DE2300194C3 - Fuel supply device for an internal combustion engine - Google Patents

Description

The invention relates to a fuel supply device, its inlet with a fuel supply and its Outlet connected to an internal combustion engine

is, with a first variable speed pump, which is connected to the inlet and conveys in an intermediate stage, and with at least two in parallel connected between the intermediate stage and the outlet, working at constant speed further

Pumps, at least one of which has a valve-controlled bypass that is controlled by the For derserte this further pump leads to the intermediate stage.

In aircraft fuel supply systems is

it is often necessary to deliver the fuel in variable flow rates and at different operating pressures. To make this possible, wise in aircraft, the fuel supply devices normally have two or more pumps. the parallel are switched. These fuel supply devices generally have a feed pump. the on Fuel container or is arranged in the vicinity of the fuel container and the one under pressure Fuel flow generated, which is led to an intermediate stage, this intermediate stage being the parallel switched pumps.

Since it is necessary that the output of the pumps downstream of the intermediate stage in a further Range, at certain times being in

close to the maximum capacity is worked at other times when the internal combustion engine is required is reduced, there is considerable overcapacity.

In these fuel supply devices, the feed pump is driven by the internal combustion engine and is usually a centrifugal pump, the speed of which is directly proportional to the speed of the internal combustion engine is. The pumps downstream of the intermediate stage, however, are usually positive displacement, Gear or vane pumps that work at a constant speed. For this reason, the delivery rate is which is available is generally constant. When the fuel requirement of the internal combustion engine becomes smaller, the fuel supply device does an unnecessary work. This work is not only a function of the delivery rate of the pumps but also of the pressure at the pump outlet pumped fuel is dispensed.

An adaptation to the different needs has therefore already been achieved in that high-pressure relief valves downstream of the pumps, these expansion valves being the Detect the presence of abnormally high pressure downstream of the pumps when fuel is needed the internal combustion engine is reduced. These valves open a bypass line into which part of the pumped fuel is supplied to an area which is upstream of the pumps. Although such

Fuel feeders up to a limited Extent of the necessary fuel flow changes are adapted, they can only do so by the expenditure of additional excessive work, In general, there must be a high pressure in the outlet of the pumps.

The additional work that acts on the fuel has the disadvantage that the temperature d-s is pumped Fuel increases As it is common to use the pumped fuel as a coolant for the oil of the Internal combustion engine to use by this fuel through the oil cooler of the internal combustion engine branches through, any unnecessary increase in temperature of the fuel reduces the efficiency.

Other fuel supply devices have externally acting controls with which one or several of the pumps are switched off. These fuel supply devices are, however, undesirable, Firstly, because they require an externally acting control of the pump, this control normally being electrical connections within the very dangerous fuel supply system make necessary. Second, these fuel devices are undesirable because of the shutdown one or more pumps allows the fuel supply devices by a Failure of the pump cannot be fully operated again if the fuel requirement increases. This can be extremely dangerous.

Many of these problems could be eliminated. if a low pressure exhaust line from a or several pumps are provided for the pumped fuel. The fact that a low pressure circulation is made possible, the amount of work done is reduced. So far, however, all attempts have to produce a low-pressure vent, for example by branching off the output of one or more the pumps at low pressure to an area upstream of the pumps, external control devices, with which a valve was opened. Such external controls are undesirable and require in general, the use of dangerous electrical connections and sensor fittings.

The invention is based on the object of the controller of the bypass to be designed so that under low pressure conditions or a diversion is achieved under certain pressure conditions, the control can be carried out using any selected operating parameters.

According to the invention this is achieved in that the valve is pressure balanced by its valve member Has throttle opening from the delivery side of this further pump to a normally closed Chamber leads, and the valve normally blocks a flow, but opens when a Pressure drop occurs at the throttle opening, wherein control members are provided, which on pressure differences respond between fuel pressures in at least three locations between the inlet and the Outlet of the fuel supply device can be established to form a drainage duct for the normally open closed chamber to generate a pressure drop at the throttle opening.

Any operating parameters used in the form of pressure differences at certain points of the fuel supply device in order to carry out a control, the control being entirely within the fuel supply device lies. There are no electrical connections or supply lines coming from outside used The bypass is advantageously a low-pressure bypass and this reduces the work which is done by the pump.

Valve-controlled bypasses in pumps are already known for fuel supply devices With the device shown in DT-AS 1190 758 a bypass is used to divert the pressures in a line upstream and downstream of a regulating element with variable To regulate average cross-section. DT-OS 1 963 830 describes a fuel supply device known in which the bypass line is controlled by a valve. The position of the valve in relation to the The valve seat is determined by the position of a baffle plate, which in turn is determined by a combined movement is set, namely by the movement of a lever and sensed operating conditions of the internal combustion engine, such as the temperature or speed. From US Pat. No. 2,740,469 there is one Fuel supply device known in which the bypass of the output of a pump to an intermediate stage is controlled by the pressure difference between two particular lines.

The invention is to be explained in the following description with reference to the figures of the drawing will. It shows

F i g. 1 is a schematic representation of a fuel supply device for an airplane,

Fig. 2 a section view of a pump housing and .

Fig. 3 is a schematic view of a modified one Embodiment of the fuel supply device. Fig. 1 shows schematically a representation for a Aircraft fuel supply system equipped with two pumps. Although only two pumps are shown in parallel, it should be noted that the Fuel supply device can be used in a plurality of pumps connected in parallel. at the in F i g. 1 shown fuel supply device 10, an inlet 11 is provided which is connected to a fuel tank can be connected. Furthermore, an outlet 12 is provided which leads to an internal combustion engine leads. A second inlet line 13 can return the fuel from there. Numerous pressure and temperature acceptance points, openings and valves 14 are also provided.

A main pump stage 15 is provided in which the parallel pumps 16 and 17 are located. It is a delivery stage pump 18 is provided, in which a feed pump 19 is located. The feed pump 19 is with the inlet 11 via a line 20 in connection. the Feed pump releases the pumped amount into a line 21, which is connected to a line via a control valve 22 23 is connected. This line is in turn connected to a line 24, which with an outer System 25, such as a heater or the like. Is connected. This heater 25 is single-line

26 connected, in turn to a pre-filter line

27 leads. A bypass 28, which is controlled by a pressure check valve 29, connects the line with the line 27. Via this line, the external device 25 is bypassed if it is blocked or closed should be. A filter unit 30 is arranged between the line 27 and a line 31, the is in turn connected to the intermediate stage 32. A bypass line 33 connects the line 27 to the intermediate stage 32 and is driven by a pressure check

controlled valve 34, whereby the filter 30 can be bypassed if this filter should be clogged.

If the feed pump 19 is not in operation or any of the lines 21 to 31 becomes blocked, connect a bypass 34a connects the inlet U via a check valve 35 to the intermediate stage 32. A line 38 can also connect the intermediate stage 32 to the inlet 13 via a check valve 39. The valves 29, 34, 35 and 39 are normal unidirectional valves commonly used in fuel supply directions are used. Normally, all of the fuel is used by the fuel supply device is fed through the inlet, fed to the feed pump 19 and then to the intermediate stage 32. The intermediate stage 32 is in communication with the lines 41 and 42, which lead to the inlets of the pumps 16 and 17 lead. The pumps 16 and 17 are in aircraft fuel supplies usually positive displacement, gear or vane pumps that operate at a constant speed. The feed pump 19 in of the delivery stage 18 is a centrifugal pump driven by the internal combustion engine. The one from the feed pump The amount of fuel dispensed is therefore a function of the engine speed. Even though it is shown that the two pumps 16 and 17 are essentially the same size, it should be noted that one of the two, for example the pump 16, can be a larger pump, which then acts as the main pump can be viewed while the other and smaller pump 17 is an auxiliary pump. The main pumping stage 15 is designed in such a way that it generates a sufficient amount of flow for the maximum demand. When the internal combustion engine is throttled, the main pump stage 15 carries the line 50 with the connected to outlet 12, a greater amount of fuel flow too al £ is required. The outlets of the pumps 16 and 17 are connected to lines 51 and 52 in connection, which are connected to the outlet line 50 via check valves 53 and 54. the Check valves 53 and 54 are normally spring loaded and positive pressure is required to to connect the lines 51 uod 52 with the Line 50 to open. At the same time, these check valves are used to prevent a return flow in the cases prevent where the pressure in line 50 is greater is than in each of lines 51 and 52.

In order to achieve relief within the line 50 when the demand of the internal combustion engine decreases, a high pressure relief valve 55 is provided, which connects the line 50 to a line located upstream of the pumps 16. 17, such as using the line 38, which leads to the intermediate stage 32. The connection is made by means of a line 56. The High pressure relief valve 55 is also a check valve which only allows flow from the Line 50 in line 38 allows.

The fuel supply device described so far is, with the exception of the control valve 22, in aircraft Known The invention will be described with reference to this fuel supply device. Be it however, notes that the invention is also adapted to most pumping systems employing parallel pumps can be.

If in the fuel supply device described above, the fuel requirement of Internal combustion engine decreases leads to the excess pump capacity in the main stage pump 15 either to greater flow through the system and backflow via auxiliary inlet 13 or into the in most cases to generate a greater pressure in the outlet line 50. The greater pressure in the line 50 opens valve 55 and this results in high pressure backflow. This means that the pressure in line 50 must be kept relatively high in order to open valve 55. In this case The pumps 16 and 17 connected in parallel do a considerable excess of work. But this will the temperature of the fuel is raised above the desired value.

To eliminate this problem, a bypass is provided which consists of lines 60 and 61 and which returns the output of pump 16 to the intermediate stage 32 branches off. Line 60 communicates with line 51 at the outlet end of pump 16 and in communication also to line 61, which in turn is connected to interstage line 32. Between the lines 60 and 61 a valve 63 is used, which controls the bypass line. The valve 63 closes normally the connection between the lines 60 and 61. So that the amount delivered by the pump 16 passes through valve 53 into line 50 and then reaches outlet 12.

The valve 63 is a pressure-balanced valve, which remains closed against a high pressure, while at the same time it is able to remain open to a low pressure. Since the valve is open, when it is exposed to a low pressure, the bypass lines 60 and 61 have a pressure that of the Intermediate level 32 is approximated. The branching off of the output quantity of the pump 16 takes place at one Low pressure and this causes the valve 53 to be closed, which ensures that the total flow rate the pump 16 is branched off. In this way, the size of the output from the pump 16 is increased useless work is reduced and the temperature rise of the fuel is kept to a minimum.

The valve 63 is controlled by sensors 70, 71 and 72, which cooperate to open a vent 74 connected to one side 75 of the pressure balanced Valve 63 is in communication. When the vent 74 is connected to the side 75 of the valve housing is the pressure compensation of the valve 63 is canceled and the valve opens. When the feelers 70, 71 and 72 are closed, the portion 75 of the valve housing of the valve 63 remains closed, and that Valve 63 also remains closed.

The sensors 70, 71 and 72 merely represent states within the fuel supply device itself namely between the inlet 11 and the outlet 12 fixed. There is no external influence on the feelers.

In a preferred embodiment, each of the sensors is a pressure-controlled valve which is an Ab has the section between the part 75 of the Vemilge housing and the exhaust line 74 is arranged. Dei Pressure acting on this valve section causes a passage through each of the sensors is opened by. When all three sensors are open, the section 75 of the valve housing with the Ab Zugsleitung 74 connected.

Like F i g. 1 shows the sensors can determine the speed of the internal combustion engine, the fuel pulp flow within the fuel supply device an auxiliary pump delivery pressure.

For example, the sensor 70 sets the delivery pressure the auxiliary pump 17 firmly, via a Druckfüh!

channel 75a, which extends from the line 52 downstream of the pump 17 to the sensor 70. This pressure is compared with the pressure in the line 61 via a pressure sensing line 76. When the valve 63 is closed, the pressure in the line 61 is the same as that in the intermediate stage 32. As long as the delivery pressure of the Auxiliary pump 17 is kept sufficiently high above the pressure of the intermediate stage, usually 21.0 kg / cm ² or 28.0 kg / cm ² , the sensor 70 remains open in order to establish a connection between the section 75 of the valve housing and the next sensor

71 to enable.

The sensor 71 determines the speed of the internal combustion engine, namely by the fact that the pressure between the inlet 11 via a sensing channel 78 to the outlet the feed pump 19 is compared, via the pressure sensing channel 79. The pressure sensing channel 78 conducts the pressure next to the inlet from, upstream of the feed pump 20. The pressure channel 79 conducts the Pressure that prevails downstream of the feed pump but upstream of the main pump stage 15. This is in FIG. 1 shown, and a sensing channel is provided between the sensor 71 and the line 61, in which there is normally a pressure which corresponds to that in the intermediate stage 32. As the feed pump 19 is a pump driven by the internal combustion engine, the delivery pressure of this pump is proportional to the speed of the internal combustion engine, and a comparison of the pressure between the inlet of the pump Ϊ9 and the outlet of the pump 19 indicates the speed of the internal combustion engine. If the speed of the Internal combustion engine is in the correct range, the sensor 71 opens, and there is a passage from Sensor 70 to sensor 72 open.

The sensor 72 has, as FIG. Figure 1 shows a drain section 72a on and further the control valve 22, with a mechanical connection between these illustrated by dashed line 80. The control valve 22 adjusts the internal flow between the feed pump 19 and the main pump stage 15 fixed. When the flow rate is small enough. What corresponds to a low demand, the sensor 72 opens a channel between the sensor 71 and the drain 74. If all three sensors are open, that will pressure balanced valve 63 unbalanced and opens to connect line 60 to line 61, and this results in the delivery rate of the pump 16 being diverted at low pressure.

The F i g. 2 and 3 show two exemplary embodiments of the valve 63 and the control sensors 70, 71 and 72. At the first embodiment shown in FIG. 2 is shown. the sensors 70 and 71 have manure slides. and the sensor 72 has a ball check valve. which is opened by a mechanical connection with the control valve 22. In the case of the in FIG. 3 shown Embodiment have the sensors 70, 71 and

72 movable membranes. who carry a needle valve, which opens and closes a drainage duct for the pressure balanced valve 63. It should be noted that These embodiments are only examples of an internal bypass control and that a larger or A smaller number of sensors can be used, with these sensors having other desired parameters can monitor.

Let that be done first in FIG. 2 embodiment shown bcispicl considered. F i g. Figure 2 is a sectional view of a portion of the pump housing containing the bypass valve and contains the sensor controls for this valve.

The pump housing 90 has a part of the line 21 which comes from the outlet of the feed pump and also the line 23, wherein the control valve 22 between these lines is used. The housing 90 also includes a portion of the conduit 60, which is in communication with the pump outlet and the bypass line 61, the pressure-balanced Valve 63 controls the connection between lines 60 and 61. The sensors 70 and 71 are designed to be axially movable Piston slide shown, while the sensor 72 from the control valve 22 and the ball check valve 193, which is arranged so that it can be actuated by the control valve 22. As shown, the valve 63 has a cup-shaped valve body 93. the one in a tubular Housing 94 is arranged. This tubular housing 94 has a passage 95 at one end, the with a flue% in connection. The cup-shaped valve body 93, which is inside the tubular Housing 94 is arranged, is biased by means of a spring 97 against a valve seat 98, which is on inner periphery of the housing 94 is formed. The bottom wall 99 of the cup-shaped valve member 93 closes against the valve seat 98, namely at the connection point with the line 60, around this line 60 block. Channels 100 in the tubular housing 94 open into a line 101, which is in connection with the bypass line 61 stands. These channels are located downstream of the valve seat 98. To the line 60 with the To connect the bypass line 61, the valve body 63 must be moved away from the valve seat 98, against the force of the spring 97.

The end wall 99 of the cup-shaped valve body 93 has a throttle bore 102. those with a Channel is connected, which opens into the line 60, through a filter 104. which a clogging of the narrow channel 103 and the throttle bore 102 prevented. Since the throttle bore 102 opens into the line 60, is the interior space 105 of the tubular housing 94. the one at the outer end by a closure plate 106 is complete. against which the spring 97 rests, and at the other end by the end wall 99 of the Valve body 93, subjected to an internal pressure, which is substantially equal to the pressure in line 60 through the tapping connection via the Throttle bore 102. As long as the exhaust duct 9t is blocked by the sensors 70, 71 and 72. is del Pressure in space 105 is equal to the pressure in line 60. The spring 97 therefore holds the valve body 93 ge against the valve seat 98, and thereby a ( Connection between the line 60 and the Bypaßlei treatment 61 prevented. A connection between the Space 105 and the bypass line 61 is through the seal seat from the valve body 93 against the inner!

Prevent circumference of the tubular housing 94 If, however, the exhaust duct 96 to Niederdruckbe rich is opened, what in this embodiment example a connection with the line 23 stroma! of the three sensors 70, 71 and 72 means that the pressure within the space 105 takes the value de Pressure within the line 23. where it is ur is the pressure that prevails upstream of the pump 1. The pressure in line 60 is then Reaching way greater than the pressure in space 10 'to overcome the spring preload and to ds Open valve 63 / u. This creates a connection between the line 60 and the bypass line 61 is hot gcsiclli. As long as the three feelers are open, wit

509 634/31

this operating state is maintained because the flues 95, 96 and 74 have a larger cross-section than the throttle bore 102.

As shown, the sensors 70 and 71 are piston valves which are inserted into the flue%. Everyone the slide has a cylindrical slide piston 109, 110, these in tubular housings 111, 112 are arranged. This tubular housing have openings 113 and 114 through which the Discharge duct 96 connected to the interior of the tubular housing upstream of the pistons 109 and 110 is. The slides have circumferential grooves 116 and 117 on, and the tubular housings have inside Circumferential grooves 118, 119 which are connected to outlet openings 120, 122 downstream of the slide piston. The outlet openings 120, 122 open into the section of the exhaust duct% downstream of the individual sensor controls. When the spool 109, 110 is moved axially, so that the inlet openings 113, 114 with the grooves 118, 119 are opened by the grooves 116, 117, then the discharge line 96 is through these sensors open through. Both spool pistons are moved by the pressure applied against the axial ends the piston 109, 110 acts. This pressure is compensated by springs 130,13t, which act against one of the axial Act on ends of the pistons.

In the sensor control 71, which determines the speed of the internal combustion engines as a function of the difference between the feed pump inlet pressure and the feed pump inlet pressure, one axial end of the tubular housing 111 is connected to the line 79, which in turn is connected to the line 21, whereby the pressure is downstream is determined by the feed pump. The other end of the housing is connected to the inlet of the fuel supply device via a conduit 78, and the inlet pressure is thereby determined. In this case, the spring 130 is arranged between a housing section 134 and the axial end 135, which is connected to the line 78. The pressure downstream of the feed pump, which is carried by the line 79, must be sufficiently greater than the pressure in front of the feed pump, which is carried by the line 78, in order to overcome the bias of the spring 130 and to axially up to the piston to move to a location in which the groove 116 is in communication with both the outlet 113 and the outlet 118-120. The spool 109 may be located within the tubular housing 111 at this point due to be passed, namely nu a position at which the groove 116. remains the m communication with the groove 118, not long is connected to the inlet 113th At this point the extraction channel is blocked again by the sensor control 71. The sensing control 71 is therefore digiich open to a medium pressure level. When the delivery pressure of the delivery pump is low. which indicates a low speed of the internal combustion engine, the slide 71 is closed by the action of the spring 130 and the inlet pressure 78, which act against the end 135 of the slide piston in order to press it up to a level at which the groove 116 is not in connection with the groove 118. When the delivery pressure of the delivery pump increases, the loading of the spring is overcome and the groove 116 is brought into communication with the groove 118, the dtc groove 116 remaining in communication with the inlet opening 113. In this operating position, the Abzugkanal 96 is opened by the control 71 through. if

the engine speed continues to increase takes and the delivery pressure of the delivery pump also increases, the spool 109 is on the sert the connection point with the opening 113 presses, and thereby the channel 76 is closed again by the controller 71. Through a dimensioning the grooves and the spool and the distances from each other and by adjusting the tension the springs, it is possible to control the control 71 in such a way

ίο notify that they are only within a desired Pressure range works, this pressure range indicating a desired speed of the internal combustion engine. For example, it is possible to adjust the spool in such a way that it falls below all speeds.

remains closed half 3000 to 3500 rpm and at all speeds above 4500 to 5000 rpm. Of the Sensor 71 prevents the bypass valve from being relieved, with the exception of a speed range of the internal combustion engine from about 3500 to 4500 rpm. Only in

The bypass valve 63 can be opened in this rotary range will. Alternatively, of course, the cooler can be designed to be below a given RPM remains open and closed above a given RPM, this RPM

is determined as a function of the delivery pressure of the delivery pump.

The sensor control 70 senses the output of the uncontrolled pump 17. For this purpose stands a End of the piston HO via line 76 with e.nem

jo channel lying in front of the pumps in connection, like for example with the line 21. Thereby the uruck before the uncontrolled pump 17 and the controlled Pump 16 detected. The other end 140 of the piston 110 is in connection with the line 75a.

manure connected to a line behind the pump, st. jr bulb such as the line 52 in c! Λ ^{em control} the spring 131 is employed the piston and the housing portion between the end 141, said end 141 to the Leii ^up is ⁷⁶ g> n connection. The pressure in the pipe 75a must therefore be sufficiently greater than the pressure in the pipe 76 in order to overcome the pretensioning of the spring 131. so that the piston can be moved to one point. . "Of the inlet opening 114 with the outlet

^ate ° opening is connected 122nd namely through an ent-Γ? ',?, ^Ubcrla PP ^u ng the grooves 117 and 119. The tnde 141i is dimensioned in relation to the housing end 143 on the line 76 such that. when the pressure is in

so., nd A ^ ⁷⁵ , ^{a sufficient} "d large, st. to overcome the spring 131" ^{and the D} ™ k .n of the line 76, the slide remains open, namely that «cn 4.». Fndc 141 rests against housing 143 to prevent further movement of the piston. That's why

«Tf h. ' ^{e Fuhlcrstcue} ™ g TO- other than the one shown-

* ^{e Fuhl} <™ control 71. only one open position and one closed position. The piston is attached to it

£ ^ ^erlSI V ^{Xial To reach a} sufficient distance to ^ ** '- ^{that the} connection between ¹¹⁷ ** «« * becomes πΐ. For all for ^g «i ^ Prechenden Pump. _{the ausrc} , -large smcL remains, the sensor 70 open. If im hon P ^F °; ^de _u ^rdruck «« «he pump falls below a given level, and z> var a certain large

6s tnn ^Cn t ^{CT e} ? P ^{NUT becomes the filer} »« escHov

Zh ? ? T ^{"mf0lge Clncs Ausfafls d} * r ^ P Pe I & Schehen or for other reasons, for example by a larger fuel consumption of Brennkraftmasch.nc. Resulting <iner large flow rate

_t «f

leads with low pressure from this pump.

The sensor 72 senses the fuel flow within the fuel supply device, in the illustrated embodiment before the main pump stage 15. The flow rate is sensed by a control valve 22 with a throttle. In the case of the in Fi g. 2, the flow takes place through the line 21 in the direction of the arrow 145, specifically against the control valve 22. The control valve has a valve body 146 with an H-shaped axial section. This valve body has a transverse wall 147. which closes off the tubular inner space 148, and a flow is prevented with the exception of that which passes through a throttle bore 149 in the transverse wall 147. Radial openings 150 are provided upstream of the transverse wall 147, and radial openings 151 are also provided downstream of the transverse wall 147. The circumference of the valve body 146 is in sealing contact with the wall 153 of the conduit in which this valve is arranged, with the exception of a groove 154 in the wall of the conduit. The groove 154 is long enough in the axial direction to connect the radial openings 150 with the radial openings 151 when the valve body is in a given position. The valve body 146 is axially movable in the line in order to shut off the connection between the groove 154 and the upstream openings 150. If this is the case, there is a flow through the line 21.23 only through the throttle bore 149. A spring 156 acts against the valve to urge it in such a direction that the connection between the openings 150 and the groove 154 is blocked . The spring force is overcome by the pressure of the fuel in the line 21, which acts against the transverse wall 147. Whenever the flow of fuel through line 21 is sufficiently large. the valve 22 remains open against the action of the spring 156. When the flow decreases, the valve closes and all flow is through the throttle bore 149. The spring 156 is dimensioned such that the pressure drop created in the throttle bore 149 of the transverse wall 147 is overcome at low flow rates around the valve 22 to press against the seat 158. As a result, the connection between the openings 150 and the groove 154 is blocked. As the flow increases, the pressure drop created by the orifice 149 in the bulkhead 147 increases. and the spring pressure is overcome. This opens the valve 22 in such a way that the openings 150 come into communication with the groove 154. By dimensioning the throttle bore 149 and the spring strength of the spring 156, the valve can be designed so that it remains closed for all flows below a certain value, such as 18.91 per minute, and remains open for all flow rates above this value 149 is dimensioned such that it can accommodate all flows below this point with a very small pressure drop. Therefore, the spring 156 can have a low spring force, with low pressures being required, for example on the order of 0.28 to 0.35 kg / cm ² . to open the valve / u. The valve does not prevent flow at full flow demand and does not interfere with very low flow rates.

The ball check valve! 93 is related to the Valve 22 is arranged in such a way that a lever arm 160 of the ball check valve engages with the valve body 146 whenever the valve 22 is in a closed position. In these cases the lever lifts 160 the ball 161 from the valve seat 162, against the pressure in the exhaust duct% and against the Action of a spring 194, and thereby the exhaust duct 96 is connected to the duct 74. If that Valve is fully open, there may be mechanical contact between the lever 160 and the valve body 146 does not occur and the kickback ball remains

ίο closed against valve seat 162. This will make the Drain channel 96 blocked. The sensor control 72, which consists of the control valve 22 and the ball check valve 193 exists, the channel 96 opens only during operating states with low flow rates, the can occur when the fuel consumption of the internal combustion engine decreases. The description above shows that in the case of FIG. 2 illustrated embodiment, the bypass control valve 63 only can then be opened when the sensor 70 detects that the speed of the internal combustion engine is within of a desired range is when the sensor 71 determines that the discharge from the pump is sufficient is great. to meet the needs of the internal combustion engine, and when the sensor 73 detects that the The engine's fuel consumption has decreased, resulting in a low fuel flow rate leads through line 21.

F i g. 3 schematically shows a further exemplary embodiment of the invention, in which the bypass valve 63 is controlled by a vent 74 which is blocked by a valve 200 attached to a valve seat 201 is present. The valve 200 is through three pressure sensing diaphragms 706.71 £> and 726 controlled.

The membranes 716 and 726 are arranged in a housing chamber 204 and divide the chamber into three spaces, a space 205 below the membrane 716, a space 206 above the membrane 726 and a space 207 between the two membranes. The space 205 under the membrane 716 is via a line 209 with the inlet 11 in front of the feed pump 19 in connection, so that the pressure in space 205 is equal to the Inlet pressure is. The space 207 is via a line 210 with the line 21 downstream of the feed pump 19 in connection, so that there is a pressure in the space 207 which is equal to the feed pump outlet pressure. The diaphragm 716 therefore senses the engine speed as a function of the increase in feed pump pressure away. A spring 212 is arranged in the space 20 and acts on the membrane 716. the one

thus has stop 213, and the spring pushes the membrane upwards until stop 213 rests against the underside of membrane 726. If the pressure increase at the feed pump is sufficiently large, the pressure in space 207 is sufficiently large than the pressure in space 205 and counteracts the force of the spring 212 and removes the influence of the stop 213 on the diaphragm 726. namely by the fact that the membrane 716 is pressed downwards. The VentH 290 is attached to the membrane 726. un <this valve moves with this, so that. if you moves diaphragm 726 up and down in the Kam mer 204, close the diaphragm 726, the valve 200 is moved and this lifts from the valve seat 201 and a this applies to the withdrawal duct 74 to open, and ζ. The diaphragm 72b is actuated as a function of the engine's fuel requirement. The engine's fuel requirement is operated as a function of the total new fuel inputs

23 OO194

The flow into the fuel supply device is determined by the fact that the pressure drop at a flow limiter Ri in the line 23 downstream of the feed pump 19 and upstream of the connection point of the line 210 to the line 21 is determined. The pressure downstream of the flow restriction A1 is fed to the space 206 via the line 216. If the fuel requirement of the internal combustion engine is lower, the pressure drop at the flow restriction Ri changes. The pressure difference at this flow restriction is measured by a line 210, which is upstream of This flow restriction branches off and is connected to the space 207 by a line 216 which is connected to a point downstream of the flow restriction Rl and leads to the space 206 Resistance to downward movement of the valve

The diaphragm 706 is disposed in the housing chamber 218 and attached to and moves with the valve 200. The membrane 706 divides the chamber 218 into spaces 219 and 220. The space 220 senses the pressure via a line 221 which is connected to the line 42 downstream of a flow restriction R1. The line 42 is in turn connected to the inlet of the pump 17. The space 219 senses the pressure in the intermediate stage 32 via a line 225, which also forms part of the flue 74 when the valve 200 is open. The membrane 706 senses the flow generated by the positive displacement pump 17 as a function of the pressure drop across the flow limiter Rl, which is the pressure difference between the pressure in the intermediate stage 32, which is discharged via a line 225, and the inlet pressure of the Pump 17 is sensed via line 221. A spring 230 acts against the diaphragm 706 in order to push it and the valve 200 upwards.

The seating of the valve 200 against the valve seat 201 is determined by the ratio of the fuel requirement of the internal combustion engine, measured by the pressure drop at the flow limiter R \ and the pump outlet, which is determined by the pressure drop at the flow limiter R2 , this quantity being applied to the diaphragms 72b and 706 act. If the pressure drop at the flow limiter A1 is greater than the pressure drop at the flow limiter Rl, the forces of the membrane 72i> the forces of the membrane 706 and become effective in conjunction with the spring 230 in order to close the valve 200 against the valve seat 201 bring. This is always the case when the fuel requirement of the internal combustion engine is sufficiently large relative to the delivery capacity of the pump 17. However, if the fuel requirement of the internal combustion engine drops and the delivery rate from both pumps 16 and 17 is branched off via the overflow valve 55 and line 56 at high pressure in the intermediate stage 32, the pressures that are effective are around the valve 200 against the valve seat

201 to keep decreased. If the fuel requirement of the internal combustion engine continues to drop, the pressure drop changes at the flow restriction R \, which measures the total flow or the actual pump throughput, and at the flow restriction Rl, which measures the flow generated by the pump 17, and this change takes place in this way long takes place until the pressure drop at the flow restriction Rl exceeds the pressure drop at the flow restriction A1 by a predetermined value At this point in time, when there is a greater pressure in space 219 than in space 220 and at which there is a small pressure difference between spaces 206 and 207 is present, the pressure difference generated by the flow restriction R2 is effective to exert a downward force on the diaphragm 706, whereby the pressure difference at the flow restriction Rl , which acts on the diaphragm 726 upward, is overcome, whereby the force is also overcome the spring 230 is overcome, which acts upwards and the valve 200 is of his seat 201 lifted. When this occurs, a drain from space 235 behind the end wall 236 of the bypass valve 53 is opened. This space can then be relieved via the exhaust duct 74 and the line 225. The relatively high pressure in the line 60 opens the valve 63 and there through the line 60 with the bypass line 61 is connected ver. At this time, the pressure downstream of the check valve 33 is reduced to a value at which the check valve 53 can close and this leads to a circulation of the delivery rate of the main pump 16 at low pressure through the bypass line 60 and 61.

The above description shows that the FIG. S the embodiment shown senses the speed of the internal combustion engine as a function of the pressure difference between the spaces 205 and 207. The system also senses the total amount of fuel inlet as a function of the pressure difference between spaces 207 and 206. The pressure of the auxiliary pump is also sensed as a function of the pressure difference in spaces 219 and 220 Rooms 205, 206, 207, 219 and 220 are within certain areas vorbe, the bypass valve can be opened.

This system has security features. which essentially correspond to the security features of the FIG. 2 correspond to the embodiment shown. If, for example, the feed pump 19 fails, the pressure difference between the spaces 205 and 207 is lost, so that the spring 212 keeps the valve 200 closed. Should the auxiliary pump 17 fail, the pressure difference at the flow limiter Rl disappears and the spring 230 keeps the valve closed. Further security features are present in the illustrated embodiment.

It should be noted that in the case of the FIG. 3 the delivery pressure of the uncontrolled pump is not sensed as in the embodiment shown in FIG. 2 system shown. This is the case because the amount of syrup from the auxiliary pump 17 is determined directly as a function of the pressure drop across the flow limiter R1, whereby the operation of this pump is determined.

Although three separate operating parameters were measured in the two exemplary embodiments shown such as the speed of the internal combustion engine, the pump work of the uncontrolled Pump and the fuel requirement of the internal combustion engine can, if desired, a smaller number can be determined by parameters, or additional parameters can be determined, and this leads for the introduction of further valves or membranes which control the bypass valve.

For this purpose 2 sheets of drawings

Claims (7)

23 OO 194 claims: 1. Fuel supply device, the inlet with a fuel supply and the outlet with a Internal combustion engine is connected to a first variable speed pump that is connected to the Inlet is connected and promotes in an intermediate stage, and with at least two in parallel between the Intermediate stage and the outlet connected, further pumps working at constant speed, at least one of which has a bypass controlled by a valve, that of the conveyor ropes this further pump leads to the intermediate stage, characterized in that the Valve (63) is pressure balanced in that its valve member (93, 236) has a throttle opening (102, 103), from the delivery side of this further pump (16) to a normally closed chamber (105, 235) leads, and the valve (63) normally blocks a flow, on the other hand opens, when a pressure drop occurs at the throttle opening (102, 103), wherein control members (22, 70, 71. 72) are provided which respond to pressure differences between fuel pressures that are at least three points between the inlet (U) and the outlet (12) of the fuel supply device be established to create a vent (74) for the normally closed chamber (105,235) to open the throttle opening (102,103) to generate a pressure drop. 2. Fuel feed device according to claim I. characterized in that at least one of the Control members (70, 71, 72) is an axially displaceable slide (109, 110) in the exhaust duct (96) for the closed chamber (C05) is arranged. and that the slide (109, 110) axially between a open and a closed position is movable according to the pressure on the axial ends act. 3. Fuel feed device according to claim 1, characterized in that the pressure differences the speed of the internal combustion engine and the operating conditions of at least one of the not with show additional pumps (17) provided with a bypass. 4. Fuel feed device according to claim 3, characterized in that the speed of the Internal combustion engine as a function of the pressure difference between the inlet (11) and the first pump (19) and the outlet (21) of this pump is displayed. 5. Fuel feed device according to claim 3, characterized in that the mode of operation one of the further pumps (17) not provided with a bypass as a function of the pressure difference (75.76) is found on this pump. 6. Fuel feed device according to claim 3, characterized in that the mode of operation of one of the further pumps (17) not provided with a bypass is determined as a function of the pressure drop across a flow limiter (R2) in a line (42) which feeds the inlet of this pump . 7. fuel supply device according to claim 3, characterized in that one of the differences in pressure, the fuel consumption rate of the engine ^r as a function of B ennstoffströmung (22) through the ^E Tt _e rstXufuhreinnchtung according to claim 7, characterized in that the fuel flow as a function of pressure drop across an I Stromungsbegrenzer (Al) between the first pump 09) and the other pumps (16.! 7) is displayed.