DE4322728A1 - Fuel tank, especially for motor vehicles - Google Patents

Abstract

The invention relates to a fuel tank, especially for motor vehicles, with a vent line, closable in the event of a maximum fuel level being exceeded or overfilling of the tank, which line is preferably connected to an adsorber device for fuel vapours or fuel. By means of a special design of the vent line the tank is normally kept free of excess pressure. On the other hand an excess pressure can be temporarily built up if the tank is overfilled, which pressure is sufficient to shut off a filler nozzle.

Description

The invention relates to a fuel tank, in particular for motor vehicles, with one if one is exceeded Maximum level of the fuel or when the Tanks lockable vent line, which preferred wise with a regenerable adsorber device or the like. for fuel vapors or fuel is connected.

For safety reasons, fuel tanks from Motor vehicles no - significant - overpressure to step. To ensure this, the fuel tank have a vent line, otherwise fuel vapors regularly present in the tank would lead to excessive pressure.

With regard to the protection of the environment, preference is given to this provided the vent line to a Adsorbervorrichtung od. Like. To guide over the Vent line escaping fuel vapors or to intercept fuel that escapes in this way and - during a regeneration phase of the adsorber direction or the like - the engine of the vehicle for ver to supply combustion.

When refueling the fuel tank, however, should A slight overpressure is reached when the maximum level is reached  can arise in the tank to safely shut off the Fuel flow through the fuel nozzle on the tank place to ensure. So much for an adsorber device or the like. should be avoided at the same time, that excessive amounts of fuel to the adsorber or the like. can reach.

So far, these contradicting demands cannot be met with reasonable effort. Usually vent valves are installed in the vent line orders that below a low threshold of Close the internal pressure in the tank and only with a certain one Overpressure in the tank are open. This under security measures harmless arrangement is indeed a flaw to ensure free switching off of the nozzles. However it is inevitable that due to the normally in the Prevailing slight overpressure when opening the Tanks, d. H. when refueling, more or less large Volumes of fuel vapors escape to the outside.

The object of the invention is now to open up a possibility show how with the simplest constructive means Reaching or slightly exceeding the pre see the maximum level of fuel in the tank a certain Overpressure can be built up to ensure a safe automa to ensure that the nozzles are switched off, and how, on the other hand, in normal operating conditions prevent overpressure in the tank.

This object is achieved in that the vent line has at least one turn with one a falling section forming the first section of the Level of the maximum level leads downwards, and one  a subsequent riser forming second section which is related to the level of the maximum level - or moreover - extends upwards, the Dimension the cross-section of the vent line in this way is that one entering the vent line Liquid line of the fuel when entering the Is able to tear down the fall path.

The invention ensures without any moving or even elaborate construction elements that the Vent line is normally open and the Prevention of excess pressure in the tank prevented.

Only when the tank is overfilled when refueling a limited excess pressure builds up in the tank because fuel now penetrates into the vent line and if the amount is sufficient, the transition area between Downpipe and riser blocked. With further inflow of fuel in the tank then becomes the fuel from the transition area into the riser presses, with the liquid column in the riser generates a back pressure that turns off the tap pistol leads. Usually then the following Driving operation due to the fuel consumption of the engine in the Tank creates a certain vacuum, through which then the fuel that has entered the vent line is sucked back.

Should the vehicle be with immediately after refueling Fuel that has entered the vent line be parked in a warm or sunny place, so that due to the heat in the tank increased strength form vapors and to a certain pressure  can lead into the vent line penetrated fuel if necessary also in the Adsorber or the like. Are displaced.

In any case, the vent line is also after maximum filling of the fuel tank before the next refueling without throttling, d. H. of the The next time you refuel, the tank is completely free of Overpressure.

If necessary, in the transition area between Drop and riser "fuel puddles" remain. However, this makes the permeability of the vent Line for fuel vapors in no way obstructed.

Another advantage of the invention is that easily check the tightness of the tank if the vent line via the adsorber device or the like. Connected to the intake manifold of the vehicle engine becomes. Then by a differential pressure meter easily determine whether the one that can be generated in the intake manifold Vacuum propagated into the tank.

Moreover, the advantageous features of Invention on the claims and the following Explanation of a preferred embodiment based on referred to the drawing.

It shows

Fig. 1 shows a schematic representation of a fuel tank with ventilation line according to the invention and an adsorber device and the intake manifold of a vehicle engine and

Fig. 2 different operating phases of the vent line.

A motor vehicle (not shown in more detail) has a fuel tank 1 , which can be constructed in a conventional manner and can be filled with fuel via a filler neck 2 which can be sealed.

In order to avoid that an unacceptable excess pressure can occur in the tank 1 due to the formation of fuel vapors, a ventilation line 3 branches off from the upper region of the fuel tank 1 , which opens into a housing 4 which is suitable for adsorbing fuel vapors or fuel Adsorption material is filled. The housing 4 has for feeding fresh air into the adsorption material 5 introduced fresh air line 6 , which is shut off by a valve 7 if necessary. Otherwise, a regeneration line 9 controlled by a valve 8 leads from the housing 4 to an intake manifold 10 of a vehicle engine, not shown in detail. Via this intake manifold 10 , the engine is supplied with the combustion air necessary for the combustion of the fuel in a generally known manner, the air flow being controllable in a known manner by means of a throttle valve 11 . The regeneration line 9 is connected between the throttle valve 11 and the engine not shown on the intake manifold 10 .

During normal driving operation, escaping fuel vapors from the adsorption material 5 are bound via the ventilation line 3 . In suitable operating phases of the vehicle engine - these operating phases are practically always present during normal driving - the adsorption material 5 is then regenerated by keeping the valves 7 and 8 open, so that fresh air flows through the adsorption material due to the negative pressure prevailing in the intake manifold 10 and adsorbs it Releases fuel to the fresh air flowing to the intake manifold 10 .

The special feature of the invention is that the ventilation line 3 has several - preferably helical - windings, each having a first section 31 forming a drop section and a second section 3 'forming a subsequent riser, the first section 3 ' from Level 12 of the maximum level of fuel to be specified in the fuel tank 1 leads downwards, while the respective second section 3 '' extends up to this level 12 , etc.

The cross-section of the vent line 3 is comparatively large, such that in the vent line 3 a kicking fuel regularly does not form a coherent liquid line and thus the vent line 3 can fill without the formation of air pockets.

The vent line 3 works as follows:

As long as no fuel has penetrated into the ventilation line 3 and the level of possibly refilled fuel remains in the tank 1 below the level 12 of the predetermined maximum level, the ventilation line 3 is completely gas and vapor permeable, ie the tank 1 can be vented via the ventilation line 3 keep free of excess pressure.

If the fuel level now reaches the maximum level during refueling, fuel will enter the first section 3 'of the first turn of the vent line 3 according to part A of FIG. 2. Because of the large cross section of the vent line 3 , the fuel will not completely fill the section 3 'mentioned. Rather, the fuel will flow essentially only along the wall of section 3 'of the first turn and collect in the transition region of the ventilation line 3 between sections 3 ' and 3 '' of the first turn.

As soon as in the deepest zone of this transition area the fuel fills the full cross-section of the ventilation line, the level of the fuel in section 3 '' of the first turn of the ventilation line will rise in the fuel tank 1 from the flowing fuel, the section 3 'of this increasing A closed air swirl remains trapped. Through the section 3 '' increasing level of the fuel is in the air-filled section 3 'of the first turn of the breather processing circuit occur a certain pressure, which searches entgegenzu act of fuel from the tank 1 to the further feed stream. This pressure propagates into tank 1 .

If this pressure is not sufficient to close the fuel nozzle that is tightly connected to the filler neck 2 , fuel will enter the section 3 'of the second turn of the vent line 3 according to part C of FIG. 2.

Finally, this can result in part D of Fig. 2, in which the sections 3 '' of, for example, three adjoining Win applications of the vent line 3 are largely filled with fuel, while in the previous sections 3 'this Turns each air is trapped. So that the further inflow of fuel counteracting back pressure is generated at the tank-side connection of the ventilation line 3 , which is proportional to the total height of the liquid columns in the fuel-filled sections 3 '' of the ventilation line.

With a sufficient number of turns of the vent line can be generated in this way in any case in the tank 1 , which closes the nozzle to the filler 2 tightly connectable nozzle, so that the refueling is terminated.

For the subsequent driving operation, the filler neck 2 is now closed. By removing fuel from the tank 1 via a fuel line (not shown) to the engine, a certain vacuum is now generated in the tank 1 , which sucks the fuel that has penetrated into the ventilation line 3 back into the tank.

In addition, part of the fuel that has entered the vent line 3 can also be temporarily absorbed by the adsorption material 5 .

In the end, the ventilation line 3 is practically completely freed of fuel in a comparatively short time, at least before the next refueling of the tank 1 . If necessary, 3 "fuel puddles" can remain in the deep zones between sections 3 'and 3 ''of the vent line 3 , but these have no measurable influence on the gas and vapor permeability of the vent line 3 . Thus, the vent line 3 is completely permeable again after a short time, with the result that no pressure can build up in the tank 1 due to vapor formation and escape of large amounts of fuel vapors from the tank when opening the filler neck 2 is avoided for subsequent refueling.

In the event of excessive filling of the tank 1 during refueling, on the one hand, a fuel nozzle can be generated from the excess pressure in the tank. On the other hand, the tank 1 is kept free of excess pressure when driving, so that no fuel vapors can escape when the filler neck 2 is opened during refueling.

A differential pressure meter 13 can also be arranged on the tank 1 , with which, when the filler neck 2 is closed and the valves 7 and 8 are closed, it can be determined whether the negative pressure which can be generated in the intake manifold 10 is propagated into the tank 1 . In this way, the tightness of the tank and the tank system parts connected to it can be checked if necessary.

The ventilation line 3 can expediently be connected to the tank 1 in the region of a zone which is shielded from surge movements of the fuel in the tank by baffles or the like. As a result, overfilling of the ventilation line 3 with fuel can be avoided even under the most unfavorable circumstances. Appropriately, the cross section of the vent line 3 is larger than the mouth cross section of fuel nozzles. This can be ensured particularly safely that when the tank 1 is overfilled in sections 3 'of the vent line 3, air is formed with successive addition of fuel from the tank 1 in sections 3 ''of the vent line 3 and liquid columns generate a back pressure to shut off the nozzle.

Claims (4)

1. Fuel tank, in particular for motor vehicles, with a lockable vent line when a maximum level of the fuel is exceeded or when the tank is overfilled, which is preferably connected to an adsorption device for fuel vapors or fuel, characterized in that the vent line ( 3 ) at least a turn with a falling section forming first section ( 3 '), which leads from the level ( 12 ) of the maximum level down, and a subsequent riser forming second section ( 3 ''), which level ( 12 ) of the maximum level extends upwards, the cross section of the vent line ( 3 ) being dimensioned such that a liquid surge entering the vent line ( 3 ) is able to tear as it enters the falling section, including air. 2. Fuel tank according to claim 1, characterized in that the ventilation line ( 3 ) has several turns. 3. Fuel tank according to claim 1 or 2, characterized, that the turn or turns are helical are trained. 4. Fuel tank according to one of claims 1 to 3, characterized in that the cross section of the vent line ( 3 ) is larger than the mouth cross section of the nozzle for filling the tank ( 1 ) serving.