EP2307690B1 - Internal combustion engine and method for operating an internal combustion engine of this type - Google Patents

Description

The invention relates to an internal combustion engine and method for operating an internal combustion engine.

From the fuel tank of a motor vehicle, in which, for example, stored gasoline, exhaust gases can escape, which dissolve from the fuel. Highly volatile hydrocarbons may release themselves from fuel at high ambient temperatures or by shaking the fuel tank while driving and leave the fuel tank as gas. To counteract this, fuel tanks can be sealed gas-tight. The volatile hydrocarbons are then stored in a memory and can be supplied to the intake air of the internal combustion engine. The problem, however, is that the gaseous hydrocarbon can ignite uncontrollably in the supply lines. US2004 / 226543 describes such a device as described above.

It is an object of the invention to provide an internal combustion engine and a method for operating an internal combustion engine, which can be operated safely.

This object is achieved by a method having the features of claim 1, a method having the features of claim 7 or an internal combustion engine having the features of claim 11.

A method of operating an internal combustion engine having at least one sensor for measuring a hydrocarbon content of a gas stream in a conduit comprises determining a temperature at the at least one sensor. If the temperature is greater than a predetermined temperature, the gas flow through the line is interrupted.

Thus, a fire of hydrocarbonaceous gas can be detected and countermeasures can be taken.

The method may include evaluating a signal of at least one temperature sensor that has the at least one sensor. The method may include evaluating a signal of at least one semiconductor device. The semiconductor component is integrated in the at least one sensor. As a result, the temperature at the at least one sensor can be determined relatively easily.

The method may include shutting off at least one heating element having the at least one sensor for heating the gas flow. A power supply of the at least one heating element can be interrupted. The heating element can cause a fire of the hydrocarbon gas by a malfunction and by switching off or interrupting the power supply, this cause of fire can be eliminated.

The method may include closing at least one valve located upstream of the at least one sensor. Thus, in a fire, the supply of combustible gas can be interrupted and further spread of a fire as possible prevented.

A method of operating an internal combustion engine according to another embodiment includes determining a temperature at a temperature sensor. The internal combustion engine has at least one sensor for measuring a hydrocarbon content of a gas stream in a line, and the at least one sensor has the temperature sensor. An additional temperature is determined at a further temperature sensor of the at least one sensor. The temperature difference of the temperature and the further temperature is determined and the gas flow interrupted when the temperature difference is greater than a predetermined temperature difference.

The method may include closing at least one valve disposed upstream of the at least one sensor. Thus, it can be prevented that further combustible gas is supplied to a fire, and a spread of fire can be effectively prevented.

The method may include shutting off the at least one heating element having the at least one sensor for heating the gas flow. The power supply of the at least one heating element can be interrupted. Thereby, a fire cause, for example, a malfunction of the heating element, are turned off.

An internal combustion engine comprises at least one sensor for measuring a hydrocarbon content of a gas stream in a pipe. The internal combustion engine has a comparison device for comparing a temperature at the sensor with a predetermined temperature. The internal combustion engine comprises at least one valve for interrupting the gas flow, which is arranged upstream of the at least one sensor. The at least one valve is controlled by the comparison device, so that the gas flow through the line is interrupted when the temperature is higher than the predetermined temperature.

The at least one sensor may have at least one heating element for heating a gas flow and at least one temperature sensor. The temperature sensor can be used to determine the temperature at the sensor.

The comparison device may be part of a motor control with which the sensor is coupled. As a result, a fire can be detected effectively, and countermeasures can be controlled by the comparison device or the engine control.

Figur 1

eine schematische Darstellung einer Brennkraftmaschine,

Figur 2

eine schematische Darstellung eines Sensors und eines Ventils in einer Leitung,

Figur 3

ein Ablaufdiagramm eines Verfahrens.

Other features, advantages and developments will become apparent from the following in connection with the FIGS. 1 to 3 explained examples. Show it:

FIG. 1

a schematic representation of an internal combustion engine,

FIG. 2

a schematic representation of a sensor and a valve in a line,

FIG. 3

a flowchart of a method.

FIG. 1 FIG. 10 shows an internal combustion engine 100 having a fuel tank 106, an internal combustion engine 114, and a hydrocarbon tank 108. In the fuel tank 106, fuel 107 is stored. Gaseous hydrocarbons 109 may be directed from the fuel tank in the hydrocarbon tank via a conduit 111 coupled to the fuel tank 106 and the hydrocarbon tank 108. The hydrocarbon tank is coupled via a line 110 to the internal combustion engine 114, in particular the intake tract of the internal combustion engine.

The line 110 has a valve 103 and a further valve 104 as well as a hydrocarbon sensor 101 and a further hydrocarbon sensor 102. The hydrocarbon sensors are configured to measure a hydrocarbon content of a gas stream. It can also be arranged only one hydrocarbon sensor, it can also be arranged more hydrocarbon sensors, for example, two or more hydrocarbon sensors. The hydrocarbon sensors can also be arranged on further lines, for example the line 111. The valves are designed to interrupt the gas flow. It can also be arranged only one valve, it can also be arranged more valves, for example, two or more valves. The valves can also be arranged on other lines, such as the line 111.

The valve 103 is coupled via an electrical line 113 to the engine controller 105, the sensors 101 and 102 are coupled via an electrical line 112 to the engine controller. The engine controller 105, which has a comparator 116, controls the valves and can evaluate signals from the sensors.

From the fuel 107, such as a gasoline, hydrocarbons, such as methane, butane or propane volatilize. The different hydrocarbon chains have different evaporation temperatures, so that different hydrocarbons are released from the liquid fuel 107 depending on the outside temperature. The higher the outside temperature and thus the temperature of the fuel 107, the more hydrocarbons pass into the gas phase. The tank 106, in which the fuel 107 is stored, is gas-tight. The fuel cap gas-tightly closes a filler neck of the fuel tank. The hydrocarbon-containing gas mixture that forms in the tank 106 is fed via the line 111 into the hydrocarbon tank 108.

The hydrocarbon tank may contain an activated carbon storage element. The evaporated hydrocarbons are taken up by the activated carbon, stored and released again when needed. If the hydrocarbon tank has taken up a certain amount of hydrocarbons, it can be drained via line 110. For this purpose, air is blown into the hydrocarbon tank from the outside via a valve 115, which receives the hydrocarbons. The hydrocarbon-containing air may be used as intake air for the engine 114, thereby contributing to combustion in the engine. Since a certain amount of energy is supplied by the hydrocarbons in the intake air to the engine, is injected with less fuel via an injection system. To control this ratio, the hydrocarbon content of the supplied air is measured via the sensors 101 and 102.

Sensors for measuring a hydrocarbon content include, for example, a heating element for heating a gas flow and a temperature sensor. For example, the sensor is integrated on a silicon chip. The flowing past the sensor element gas stream is heated and based on signals from the temperature sensor, which are evaluated by the engine control, the thermal conductivity or the heat capacity of the gas flowing past can be determined. From this, the concentration of the hydrocarbon in the gas can be determined, since this is proportional to the thermal conductivity or heat capacity of the gas.

In the event of a malfunction of the sensor for measuring the hydrocarbon content, for example overheating of the heating element or sparking due to breakdown, the hydrocarbon-containing gas in the line 110 may ignite. In order to be able to detect such a fire, the comparison device 116, which is part of the engine control 105 in the embodiment shown, compares a respective temperature at the hydrocarbon sensors with a predetermined temperature, which was determined representative of a fire. If the comparison device determines that the temperature determined at the sensor element is above the predetermined temperature, it can take measures. To prevent a supply of further flammable gas to the fire, the gas supply is interrupted. This can be done by closing the valve 103 or the valve 104. It can also be closed, the valve 115 and thereby the emptying of the hydrocarbon tank can be stopped. If a fire is detected on the sensor 101, the valve 103 can be closed and the valve 104 remain open. If a fire is detected on the valve 102, either only the Valve 104 are closed or the valve 103 and 104 are closed.

Another measure that can be taken when the temperature of the gas flow at a sensor is higher than the predetermined temperature, is the switching off of the corresponding sensor, in particular the switching off of the heating element. The power supply to the sensor is interrupted. By interrupting the gas flow in the conduit 110 and switching off the at least one heating element, a spread of a fire of the hydrocarbon gas can be prevented as well as possible.

FIG. 2 shows a sensor 200 and a valve 204, which are arranged in a line 206. In line 206, a gas 205 is performed. The sensor 200 has a temperature sensor 201 and a further temperature sensor 203, which are each arranged on one side of a heating element 202. The sensor 200 is configured to measure the concentration of hydrocarbon in the gas 205. The valve 204 may terminate the conduit 206 so that no gas passes through the valve. The sensor 200 may be coupled to a comparison device, which is part of an engine control of an internal combustion engine, for example.

The sensor 200 is integrated, for example, on a silicon substrate and may comprise further elements, for example an evaluation circuit or an analog-to-digital converter. The gas 205 flowing past the sensor 200 is heated by the heating element 202 in a defined manner. The temperature sensor 201, which is located upstream of the heating element, detects the temperature of the gas flow before the gas flow is heated, the further temperature sensor 203, which is arranged downstream of the heating element 202, detects the temperature of the heated gas. About a difference of these temperatures can be concluded that the heat capacity of the gas.

From this, the content of hydrocarbons in the gas 205 can be determined.

The comparison device may compare the temperature of the temperature sensor 201 with a predetermined temperature. The comparison device may instead or additionally compare the temperature of the further temperature sensor 203 with a predetermined temperature. The comparison device can also compare the temperature difference between the two measured temperatures with a predetermined temperature difference. The predetermined temperature or the predetermined temperature difference represents an upper limit of the temperature which occurs during normal operation of the sensor 200. A higher temperature than the predetermined temperature suggests a fire of gas 205 in line 206. A higher temperature difference than the predetermined temperature difference indicates a fire of gas 205 in line 206. If the comparison device determines a higher temperature than the predetermined temperature or a higher temperature difference than the predetermined temperature difference, it can regulate the valve 204 in such a way that no additional gas can reach the sensor 200. In addition, the power supply to the sensor 200, in particular to the heating element 202, be interrupted in order to eliminate a possible cause of fire. By switching off or interrupting the power supply of the sensor, a fire causing malfunction, such as sparking, turned off and thus prevents the faulty sensor triggers another fire.

In a first step S1 of a method for operating an internal combustion engine, the start takes place, which can be close to a start of the internal combustion engine.

In a second step S2, a temperature is determined on at least one sensor. The sensor is a sensor for Measurement of a hydrocarbon content of a gas stream in the internal combustion engine.

In a third step S3, the determined temperature is compared with a predetermined temperature and it is determined whether the determined temperature is greater than the predetermined temperature. If the specific temperature is not greater than the predetermined temperature, the process continues with step S2. If the specific temperature is greater than the predetermined temperature, the gas flow in the line is interrupted in step S4.

In addition, in step S4, a heating element of the sensor can be switched off and / or the power supply of the heating element or the sensor can be interrupted. The determination of the temperature at the at least one sensor in step S2 can be carried out by evaluating a signal of a temperature sensor. The temperature sensor is, for example, a semiconductor component which is integrated in the at least one sensor.

In a further exemplary embodiment of the method, a first temperature is determined by a temperature sensor of the at least one sensor in step S2. A further temperature is determined by a further temperature sensor of the at least one sensor and a temperature difference of the temperature and the further temperature is determined. In step S3, the temperature difference is compared with a predetermined temperature difference and it is determined whether the temperature difference is greater than the predetermined temperature difference. If this is the case, in step S4, for example, a valve is closed to interrupt a gas flow, and / or the sensor is turned off. If the temperature difference is not greater than the predetermined temperature difference, step S2 is continued.

Claims (13)

1. Method for operating an internal combustion engine which has at least one sensor (101) for measuring a hydrocarbon content of a gas flow in a line (110), the line conducting the gas flow from a tank (106) to a hydrocarbon tank (108), and the hydrocarbon tank being coupled via the line to an intake tract of a combustion engine (114), comprising:

   - determining a temperature at the at least one sensor (101);

   - interrupting the gas flow through the line (110) if the temperature is greater than a predefined temperature.
2. Method according to Claim 1, comprising: evaluating a signal of at least one temperature sensor (203) which the at least one sensor (101; 200) has.
3. Method according to Claim 1 or 2, comprising: evaluating a signal of at least one semiconductor component which is integrated in the at least one sensor (101).
4. Method according to one of Claims 1 to 3, comprising:

   deactivating at least one heating element (202) which the at least one sensor (101; 200) has for heating up the gas flow.
5. Method according to one of Claims 1 to 4, comprising:

   interrupting a supply of current to the at least one heating element (202).
6. Method according to one of Claims 1 to 5, comprising:

   closing at least one valve (103; 204) which is arranged upstream of the at least one sensor (101).
7. Method for operating an internal combustion engine according to Claim 1, wherein

   - a temperature at a temperature sensor (203) of the at least one sensor (101; 200) is determined;

   - a further temperature at a further temperature sensor (201) of the at least one sensor (101; 200) is determined;

   - a temperature difference between the temperature and the further temperature is determined;

   - the gas flow at the at least one sensor (101; 200) is interrupted if the temperature difference is greater than a predefined temperature difference.
8. Method according to Claim 7, comprising: closing at least one valve (103) which is arranged upstream of the at least one sensor (101).
9. Method according to Claim 7 or 8, comprising: deactivating at least one heating element (202) which the at least one sensor (101; 200) has for heating up the gas flow.
10. Method according to one of Claims 7 to 9, comprising:

    interrupting a supply of current to the at least one heating element (202).
11. Internal combustion engine (100), comprising:

    - at least one sensor (101) for measuring a hydrocarbon content of a gas flow in a line (110), the line conducting the gas flow from a tank (106) to a hydrocarbon tank (108), and the hydrocarbon tank being coupled via the line to an intake tract of a combustion engine (114);

    - a comparison device (116) for comparing a temperature at the sensor (101) with a predefined temperature;

    - at least one valve (103) for interrupting the gas flow, which valve is arranged upstream of the at least one sensor (101) and is regulated by the comparison device such that the gas flow through the line is interrupted if the temperature is higher than the predefined temperature.
12. Internal combustion engine according to Claim 11, in which the at least one sensor (101; 200) has at least one heating element (202) for heating up a gas flow and has at least one temperature sensor (203).
13. Internal combustion engine according to Claim 11 or 12, in which the comparison device is part of an engine controller (105).

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