EP0067369A2 - Fuel injection apparatus for internal-combustion engines - Google Patents

Abstract

A fuel injection device for internal combustion engines is proposed, in which, from a certain residual stroke during the delivery stroke of the pump piston, a relief channel is opened via a control edge. The same control edge closes the relief channel again during the suction stroke. During the subsequent effective suction stroke, the amount of fuel to be injected during the following pressure stroke is metered by means of an electrically actuated valve. The solenoid valve is already opened by the control edge before the relief channel is closed, so that the pump working chamber of the fuel injection device is flushed in the opening phase of the relief channel. In this way, an exact metering of the fuel quantity to be injected is obtained.

Description

State of the art

The invention relates to a fuel injection device according to the preamble of the main claim. In such an injection device known from DE-OS 19 19 969, the amount of fuel which is to be injected during the delivery stroke of the pump piston of an injection pump is metered in during the suction stroke of the pump piston by means of a solenoid valve which is clocked or controlled analogously. The metered quantity is determined by the opening time of the solenoid valve, the opening phase of this valve lying exclusively in the suction stroke area of the pump piston. In this known device, the pressure conditions in the working space and the valve cross section of the fuel injection pump influence the metering quantity. For an exact metering of the fuel injection quantity, the speed and the injection timing must be taken into account in this known device for dimensioning the opening times of the solenoid valve. The pressure fluctuations in the work area during the filling process must also be taken into account. Further disadvantages result from the limited switching speed of a solenoid valve. The during the metering phase at Suction stroke occurring two switching operations of the solenoid valve thus affect the accuracy of the metering result. Furthermore, the speed or the injection pump speed are limited by the switching time of the solenoid valve.

In another fuel injection pump known from DE-OS 19 19 707, the limited switching speed of solenoid valves was taken into account in that in this distributor pump two pump systems are accommodated in the distributor, each of which is supplied with fuel via a solenoid valve. In this way, a higher pump speed can be achieved. Furthermore, in this injection pump, the cam drive of the pump piston is designed such that the stroke speed of the pump piston during the suction stroke is significantly lower than that during the delivery stroke of the pump piston. The solenoid valve of each pump system of this radial piston pump is also only opened during the suction stroke of the pump piston, the opening time of the solenoid valve determining the metered quantity. Here too, the speed and the injection timing must be taken into account when controlling the solenoid valves. When designing this pump, the metering stroke of the solenoid valve begins with the suction stroke of the associated pump pistons. A spray start adjustment requires a change in the suction stroke start, so that this suction stroke start must be entered exactly when calculating the opening time of the solenoid valve. Furthermore, the dynamic conditions at the reversal point of the pump piston during the transition from the delivery stroke to the suction stroke are difficult to control. Because of the duplicate Pump system in this fuel injection pump, the device is still very expensive.

Advantages of the invention.

In contrast, the fuel injection device according to the invention with the characterizing features of the main claim has the advantage that a flushing phase follows the delivery phase, that is to say the period in which fuel is delivered into the injection lines. In this flushing phase, which also includes the remaining pressure stroke of the pump piston, the pump workspace of the fuel injection pump is constantly filled with fuel via the electrically actuable valve and, if necessary, via the relief line, if this leads to the pump suction chamber usually present in a fuel injection pump, which fuel is below that in the pump suction chamber or the pressure in the fuel supply source. At the time the relief channel is closed, the pressure conditions are balanced, so that with a sufficiently large metering cross-section on the valve, the opening time of the valve in relation to the speed or the opening phase over a certain suction stroke length of the pump piston is a precise measure of the injection quantity. Since z. B. following the delivery stroke of the pump piston, the electrically operable metering valve is already open, the closing time of the relief channel through the control edge advantageously determines the beginning of metering. This closing takes place without the loss of time to be taken into account in the solenoid valve, so that the metering quantity can only be influenced by the closing time of the valve at the end of the metering phase.

Advantageous further developments and improvements of the solution specified in the main claim are characterized by the measures listed in the subclaims.

drawing

An embodiment of the invention is shown in the drawing and is explained in more detail in the following description. 1 shows the exemplary embodiment in a basic representation, FIG. 2a shows a diagram of the switching time of the metering valve over the angle of rotation, FIG. 2b shows the stroke course of the pump piston in association with the switching times of the metering valve, FIG. 3 shows a development of the embodiment according to FIG. 1 4 shows an enlarged view of the device for recording the switching times of the relief channel, FIG. 5 shows a first modified form of the device according to FIG. 4, FIG. 6 shows a second modified form of the device according to FIG 4, FIG. 7 shows a device for determining the stroke movement of the pump piston, FIG. 8 shows a modification of the embodiment according to FIG. 1 with a modified spray timing device, FIG.

Description of the embodiment

In the embodiment shown in FIG. 1, a bore 2 is provided in a pump housing 1, in which a pump piston 3 encloses a pump working space 4. The pump piston is passed through a cam disk 5, which runs on a roller ring 6 Means not shown driven and performs a reciprocating pump movement with a suction stroke and a delivery stroke during its rotational movement. The fuel supply to the pump work chamber takes place via a fuel inlet channel 8, which leads from a pump suction chamber 9. This suction chamber is supplied with fuel from a fuel tank 12 by means of a fuel feed pump 11, the pressure in the pump suction chamber 9 being adjusted with the aid of a pressure control valve 14 which is connected in parallel with the fuel feed pump 11.

In the fuel inlet channel is an electrically actuated valve 16 which, for. B. can be a solenoid valve, used as a fuel metering device. A check valve 17, which opens in the direction of the fuel inflow into the pump work chamber 4, is also provided downstream of this valve. A blind bore 18, which is arranged in the pump piston 3, leads from the pump work chamber 4, from the end of which a radial bore 19 leads to the outside. Another radial bore 20 connects the blind bore 18 to a distributor groove 21, through which delivery lines 22 are connected to the pump work chamber 4 in succession when the pump piston rotates and its delivery stroke. The delivery lines are distributed according to the number of cylinders to be supplied to the associated internal combustion engine on the circumference of the bore 2 and each contain a relief valve 23 and are each connected to an injection valve 24. In the wall of the bore 2, an annular groove 26 is also provided, which is connected to the pump suction chamber 9 via at least one bore 27. The annular groove 26 is arranged so that the radial bore 19th is opened in the pump piston 2 from a maximum delivery stroke, so that the fuel delivered from this point in the further stroke movement of the pump piston 2 can flow out via the blind bore 18 serving as a relief channel, the radial bore 19 and the bore 27 into the suction chamber 9 and thus the pressure delivery is interrupted in the delivery line 22.

To change the time of injection, a spray adjustment piston 29 is also provided, which is coupled to the cam ring 5 and is adjustable against the force of a spring 30. The injection adjustment piston includes a pressure chamber 31, which is connected to the pump suction chamber via a throttle 32 and is therefore acted upon by the speed-dependent pressure in the pump suction chamber. In accordance with this speed-dependent pressure, the injection timing piston is used to adjust the injection timing to early by rotating the cam ring with increasing speed. In order to influence the injection adjuster time, the pressure chamber 31 is also connected to the suction side of the feed pump 11 via a solenoid valve 34 and can be relieved with the aid of this valve. The solenoid valve 34 is controlled by a control device 36, which also serves to control the electrically actuable valve 16 in the fuel inlet duct. For this purpose, the control unit works in accordance with parameters that have to be taken into account for the dimensioning and the timing of the fuel injection quantity. The control unit can, for. B. contain at least one map, in the target values for the amount of fuel to be injected in indirect or direct form are included. In a manner known per se, the speed, the temperature, the air pressure and the load can be taken into account as parameters. Especially for the control of the solenoid valve, signals of a needle stroke transmitter in the injection valve 24 can be detected as further parameters for determining the actual start of injection and the actual fuel injection duration. As an alternative to this, control signals can also be used via a pressure transmitter 38, which is suitably arranged on the high-pressure side of the fuel injection pump, to determine the start of delivery or the delivery period. To determine the stroke position of the pump piston and / or its speed, an encoder 39 z. B. in the form of an inductive sensor on the cam 5.

The mode of operation of the fuel injection device shown in FIG. 1 will now be explained with the aid of the diagrams in FIGS. 2a and 2b. 2b shows the elevation curve of the pump piston over the angle of rotation α. By appropriate design of the cam disc 5 it has been achieved that the change in stroke per angle of rotation D1 during the pressure or delivery stroke of the pump piston is substantially greater than the change in stroke during the suction stroke of the pump piston. This curve part B of the elevation curve runs very flat and is linear except for the border area at the reversal points of the pump piston. The pressure stroke part A of the curve in Fig. 2b is divided into three sections. Between the bottom dead center UT of the pump piston at the beginning of the pressure stroke up to the point FB, the fuel present in the pump work chamber 4 is compressed until the delivery pressure, which is an opening of the Nozzle 24 causes is reached. The second part of the curve now extends between FB and EO. In this area, fuel is delivered into the delivery channel 22. The check valve 17 continues to be closed by the delivery pressure, possibly supported by the spring installed there. So that the electrically actuated valve 16, which is here z. B. is designed as a slide valve, relieved of pressure.

When reaching the point of the EO Erhebun ^g skurve the radial bore 19 is brought into connection with the annular groove 26 so that the pressure space is relieved into the suction chamber 4. 9 The remaining amount of fuel displaced by the pump piston flows out there. This takes place in the area between the opening of the relief channel (EO) and top dead center (OT). The solenoid valve 16 is opened at the latest when the point OT is reached. The opening can take place earlier since the fuel inlet channel 8 is closed by the check valve 17 during the pressure stroke. In the area between TDC and the closing point of the relief channel ES, fuel is now drawn in via the large opening cross section of the valve 16. The pressure equalization in the pump work space can also take place via the relief channel 18, the radial bore 19 and the bore 27. In the area between EO and ES it is ensured that the pressure in the work area 4 is balanced and the work area 4 is constantly filled and flushed. The effective suction stroke of the pump piston begins from ES. Fuel is drawn in until the solenoid valve on MS closes. The effective suction stroke length α ₂ is thus determined on the one hand by the geometric design of the fuel injection pump or by the Position of the control edge delimiting the annular groove 26 and on the other hand determined by the switching time of the solenoid valve. The switching times of the solenoid valve are recorded in FIG. 2a, where o (1 is the total opening time of the solenoid valve and α 2 denotes the time effective for the metering.

Since the solenoid valve can be opened much earlier than the actual effective suction stroke begins and since there is still a rinsing phase between the effective delivery stroke and the effective suction stroke of the pump piston (EO-ES), when the solenoid valve is opened, the spraying time within the possible spray timing adjustment range does not need to be taken into account will. The fuel metering control does not influence or hinder the spray timing adjustment options. Due to the flat cam profile during the suction stroke, there is the further advantage that the pump piston can constantly follow the cam even at high speed without the pump piston jumping off within the effective suction stroke length and thus influencing the amount of fuel drawn in.

The cam pitch is advantageously linear over the possible length of the effective suction stroke, which has a particularly advantageous effect in the case of correction interventions. In principle, however, the type of metering is not dependent on the linearity of the survey curve, but it does facilitate accurate metering. By determining the effective suction stroke length, you get a very good metering accuracy of the amount of fuel to be metered. In the simplest case it can the effective suction stroke length for metering can be controlled directly without feedback of the amount of fuel actually injected being required. Very good control results are obtained if the actual fuel injection quantity is detected in a manner known per se by means of the control unit and compared in a comparison device of the control unit with a target fuel quantity signal formed there. As mentioned at the beginning, the actual fuel quantity can be determined by a needle stroke transmitter or by a correspondingly evaluated pressure signal from the pressure transmitter 38. The target fuel quantity is formed from the parameters mentioned at the beginning with the load as a reference variable. The actual opening time of the solenoid valve is then corrected in accordance with the comparison result when the actual fuel quantity deviates from the target value. The basic opening duration signal of the valve 16 is formed in accordance with the target fuel quantity signal.

A transmitter 40 is advantageously provided, as shown in FIG. 3, for the precise detection of the collection point at which the relief channel 19 is closed again (ES). 3 corresponds to that of FIG. 1. In FIG. 4, such an encoder is shown larger. The bore 27 'in this development of the fuel injection device also leads from the annular groove 26 and via the transmitter h0 with complete pressure relief to the suction side of the fuel delivery pump 11 or to the fuel tank 12. The transmitter 40 is thus in a pressure-relieved space 41 Bore 27 ' in the pressure-relieved space 41 is controlled by a valve closing part 43 which is fastened on a leaf spring 45. This is attached at the other end via an insulating piece 46 on the pump housing, which also represents the ground connection. An electrical line 42 leads from the leaf spring, which in another embodiment can also be a membrane or spider in a suitable configuration, to the control device 36. Furthermore, a throttle bore 48 is provided coaxially with the axis of the bore 27 ′ in the valve closing part, via which the bore 27 'is constantly connected to the space 41 even when the valve closing member 43 is in the closed position. At this throttle bore, pressure can build up in the bore 27 ′ as long as fuel continues to flow from the pump work chamber 4 via the blind bore 18. This is the case as long as the radial bore 19 is in connection with the annular groove 26 and as long as the solenoid valve 16 is open. This condition applies to the area of the suction stroke B between OT and ES. Under the resulting pressure, the valve closing part 43 lifts off its seat on the bore 27 'and thus interrupts the circuit to ground. However, as soon as the connection between the radial bore 19 and the bore 27 'is interrupted again in the course of the suction stroke of the pump piston, the valve closing part 43 returns to its seat and closes the circuit. This is the signal that the effective suction stroke has started. Accordingly, the signal is processed in control unit 36, which can advantageously be done with the aid of an integrating device.

With the closing signal of the encoder 14, the integrating device is set and as soon as the output value of the integrating device has reached the setpoint value for the fuel quantity given by the control device 36, a switching signal is emitted from a comparing device of both values to the solenoid valve for closing the fuel inlet channel. Thus, the switching time _'of the valve is purely hublängenbezogen 16, the running time of the integrator must be corrected by a speed-adapted integration time constant for the integration. This can be done with known methods, on the one hand by making the design of the integrator itself speed-dependent in an analogous manner or by integrating the integrator in constant integration steps with speed-dependent frequency.

In another embodiment, a correction signal can be generated from an TDC signal, which is achieved with the aid of the transmitter 39, and the closing signal, which is output by the transmitter 40, which corrects the opening phase of the valve, which is switched in synchronism with the speed.

The configuration of the transmitter 40 according to FIGS. 3 and 4 also permits the formation of an opening signal for opening the bore 27 '. With this opening signal, for example, an opening signal for the valve 16 could be formed.

5 shows an alternative embodiment of the transmitter for opening or closing the bore 27 '. The throttle bore 48 provided in FIG. 4 in the closing part 43 is in this Design in a branch duct 49 ', which leads to the pressure-relieved space 41, is provided as a throttle 50. In the embodiment according to FIG. 6, a throttle 51 is provided at the outlet of the bore 27 'in the pressure-relieved space 41, and a pressure transmitter 52 is arranged upstream of this throttle 51 in the wall of the bore 27'. The pressure signal emitted by this is preferably converted into the closing signal or the opening signal via a threshold switch.

Instead of the speed-compensated integration described above, it is also possible to assign a stroke sensor 54 to the pump piston, which is shown in FIG. 7. For this purpose, a pulse generator 55 is provided with the pump piston 3 parallel to the pump piston axis, which a transducer, for. B. an inductive pickup 56 is assigned. The pulse generator can e.g. B. consist of magnetized parts lying one behind the other or be designed as a toothed rack. Such pulse generators are known in principle and need not be described in more detail here. The signals emitted by the transmitter 56 are then integrated in an integrator, the speed or the lifting speed of the pump piston no longer having to be taken into account.

The principle used in the above-described designs of the fuel injection device and their developments can also be applied to a fuel injection pump which is constructed in the manner of a series pump. 8 shows a pump piston 60 as one of the pump pistons In-line pump. This pump piston can be moved up and down in a cylinder 61 for the purpose of suction and fuel delivery and can also be rotated at the same time. It encloses a pump working chamber 62 in the pump cylinder, from which a fuel injection nozzle is supplied with fuel. A fuel inlet duct 8 ′ also opens into the working chamber 62 and, like in FIG. 1, contains a check valve 17 ′ and an electrically operable metering valve 16. To achieve a flushing phase of the type described above, the pump piston has an oblique control edge 63 which delimits a partial annular groove 64 in the outer surface of the pump piston. The partial ring groove is connected to the pump work chamber 62 via a longitudinal groove 65 or via a corresponding bore. The oblique control edge works together with a relief channel 27 ″, through which the displaced fuel can flow out of the working space 62 during a residual stroke of the pump piston 60. Depending on the rotational position of the pump piston, set by a rack 70, for example, the relief channel 27 becomes Sooner or later opened or closed again, the rotary position of the piston can thus achieve an injection adjustment, ie a variable delivery end. on the rack 70 detecting encoder 71 are used, the correction signal is taken into account by a corresponding control device when forming the opening pulse of the electrically actuated valve.

As FIG. 9 shows, it is also possible to use several electrically operated metering valves for several pump pistons to be supplied with fuel. A check valve 67, 68 is advantageously assigned to each individual pump piston. The condition for such an embodiment is that the cam descent flank, ie the stroke profile of the pump piston, is the same for both pistons during the effective suction stroke.

Claims (22)

1. A fuel injection device with at least one working space enclosed by a pump piston in a cylinder, which can be connected to the fuel injection point via at least one delivery line and can be connected during the suction stroke to a fuel inlet channel having a fuel quantity metering device that can be operated electrically by a control unit and leading to a fuel supply source that a relief channel (18, 19, 27; 65, 64 _e 27 ") leads away from the pump work chamber (4, 62), the passage cross section of which can be controlled by an adjustable pressure stroke of the pump piston through a control edge (26, 63) which is guided synchronously with the movement of the pump piston and can be closed again from a suction stroke corresponding to the remaining stroke of the pump piston and that the fuel quantity metering device (16) acts as an electrically actuated valve is formed, which can be brought into an open position or a closed position, depending on the control, and can be switched by the control unit (36) in such a way that it is already open before the relief channel is closed and, depending on the size of the fuel quantity to be injected, sooner or later after the closing of the Relief channel is closed during the suction stroke of the pump piston (2). 2. Fuel injection device according to claim 1, characterized in that the pump piston (2, 60) is actuated periodically by a cam track (5) which is designed so that the stroke change of the pump piston per unit of movement of the cam track during the suction stroke of the pump piston is substantially less than during the pressure stroke of the pump piston. 3. Fuel injection device according to claim 2, characterized in that the cam track is designed such that the change in stroke of the pump piston per movement unit (angle of rotation) of the cam track is constant in the region of the effective suction stroke of the pump piston. 4. Fuel injection device according to one of claims 1 to 3, characterized in that for controlling the amount of fuel, the effective suction stroke length after closing the relief channel can be controlled by the opening time of the valve. 5. Fuel injection device according to claim 4, characterized in that the control unit (36) is connected to a transmitter (24, 38) for the actual fuel injection quantity, the output value of which is compared in a comparing device in the control unit with the target fuel quantity signal, corresponding to the Output signal of the comparison device, a correction signal for an opening duration signal of the valve formed according to the setpoint is formed. 6. Fuel injection device according to claim 5, characterized in that the control device is connected to a transmitter (40) which emits a signal which detects the closing of the relief channel and that a correction signal can be generated in accordance with the closing signal, according to which the position of the opening phase of the valve ( 16) is changeable. 7. Fuel injection device according to claim 5, characterized in that a pressure transmitter (38) detecting the delivery phase is provided as the actual fuel injection quantity transmitter. 8. A fuel injection device according to claim 5, characterized in that the needle stroke of the injection nozzle (24) is provided as the actual fuel quantity sensor. 9. Fuel injection device according to claim 4, characterized in that the control device (36) is connected to a transmitter (40) which emits a signal which indicates the closing of the relief channel or the beginning of the effective suction stroke length, by means of which an opening signal which determines the effective suction stroke length the valve is set, the length of the opening duration signal corresponding to the respective target value of the fuel metering amount. 10. Fuel injection device according to claim 9, characterized in that an integrator can be set by the closing signal, the integration value with a setpoint in a comparison device in Control unit is compared and that a switching signal can be output to the valve by the comparison device when the setpoint is reached. 11. Fuel injection device according to claim 10, characterized in that the integration constant of the integrator is dependent on the speed. 12. Fuel injection device according to claim 11, characterized in that the integrator adds constant integration steps in the speed-dependent cycle. 13. Fuel injection device according to claim 4, characterized in that the control unit is connected to a stroke length sensor (54) to form the signal controlling the valve. 14. Fuel injection device according to claim 13, characterized in that the stroke length generator generates equidistant pulses along the stroke of the pump piston and is connected to an integrator which can be set by a closing signal of the relief channel and whose integration value in a ver the control device is compared with a setpoint, a switching signal for the valve (16) being generated when the setpoint is reached. 15. Fuel injection device according to one of claims 6 to 14, characterized in that a throttle (48, 50, 51) is arranged in the discharge channel (27 ") leading to a space (41) with low pressure and (42), downstream of the control edge (26) a pressure transducer (45, 43; 52) is provided which is exposed to the pressure in the relief line (27 ') upstream of the throttle point and that a signal for the open state and the closed state of the relief duct can be formed from the output signal of the pressure transducer. 16. Fuel injection device according to claim 15, characterized in that the pressure transmitter consists of a spring (45) which is electrically insulated from its attachment point and has a closing part (43 ') designed as a closing member of the relief line (27'), which by the bias of the Spring can be pressed against the outlet opening of the relief line. 17. Fuel injection device according to claim 16, characterized in that in the overlap region of the closing part (43) with the outlet opening of the relief line (27 '), the throttle is arranged as a through hole (48) through the closing part (43). 18. Fuel injection device according to one of the preceding claims, characterized in that a device for adjusting the pump piston rotation position relative to the pump piston drive is provided for the injection timing adjustment. 19. Fuel injection device according to one of the preceding claims 1 to 18, characterized in that the control edge (63) extends obliquely and the control edge is transversely adjustable for the injection timing. 20. Fuel injection device according to claim 19, characterized in that a position sensor (71) is connected to an adjusting device (70) for the rotary position of the control edge, through which a signal for detecting the effective start of the suction stroke can be derived. 21. Fuel injection device according to one of the preceding claims, characterized in that Between the electrically actuable valve (16) in the fuel inlet channel (8) and the working space of the fuel injection pump, a check valve is arranged, which opens in the direction of the working space. 22. Fuel injection device according to claim 21, characterized in that the valve closing member of the electrically operable valve is stable in the closed position when the valve is de-energized by the delivery pressure in the working space of the fuel injection pump.

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