EP1180595B1 - Fuel supply arrangement - Google Patents

Description

State of the art

The invention is based on a fuel supply system for supplying fuel to an internal combustion engine according to the preamble of claim 1.

So far there were fuel supply systems, where one first fuel pump from a fuel tank Fuel via a fuel connection to a second Fuel pump promotes. The second fuel pump in turn Promotes the fuel via a pressure line at least one fuel valve. Usually that is Number of fuel valves equal to the number of cylinders the internal combustion engine. The fuel supply system can be built so that the fuel valve is the fuel injected directly into a combustion chamber of the internal combustion engine. When operating this fuel supply system is a high pressure in the pressure line leading to the fuel valve required. For safety reasons and never completely exclude leakage of the fuel valve in the combustion chamber, it is useful after stopping the Internal combustion engine the pressure in the fuel connection and in the pressure line of the fuel supply system all the way or at least largely reduce.

The German patent application DE 195 39 885 A1 shows a Fuel supply system, in which for starting the internal combustion engine a valve means ensures that during startup, the first fuel pump the Fuel with increased feed pressure to the fuel valves supplies. In many cases, this increased Supply pressure off to the internal combustion engine in the shortest possible time to start. Due to the increased feed pressure can a possible gas bubble in the fuel connection between the first fuel pump and the second fuel pump in many cases are compressed so much that a safer Operation of the internal combustion engine is ensured. Nevertheless It can be particularly at high temperatures during the Operating the internal combustion engine and in particular also when the engine stopped at high temperature was, continue to startup problems and too Problems during operation of the internal combustion engine during high temperatures come. As has now been stated, this is obviously due to the fact that the gas bubble largely compressed by the increased feed pressure, but not sufficiently removed from the fuel supply system becomes. Furthermore, it has now been found that by insufficient heat dissipation from the fuel supply system it causes problems at high operating temperature Internal combustion engine can give.

Advantages of the invention

The fuel supply system according to the invention with the Characteristic features of claim 1 provides the advantageous Possibility for particularly high heat load of the fuel in the fuel supply system, in particular but also with particularly high heat load especially the second fuel pump, to make sure that sufficient heat dissipation from the lines of Fuel supply system takes place and that no gas bubbles arise within the pipes. Especially because of Purge line can transfer fuel into the fuel tank be returned, which is an advantageous heat dissipation allows. Due to the closable shut-off valve the removal of the fuel through the purge line increased pressure in the fuel connection between the both fuel pumps, allowing an effective rinse guaranteed and that it is further ensured that on Input to the second fuel pump no gas bubbles or Steam bubbles occur. This will advantageously Reliably a performance drop especially the second Fuel pump reliable even at high temperature prevents and even at high temperature is a reliable Starting the internal combustion engine guaranteed.

By the measures listed in the dependent claims are advantageous developments and improvements the fuel supply system according to claim 1 possible.

drawing

Selected, particularly advantageous embodiments of the Invention are shown in simplified form in the drawing and explained in more detail in the following description. Show it 1 shows a first embodiment, the figure 2 a second embodiment, Figure 3 shows a third embodiment, FIG. 4 shows a detail, FIG. 5 a fourth embodiment, the figure 6 a fifth Embodiment, Figure 7 shows a sixth embodiment, 8 shows a seventh embodiment, the Figure 9 an eighth embodiment, the figure 10 a Detail view, Figure 11 shows a ninth embodiment and FIG. 12 shows a tenth embodiment.

Description of the embodiments

The fuel supply system according to the invention for Metering of fuel for an internal combustion engine can at used different types of internal combustion engines become. The same applies to the invention Method for operating an internal combustion engine. The internal combustion engine is for example a gasoline engine with outer or internal mixture formation and spark ignition, wherein the Engine with a reciprocating piston (reciprocating engine) or with a rotatably mounted piston (Wankel piston engine) can be provided. The internal combustion engine can for example, be a hybrid engine. In this engine with charge stratification, the fuel-air mixture in the Area of the spark plug enriched so far that a safe ignition is guaranteed, combustion in the Medium but takes place in a strongly lean mixture.

The gas change in the combustion chamber of the internal combustion engine can for example, after the four-stroke process or after Two-stroke procedure done. For controlling the gas exchange in the Combustion chamber of the internal combustion engine can in a known manner Gas exchange valves (intake valves and exhaust valves) provided be. The internal combustion engine can be designed in such a way that at least one fuel valve directs the fuel injected into the combustion chamber of the internal combustion engine. The Control of the power of the internal combustion engine takes place preferably by controlling the combustion chamber supplied Amount of fuel. But it can also be provided that the fuel valve the fuel at the inlet valve to Stove combustion chamber. In this embodiment, the for the Combustion of the fuel supplied to the combustion chamber air usually controlled by a throttle. About the Position of the throttle may be that of the internal combustion engine to be delivered power to be controlled.

The internal combustion engine has, for example, a cylinder with a piston, or it can with multiple cylinders and be provided with a corresponding number of pistons. Preferably, one fuel valve per cylinder is provided.

To the extent of the description is not unnecessarily extensive to fail, the following is limited Description of the embodiments of a reciprocating engine with four cylinders as internal combustion engine, wherein the four fuel valves fuel, usually gasoline, Inject directly into the combustion chamber of the internal combustion engine. The performance of the internal combustion engine is over Control of the injected fuel quantity controlled. at Idle and (lower) partial load is a charge stratification with fuel enrichment in the area of the spark plug. Outside this range, the mixture is very lean. At full load or upper part load becomes a homogeneous distribution sought between fuel and air in the combustion chamber.

1 shows a fuel tank 2, a suction line 4, a first fuel pump 6, a pressure relief valve 7, an electric motor 8, a fuel connection 10, a second fuel pump 12, a pressure line 14, four fuel valves 16 and a control device 20. The fuel valves 16 are In professional circles often referred to as injectors or injectors.

The first fuel pump 6 has a pressure side 6h and a suction side 6n. The second fuel pump 12 has a High pressure side 12h and a low pressure side 12n. The fuel connection 10 leads from the pressure side 6h of the first Fuel pump 6 to the low pressure side 12n of the second Fuel pump 12. From the pressure side 6h of the first fuel pump 6 leads a channel back into the fuel tank 2. In this channel is the pressure relief valve 7th intended.

From the fuel connection 10 branches a fuel line 22 off. Via the fuel line 22 can fuel from the fuel connection 10 in the fuel tank 2 be returned. In the course of the fuel connection 10, between the first fuel pump 6 and the second fuel pump 12, there is a filter 24th

In the fuel line 22 is a pressure regulating valve 26 and a shut-off valve 30 is provided. The pressure regulating valve 26 and the shut-off valve 30 are effective behind each other connected. That is, the pressure regulating valve 26 and the shut-off valve 30 are in circuit series. The Pressure control valve 26 and the valve device 30 can also compactly realized together in a common housing be.

The shut-off valve 30 has a first switching position 30 a and a second shift position 30b. In the first switching position 30a may fuel from the fuel connection 10 through the fuel line 22 via the pressure regulating valve 26 in the Fuel tank 2 flow. In this switching position determines the pressure control valve 26 immediately the Feed pressure of the fuel in the fuel connection 10. The check valve 30 is in its second switching position 30b, then the fuel can not go out immediately the fuel connection 10 to the pressure control valve 26 flow.

The first fuel pump 6 is driven by the electric motor 8 driven. The first fuel pump 6, the pressure relief valve 7, the electric motor 8, the filter 24, the pressure control valve 26 and the shut-off valve 30 are in the area of the fuel tank 2. These parts are preferably arranged outside of the fuel tank 2 or are inside the fuel tank Second

Via mechanical transmission means 12m is the second Fuel pump 12 mechanically with an output shaft of a symbolically represented internal combustion engine 32 coupled. The camshaft of the engine 32 serves as Output shaft. Since the second fuel pump 12 mechanically coupled to the output shaft of the internal combustion engine 32 is the second fuel pump 12 is proportional to Speed of the output shaft of the engine 32nd Weil the second fuel pump 12 spatially close to the housing the internal combustion engine 32 is flanged, is a strong Heating the internal combustion engine 32 to the second fuel pump 12 transmit, which is a relatively high heat load of the fuel in the fuel supply system caused.

The from the second fuel pump 12 to the fuel valves 16 leading pressure line 14 can simplify be divided into a line section 42, a Storage space 44 and into several distribution lines 46th Die Fuel valves 16 are each a distribution line 46 at the memory space 44 is connected. A pressure sensor 48 is on connected to the memory space 44 and senses the respective pressure of the fuel in the pressure line 14th According to this pressure, the pressure sensor 48 inputs electrical signal to the controller 20.

To the storage space 44 of the pressure line 14 is a through the Control device 20 electrically controllable control valve 50 connected. Depending on the control of the control valve 50 Fuel is from the pressure line 14 via a circulation line 52 on the low pressure side 12n of the second fuel pump 12 headed. Between the control valve 50 and the Low pressure side 12n is a hydraulic resistance element arranged. The resistance element is a check valve 53, which is towards the fuel connection 10 already opens at very low pressure difference.

The first fuel pump 6 is, for example about a driven by the electric motor 8 positive displacement pump, the type of construction per revolution a certain amount Fuel promotes. The pressure of the fuel on the pressure side 6h of the first fuel pump 6 is hereinafter referred to as Supply pressure called. With the shut-off valve 30 open the pressure regulating valve 26, the height of the feed pressure in the fuel connection 10. The pressure regulating valve 26 is For example, set to a differential pressure of 3 bar. So is the feed pressure in the fuel connection 10 with open shut-off valve 30 three bar (3 bar).

A purge line 60 leads from the second fuel pump 12 in the fuel tank 2. Inside the pump housing 12g is the purge line 60 with the low pressure side 12n of the fuel pump 12, as in FIG. 4 recognizable. In the course of the purge line 60 there is a hydraulic resistance. The hydraulic resistance is formed by a first overflow valve 61 and a second overflow valve 62. In the course of the circulation line 52nd there is a branch 63. At the junction 63 branches the Purge line 60 from the circulation line 52 from. When in the Figure 1 shown, particularly advantageous and therefore Preferably selected embodiment opens the purge line 60 at a junction 64 between the shut-off valve 30 and the pressure regulating valve 26 in the fuel line 22nd The first spill valve 61 is at a relatively low Differential pressure, preferably set to 1 bar. Also the second spill valve 62 is at a relative low differential pressure, preferably set to 1 bar. Because the set differential pressure at the two Overflow valves 61, 62 each chosen rather low can be for the overflow valves 61, 62 advantageously a fairly easy to build design be chosen without causing thereby large variations would result in the set differential pressure.

The first fuel pump 6 usually conveys a little more Fuel in the fuel connection 10 than from the second fuel pump 12 from the fuel connection 10th is removed. In normal operating condition of the flows excess fuel through the normally open Shut-off valve 30 and through the pressure regulating valve 26, so that in the fuel connection 10 due to the Differential pressure at the pressure control valve 26 adjusting feed pressure results.

If a sensor 65 determines that a particularly high Temperature prevails, then a corresponding signal the controller 20 is supplied. The control device 20 then switches the shut-off valve 30 in the second switch position 30b, in which the direct connection of the fuel connection 10 is interrupted to the pressure control valve 26 is. With closed shut-off valve 30 flows excess, from the second fuel pump 12 from the Fuel connection 10 Unpicked fuel the pump housing 12g of the second fuel pump 12, through the first overflow valve 61, through the second overflow valve 62 and through the pressure regulating valve 26 back into the Fuel tank 2. This results in closed Shut-off valve 30 in the fuel connection 10th a feed pressure, which is the sum of the differential pressures of Valves 61, 62 and 26 corresponds. In the selected embodiment is the pressure relief valve 7, for example set to a pressure higher than the sum of the Differential pressures of the valves 61, 62 and 26th

Because the purge line 60 through the pump housing 12g of second fuel pump 12 can, by the through the Flush line 60 flowing fuel heat energy from the second fuel pump 12 are discharged, whereby one to high temperature of the fuel in the area of the fuel connection 10 and in the region of the second fuel pump 12 is avoided. This causes the feed pressure in the fuel connection 10 with closed shut-off valve 30 higher is considered to be the feed pressure in normal operating condition Internal combustion engine 32, it is ensured that also one unusually high temperature does not cause gas bubbles in the Fuel connection 10 leads, which also at high Heat load no deterioration of the efficiency of the Fuel pump 12 must be feared. Because the increased Supply pressure only at fairly high temperature, so usually only a relatively short time, is set, this does not give a noticeable reduction in the durability of the relatively inexpensive producible first fuel pump. 6

Because of the second fuel pump 12 in the pressure line 14 excess amount delivered by the fuel valves 16 is not removed, and that of the Control valve 50 is shut down from the storage space 44, via the circulation line 52 through the check valve 53rd directly to the low pressure side 12n of the second fuel pump 12 will be unnecessary ways for the circulation of the fuel avoided and in normal operating condition the internal combustion engine is out of the range of Pressure line 14 no heated fuel in the fuel tank 2 led, which at normal Operating temperature of the internal combustion engine 32 an unnecessary Heating of the fuel in the fuel tank 2 is avoided.

The fuel pump 12 has a dashed line in the drawing Lines indicated pump housing 12g. The Overflow valves 61, 62, the check valve 53, the branch 63 and the sensor 65 are preferably within the pump housing 12g provided.

The sensor 65 is for example a temperature sensor and he can, for example, directly in the pump housing 12g or in Be arranged region of the pressure line 14. To measure the Temperature can instead of the sensor 65, for example, too the water temperature of the cooling water of the internal combustion engine 32 are used.

FIG. 2 shows a further, preferably selected, particularly advantageous exemplary embodiment.

In all figures are the same or equivalent parts with provided the same reference numerals. Unless otherwise stated mentioned or shown in the drawing is, this applies to one of the figures mentioned and Also shown in the other embodiments. Unless otherwise stated in the explanations, are the details of the various embodiments combinable with each other.

In contrast to Figure 1, the purge line 60 is in the in 2 illustrated embodiment downstream behind the second overflow valve 62 directly into the fuel tank 2 led. To when the shut-off valve is closed 30 to obtain an equal charge pressure, As explained with reference to Figure 1, the differential pressure of the second spill valve 62 not to, for example, 1 bar as in the first embodiment, but for example set to 5 bar.

In the embodiments shown in Figures 1 and 2 is an intermediate piece of the purge line 60 between the first spill valve 61 and the second spill valve 62 brought together with an intermediate piece of Circulation line 52 between the control valve 50 and the check valve 53. This will effectively flush both the fuel connection 10 and the housing 12 g of the second fuel pump 12 and a purge and thus achieved a heat dissipation from the circulation line 52.

FIG. 3 shows a further, preferred, selected, particularly advantageous exemplary embodiment.

In the embodiment shown in Figure 3 passes the fuel from the low pressure side 12n of the fuel pump 12, via a spill valve 66, through the purge line 60 and via the pressure control valve 26 in the fuel tank 2. The overflow valve 66 forms a hydraulic resistance in the purge line 60.

In contrast to those shown in Figures 1 and 2 Embodiments is the purge line 60 in FIG downstream behind the spill valve 66 is not with the Circulation line 52 merged. This gives you the Advantage that fewer valves are required. Nevertheless is also in the embodiment shown in Figure 3 at least one indirect ventilation of the circulation line 52 via the check valve 53, via the low pressure side 12n of the fuel pump 12 and the purge line 60 possible with the overflow valve 66.

To in the embodiment shown in the figure 3 to obtain the same pressure conditions as in the With reference to Figures 1 and 2 explained embodiments, In FIG. 3, the differential pressure of the Overflow valve 66, for example, set to 2 bar.

In the embodiments illustrated in Figures 1 to 3 can in principle on the pressure relief valve. 7 be waived. However, it is also suggested at these embodiments, the pressure relief valve 7 as Protection with possibly clogged filter 24 anyway provided.

FIG. 4 shows a longitudinal section through the second fuel pump 12.

The fuel pump 12 has at least one pump piston 12p. Preferably, the fuel pump 12 has three pump pistons 12p, for the sake of clarity only one is shown. The fuel passes over the Fuel connection 10 in the interior of the pump housing 12g. In the pump housing 12g is the low pressure side 12n and the at least one pump piston 12p. The pump piston 12p is thus surrounded by the fuel, wherein the fuel has the same feed pressure as in the fuel connection 10. At the highest point of the interior of the housing 12g of the fuel pump 12 branches off the purge line 60. This will ensure that is at the highest point in the pump housing 12g accumulating air through the purge line 60 is discharged to the fuel tank 2.

FIG. 5 shows a further, preferably selected, particularly advantageous exemplary embodiment.

Immediately downstream of the first fuel pump. 6 branches on the pressure side 6h of the fuel pump 6 in the fuel tank 2 leading channel. Within of the channel there is the pressure relief valve 7. The pressure relief valve For example, 7 is set to 8 bar. The pressure relief valve 7 is located, viewed in the flow direction, even before the filter 24 to make sure a blockage at any point to no impermissible Overpressure in the fuel pump 6 leads.

Between the control valve 50 and the check valve 53rd there is the branch 63, at which the purge line 60th branches off from the circulation line 52. In the course of the flushing line 60, a hydraulic resistance is provided. Of the Hydraulic resistance is formed by a throttle 70.

The check valve 53 has a biasing spring. The preload pressure the check valve 53 is on the flow resistance the throttle 70 is tuned, in such a way that too when the shut-off valve 30 is in its open switching position 30a, from the circulation line 52 is constantly one desired amount of fuel through the purge line 60 and through the pressure control valve 26 to the fuel tank 2 flows.

When the shut-off valve 30 in its closed position 30b, then flows from the first fuel pump 6 funded, but from the fuel valves 16 not removed excess fuel through the pressure relief valve 7 in the fuel tank 2, and a Part of the excess fuel delivered flows through the throttle 70 and through the pressure control valve 26 to the fuel tank 2. Because the pressure on the pressure relief valve 7 is set higher than the differential pressure at the pressure control valve 26 and because the flowing through the purge line 60 Fuel is additionally accumulated at the throttle 70, results in the fuel connection 10 when closed Shut-off valve 30, a feed pressure which is significantly higher than in normal operating condition with the shut-off valve open 30 occurring feed pressure. This achieves a reliable Compression possibly in the fuel connection 10 or in the fuel pump 12 occurring gas bubbles, and a purging of a portion of the fuel is accomplished the circulation line 52 back to the fuel tank. 2 This will cause an additional discharge of unwanted, in the fuel supply system occurring heat energy reached. By adjusting the bias pressure of the check valve 53 via the spring, the proportion of fuel, the directly from the circulation line 52 to the low pressure side 12n of the fuel pump 12 flows and by the Purge line 60 back to the fuel tank 2 flowing proportion of fuel matched become.

In the embodiment shown in FIG choke 70 ensures that a certain proportion of the Fuel, this proportion being set accordingly Bias be selected at the check valve 53 can, even in normal operation constantly from the circulation line 52nd is returned to the fuel tank 2.

FIG. 6 shows a further, preferably selected, particularly advantageous exemplary embodiment.

In a departure from FIG. 5, in the case of that shown in FIG Embodiment of the hydraulic resistance in the purge line 60 of one provided in the purge line 60 Overflow valve 72 is formed. The overflow valve 72 is For example, set it to a pending Differential pressure of 2 bar opens. The check valve 53 is set so that, for example, already at very low differential pressure opens. This ensures that in the normal operating state of the fuel supply system, that is, when the check valve 30 in its open Shift position 30a is the feed pressure in the fuel connection 10 is determined by the pressure control valve 26, and the funded by the second fuel pump 12 and not by the fuel valves 16 removed fuel flows short ways from the high pressure side 12h via the control valve 50, through the circulation line 52 and the check valve 53 on the low pressure side 12n of the fuel pump 12th The prestressed overflow valve 72 ensures that no fuel from the circulation line 52 to the fuel tank 2 flows back. This ensures that in the normal operating state of the fuel supply system the temperature of the fuel in the fuel tank 2 is kept as low as possible.

In order to achieve a rinse, the check valve 30 is in the closed switch position 30b connected. This increases the feed pressure in the fuel connection 10 to a maximum to the pressure set at the pressure relief valve 7, and due This increased feed pressure will be the preload pressure of the Overflow valve 72 exceeded, and it flows fuel from the circulation line 52, via the overflow valve 72 and via the pressure control valve 26 in the fuel tank Second

FIG. 7 shows a further, preferably selected, particularly advantageous exemplary embodiment.

Deviating from the embodiment shown in FIG has the symbolically reproduced in the figure 7 Embodiment in the course of the circulation line 52 a another hydraulic resistance element. The further Resistor element is a throttle 74. The throttle 74 is hydraulically in series with the check valve 53. Viewed in the flow direction, the throttle can 74 in front of or behind the check valve 53. The Throttle 74 and the check valve 53 are located downstream flow downstream of the branch 63 to Purge line 60.

With the throttle 74 can be achieved that, if at higher Speed of the engine 32 is a relatively large amount is pumped to fuel in the circulation line 52, before the throttle 74 creates a dynamic pressure and if this back pressure is large enough to the biased spill valve 72nd to overcome at least a portion of that of the second Fuel pump 12 pumped fuel into the fuel tank 2 flows back.

The embodiment shown in Figure 7 can thus Be agreed that at higher speed of the internal combustion engine 32 a part of the fuel from the circulation line 52 flows back into the fuel tank 2, without that by switching the shut-off valve 30 in his closed switching position 30b in the fuel connection 10 an increased feed pressure must be set. this has the advantage that at increased speed of the internal combustion engine 32, which can often occur depending on the driving style, the first fuel pump 6 is not raised Supply pressure must work, what their durability clearly elevated. In the embodiment of Figure 7 must the shut-off valve 30 only briefly, for example, only for Rinse the fuel lines during the start of the Internal combustion engine 32, in the closed switching position 30b are switched, which means that the fuel pump 6 only rarely corresponding to an increased feed pressure must work, what the durability of the fuel pump 6 significantly extended.

FIG. 8 shows a further, preferably selected, particularly advantageous exemplary embodiment.

In the embodiment shown in FIG the throttle 74 and the check valve 53 are in History of the circulation line 52 hydraulically behind the branch 63, at which the purge line 60 from the circulation line 52 branches off. Hydraulically considered are the throttle 74 and the check valve 53 parallel to each other. The check valve 53 is provided with a closing spring biased. The check valve 53 opens only when due to a relatively high pressure medium flow at the Throttle 74 a sufficient for the opening of the check valve 53 large differential pressure is pending. The check valve 53 thus limits the pressure drop across the throttle 74.

Hydraulically downstream behind the junction 63rd is in the purge line 60 an additional hydraulic Resistance provided. The additional hydraulic resistance is formed by a throttle 76. The throttle 76 is hydraulically in series with the overflow valve 72 in front of or behind the overflow valve 72.

By tuning the chokes 74 and 76 as well as the biasing pressures the check valve 53 and the spill valve 72nd can through the purge line 60 to the fuel tank 2 flowing fuel flow and the over the Circulation line 52 to the low pressure side 12n of the fuel pump 12 flowing fuel flow matched become. It can also be determined from which speed the engine 32 is a part of the by the circulation line 52 flowing fuel flow through the purge line 60 flows back to the fuel tank 2.

FIG. 9 shows a further, preferably selected, particularly advantageous exemplary embodiment.

FIG. 10 shows a detailed view of the exemplary embodiments illustrated in FIGS. 9, 11 and 12.

In the embodiment shown in Figures 9 and 10 the second fuel pump 12 has a pump piston 12p, an input-side check valve 12a, a output side check valve 12b, a compression space 12k and a control valve 50 '.

To the fuel connection 10 is a pressure damper 78th connected. The pressure damper 78 is preferably located within the pump housing 12g. In the course of Circulation line 52 ', there is a hydraulic resistance element. The resistance element is a check valve 80, that opens towards the fuel connection 10. At a Orifice 82 opens the circulation line 52 'in the fuel connection 10. The circulation line 52 'leads from the Compression space 12k, through the control valve 50 ', over the Branch 63 ', through the check valve 80 and over the Intersection 82 in the fuel connection 10. The circulation line 52 'runs a short distance directly inside of the pump housing 12g. The control valve 50 'has an open Switch position 50'a and a closed switching position 50'b. At between the control valve 50 'and the check valve 80 provided branch 63 'branches the purge line 60 off. Downstream past the branch 63 ' the purge line 60 a hydraulic resistance. Of the Hydraulic resistance is formed by a choke 84.

From the fuel connection 10 leads a line 86 in the Area of the piston guide of the piston 12p. The over the Line 86 of the piston guide supplied feed pressure ensures for a reduction of friction in the area of Piston guide.

From the area of the compression chamber 12k facing away End of the pump piston 12p introduces a leakage line 88 in the fuel line 22. Downstream of the pressure control valve 26 is in the fuel line 22 a second shut-off valve 90. The second shut-off valve 90 has an open switch position 90a and a closed switch position 90b. The leakage line 88 opens between the Pressure control valve 26 and the second shut-off valve 90 at a junction 92 in the fuel line 22nd

During a suction stroke, that is, while the pump piston 12p moves down while the compression chamber 12k increases, the fuel flows from the fuel connection 10 through the input-side check valve 12a in the compression space 12k. During a print stroke, that is called while the pump piston 12p moves upward and thereby reduces the compression space 12k, presses the Pump piston 12p the fuel from the compression chamber 12k via the output-side check valve 12b in the Storage space 44 of the pressure line 14, provided the control valve 50 'is in its closed position 50'b. It is possible to control the control valve 50 'so that it during a part of the pressure stroke of the pump piston 12p in the open switch position 50'a is. While the control valve 50 'during the compression stroke in the open position 50'a, the fuel is due to the normally high pressure in the pressure line 14 over the open control valve 50 'through the circulation line 52' and over the check valve 80 in the fuel connection 10th promoted. The throttle 84 and the preloaded check valve 80 can be so coordinated that if during the compression stroke, the control valve 50 'is open, a Part of the fuel flowing through the circulation line 52 ' through the purge line 60 and via the pressure control valve 26 in the fuel tank 2 flows back.

By appropriate, depending on the stroke of the pump piston 12p Switching the control valve 50 'in the switching positions 50'a or 50'b can be that of the second fuel pump 12 in the pressure line 14 funded amount of fuel to be controlled. By appropriate activation of the Control valve 50 ', the of the fuel pump 12 in the Pressure line 14 conveyed amount to be controlled so that in the pressure line 14 of the respective desired high pressure prevails, which can be sensed by the pressure sensor 48. Depending on the pressure detected by the pressure sensor 48 the control valve 50 'is controlled.

From the pressure line 14 to the storage space 44 performs a Return line 94 into the fuel connection 10. In the return line 94, there is a pressure relief valve 96. The pressure relief valve 96 is provided, so that even at a Occurrence of an error, for example in the event of a fault Working the control valve 50 ', in the pressure line 14 no dangerous overpressure can occur. The pressure relief valve 96 may also be electrically controllable, and so on, that depending on the operating condition of the pressure in the Storage space 44 can be quickly reduced.

When the shut-off valve 30 in its open position 30a, then flows, as the throttle 84 and the pressure difference of the check valve 80 to each other are tuned, for example, only a very small part of the fuel flow passing through the circulation line 52 ' via the purge line 60 in the fuel tank. 2 The usually larger fuel flow flows through the Check valve 80 in the fuel connection 10, where the Pressure damper 78 is provided to the pulsating incoming Caching fuel.

When the shut-off valve 30 in its closed position 30b, then determines the pressure relief valve 7 the Feed pressure in the fuel connection 10. Because the pressure relief valve 7 to a higher pressure than the pressure control valve 26 is set, the feed pressure is closed Shut-off valve 30 higher than when the shut-off valve is open 30. When switch position 30b of the closed Shut-off valve 30 flows out of the compression chamber 12k by the control valve 50 'flowing fuel flow in Essentially through the throttle 84, through the purge line 60th in the fuel line 22 and from there into the fuel tank Second

While the engine 32 is operating, the second is Shut-off valve 90 usually in its open position 90a. If the engine 32 is turned off, then the second shut-off valve 90 is in its closed Switched position 90b, thereby a premature pressure reduction in the low pressure system across the gap between the pump piston 12p and the pump housing 12g avoid.

FIG. 11 shows a further, preferably selected, particularly advantageous exemplary embodiment.

In contrast to the embodiment shown in FIG becomes in the embodiment shown in FIG the leakage line 88 without sharing the fuel line 22 in the fuel tank 2 led. In the course of the leakage line 88 is the Shut-off valve 90 is provided. Because through the leakage line 88 only a very small amount of the fuel flows, the many times smaller than the one through the fuel line 22 flowing fuel is sufficient for the shut-off valve 90 a very small and very easy to make Valve.

FIG. 12 shows a further, preferably selected, particularly advantageous exemplary embodiment.

In the embodiment shown in FIG is in the fuel line 22, in the flow direction considered, the shut-off valve 30 downstream of the Pressure control valve 26 is arranged. At a junction 63 '' the purge line 60 branches out of the fuel connection 10 from. Downstream of the throttle 84, the leakage line opens 88 in the purge line 60 a. The junction 64, on the purge line 60 in the fuel line 22nd opens, is between the pressure control valve 26 and the Shut-off valve 30 is provided.

The control valve 50 'is via the circulation line 52' and over the junction 82 is connected to the fuel connection 10. During the intake stroke of the fuel pump 10, the fuel with open control valve 50 'not only by the input-side check valve 12a, but in addition also by the control valve 50 'in the compression chamber 12k flow. During the pressure stroke of the fuel pump 12th the control valve 50 'is in the closed Switch position 50'b held up in the pressure line 14 of the each desired pressure is reached.

In the figure 12 are two dotted lines 98r and 98f drawn. Usually the left of the dotted line 98r components shown in the rear area of the motor vehicle, and the right of the dot-dash line 98f illustrated components are usually located in the front of the vehicle.

Usually, to those in the rear area and the connecting components arranged in the front area, put pretty long lines for the fuel become. For this reason, one strives to increase the number of Lines between the rear area and the front area keep as small as possible. How to get the figure 12 may be sufficient in the preferred embodiment selected for hydraulic connection of the components the rear area with the components of the front area advantageously, the fuel connection 10 and the purge line 60th

To facilitate a restart of the engine 32, when the engine 32 at a relatively high temperature the following procedure is proposed: Turning off the engine 32 is still open Shut-off valve 30 over a predetermined period of time, the may be temperature dependent, the first fuel pump 6 continued to operate. This will turn off the area of the second fuel pump 12 and out of the Area of the fuel connection 10 and the pressure accumulator 78th accumulating heat energy through the purge line 60 in the Fuel tank 2 discharged. This reduces the Danger of undesired gas bubble formation in the fuel lines. In addition, it can be provided that, after the flushing of the fuel connection 10, just before parking the electrically driven fuel pump 6, the Shut-off valve 30 in its closed switching position 30b is switched. This increases the pressure in the fuel connection 10 and in the pressure damper 78 on the pressure relief valve 7 certain feed pressure, which is higher than that with open shut-off valve 30 from the pressure control valve 26th certain feed pressure. This ensures that at shut off internal combustion engine in the pressure damper 78 a increased pressure prevails, what the subsequent start of the Internal combustion engine 32, even at high temperature essential facilitated.

The embodiments shown in FIGS. 1 to 8 become used especially when the second fuel pump 12 several pump piston 12p, usually three pump piston 12p, has. The embodiments shown in Figures 9 to 12 are used in particular when the second fuel pump 12 a single pump piston 12p having.

Claims (14)

1. Fuel supply system for delivering fuel for an internal combustion engine, having a fuel reservoir vessel (2), a first fuel pump (6), a second fuel pump (12) and having at least one fuel valve (16), where the first fuel pump (6) feeds the fuel from the fuel reservoir vessel (2) into a fuel connection (10), and the second fuel pump (12) feeds the fuel from the fuel connection (10) via a pressure line (14, 42, 44) to the fuel valve (16) via which the fuel passes at least indirectly into a combustion chamber of the internal combustion engine, having a fuel line (22) which leads out of the fuel connection (10) to the fuel reservoir vessel (2), and having a pressure regulating valve (26) in the fuel line (22), where a shut-off valve (30) is provided in the fuel line (22), hydraulically in series with the pressure regulating valve (26), and a scavenging line (60) which conducts the fuel at least partially through the second fuel pump (12) and through a hydraulic resistor (61, 62, 66, 70, 72, 76, 84) to the fuel reservoir vessel (2) is provided, characterized in that the scavenging line (60) is led through a pump housing (12g) of the second fuel pump (12).
2. Fuel supply system according to Claim 1, characterized in that the shut-off valve (30) is controlled as a function of temperature.
3. Fuel supply system according to one of the preceding claims, characterized in that the hydraulic resistor (61, 62, 66, 70, 72, 76, 84) is formed by a valve (61, 62, 66, 72) which opens as a function of pressure.
4. Fuel supply system according to one of the preceding claims, characterized in that the hydraulic resistor (61, 62, 66, 70, 72, 76, 84) is formed by a valve (70, 76, 84) which has a through-flow resistance which is dependant on the fluid stream flowing through.
5. Fuel supply system according to one of the preceding claims, characterized in that the scavenging line (60) opens into the fuel line (22) hydraulically between the shut-off valve (30) and the pressure-regulating valve (26).
6. Fuel supply system according to one of the preceding claims, characterized in that an excess pressure valve (7) is provided hydraulically in parallel with the pressure-regulating valve (26).
7. Fuel supply system according to one of the preceding claims, characterized in that a circulation line (52, 52') which leads from the pressure line (14, 42, 44) into the fuel connection (10) via a control valve (50, 50') is provided, and in that the scavenging line (60) branches off from the circulation line (52, 52').
8. Fuel supply system according to Claim 7, characterized in that the circulation line (52, 52') leads into the fuel connection (10) via a resistor element (53, 74, 80).
9. Fuel supply system according to Claim 7 or 8, characterized in that the circulation line (52, 52') leads into the fuel connection (10) via a non-return valve (53, 80).
10. Fuel supply system according to Claim 9, characterized in that a throttle (74) is provided hydraulically in parallel with the non-return valve (53).
11. Fuel supply system according to Claim 1, characterized in that the scavenging line (60) branches off from the pump housing (12g) at the highest point of the low-pressure side (12n) of the second fuel pump (12).
12. Fuel supply system according to Claim 7, characterized in that the second fuel pump (12) has a compression space (12k), and the circulation line (52') leads out of the compression space (12k).
13. Fuel supply system according to one of the preceding claims, characterized in that a leakage line (88) which leads from the second fuel pump (12) into the fuel reservoir vessel (2) is provided.
14. Fuel supply system according to Claim 13, characterized in that the leakage line (88) opens into the fuel line (22) upstream of the shut-off valve (30).

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