Method according to claim 4, characterized in that the pressure in the cathode circuit ( 40 . 24 . 42 ) during operation of the fuel cell system ( 10 ) is increased, the pressure in the anode circuit ( 30 . 22 . 32 ) is automatically tracked via a single-acting control system to the desired differential pressure to the cathode circuit, then the pressure in the cathode circuit again reduced and the adjustment of the pressure in the anode circuit is detected by determining the pressure value over at least a period of time. Method according to claim 5, characterized in that that the unidirectional control system, a pneumatic pressure control valve is.