CS225751B1 - The connection of the impulse forming moment regulation - Google Patents

Abstract

1515621 Controlling I C engine fuel injection and ignition FAHRZEUG-UND JAGDWAFFENWERK "ERNST THALMANN" VEB 13 July 1976 [15 July 1975] 29117/76 Heading F1B [Also in Division G4] An arrangement for generating a triggering pulse a selectable time before a rotating element reaches a particular angular position comprises a first means 4, 41 which generates a reference pulse each time the element reaches the particular position, for instance top dead centre in an I.C. engine; a second means 3, 31 which generates n equally spaced timing pulses for each rotation of the element; third means 1 responsive to the reference pulse to generate a control pulse the duration of which is representative of the selectable time; and a counter 2 of capacity n which is reset to zero by the reference pulse and which continuously counts the timing pulses but is arranged to record two counts for each timing pulse during the period of the control pulse, the counter issuing the triggering pulse on reaching its full count of n. The control pulse at 11 switches the timing pulses to the second stage of the binary counter 2. The trigger pulse may control ignition or fuel injection in the I.C. engine.

Description

The invention relates to a circuit for regulating the moment of momentum in relation to an angular position of a shaft having two discs mounted on a rotating shaft and provided with a movable sensor member in which the output of one sensor member is connected to an input for setting the computer to the starting position. The time input is connected to the control signal source and the switch output is connected to the input of the actuator.

An electronic fuel injection system is known from DT-OS No. 2,248,530 which is equipped with a forward-back computer for injection molding and for controlling the start of injection. An angular section of two consecutive constant savings is determined by two switches on the camshaft. The first switch provides a regular pulse in the pulse generator, and after the regular pulse is complete, the forward-reverse computer counts - depending on the number of revolutions - the pulses that are sensed from the crankshaft.

This counting process is terminated by switching on the second switch, and at the same time, the downward counting of the pulses of the speed coming from the crankshaft until the zero crossing is started.

When the computer is set to the zero position, it is equipped with spraying and later results in a camshaft-dependent pulse.

In this method of control, the disadvantage is the use of the pulse pulsator body on the camshaft and the use of the forward-return computer.

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SUMMARY OF THE INVENTION It is an object of the present invention to provide an impulse handling device in which. the device gives a simple computer the impulse to recall the pulse in a controllable mm period relative to a particular reference position of the rotating component.

According to the invention, the problem is solved by having one auxiliary switch input connected to the output of the time interval shaping device and a second auxiliary switch input connected to the output of the second sensing member, one auxiliary switch output connected to the first computer input stage and it is connected to the input of the second computer of the computer, and the output of the computer and the output of one sensor are connected to the control inputs of the switch ·

According to the invention, the computer is preferably designed as a binary computer to which successive pulses are fed via an additional switch to the first or second counting stage. In this case, the additional switch is set so that subsequent pulses are fed to the second counting stage. .

According to another embodiment of the invention, the second computer counting stage is connectable to the second switching member via an additional switch.

According to the invention, the length of the control pulse is influenced by the control variables which act on the time pulse former and thus the time interval from the reference position is determined.

The device according to the invention can be implemented at a low cost without the use of a forward-back computer and is useful for controlling the ignition time as well as the injection times. for combustion seas.

The reference angle can be selected at 360 [deg.], But it can also be of a different magnitude, the temporal displacement of the pulse to be provided can only be performed at half the time required to run the reference angle.

With reference to the accompanying drawings, the invention will be explained in more detail with reference to an exemplary embodiment, in which Fig. 1 is a schematic circuit diagram of a device according to the invention and Fig. 2 is a pulse plan of a device according to the invention.

The device according to the invention comprises two pulse discs 2 and 6 of pulse which are arranged on a rotating shaft The reference pulse disc 4 has a reference pulse B at its reference position 41 at its pulse sensor 41, which is a reference position. in this case, every 360 °,

The control of the time-delayed time of the pulse A and e provided is based on the reference pulse B and the corresponding angular position of the rotating shaft 2.

This reference pulse B is provided via the adjustment line. 11, the computer 2 always starts from the zero position and provides a control pulse St. in the shaping 1 of the time interval. This control pulse St, in its length X, is determined by the input variables that affect the meaid time of the equipped pulse A from the reference position. These input values are the speed ij, the set torque M and the temperature T.

The control pulse St reaches via the switch line 11 an additional switch 21 which is upstream of a computer having two switching positions; the control pulse St determines its switching position. In the first switching position of the auxiliary switch 21, following the insertion of the control pulse St, subsequent pulses P from the pulse disk 2 arrive via the second sensor member 21 via

225 751 a counting line 32 and an additional switch 21 to the second counting stage 202 of the computer 2, whereby a double counting of the subsequent pulses provedeno is performed.

In the second switching position of the auxiliary switch 21, in the absence of control of the pulse St, the subsequent impulses F reach the first counting stage 201 of the computer. Normal counting of the follow-on pulses F.

It must be taken into account that the pulse disk 3 of the subsequent pulses emits during the reference angle, in this case 360 °, of the subsequent pulses F and, in addition, the computer 2 shows a counting capacity n of the pulses.

Device features - is as follows:

When the shaft 5 rotates, the pulse discs 3 and 6 rotate with this shaft 5. The subsequent pulses F are continuously melted in the transmitter -2 at night, with the reference pulse B always bringing the computer 2 to the zero position.

The process from the occurrence of the reference reset B to the release of the trip pulse A is described below. The reference pulse B is provided with a control pulse St with a duration t1. This control pulse St brings the auxiliary switch 21 to its first position, the successive pulses F coming from the pulse disk 3 arriving at the second counting stage 202 of the computer 2 and thus counting twice.

After the time X of the control pulse St has elapsed, the auxiliary switch 21 assumes its second position. Subsequent impulses F reach the first counting stage 201 of the computer 2 and are normally counted. The computer 2 reaches by double counting its full state n - before the full course of the reference angle and outputs a trip pulse A. This trip pulse A arrives at a distance T1 before the nearest reference pulse B,

The described device is useful, for example, for controlling the moment of ignition or for controlling the infiltration of fuel in combustion engines, the impulse discs 3 and 4 are seated on the crankshaft - It is obvious that it is also feasible to design with one disc on which subsequent impulses and reference pulse are taken.

In the application of the ignition device to the Otto moors, the firing signal A of the ignition control computer 2 is used, the time t corresponding approximately to the time by which the ignition occurs before reaching the upper dead point.

If the computer 2 is connected behind a bistable switch 6, in which the trip signal A causes the current circuit 61 to be switched on and off by the switch 6 via the reference pulse B, then the current 61 can be used to control the fuel quantity by the electromagnetic injection nozzle 7. it starts in dependence on time t of the control pulse St before the reference pulse B and ends after time t at the arrival of the reference pulse B.

It can be seen from the pulse plan in FIG. 2 that the time χ of the control pulse St corresponds to the switching time of the switch 6 and hence the injection time and the fuel proportions proportional to this time.

Due to the system, there is a time difference - t ^ between the time t of the control pulse St and the injection time when the time χ of the control pulse St is greater than - the respective multiple and distance

Fa between two consecutive imals F.

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The error value t t corresponds to the exceeding of the remainder of the respective multiple i of the distance Fa, i.e. Fa.i mmz, with two successive pulses. .

Instead of a binary computer, it is also possible to use a resettable frequency divider with a corresponding end output.

Claims (3)

OBJECT OF THE INVENTION A wiring for controlling the moment of momentum generation in relation to an angular position of a shaft having two disks mounted on a rotating shaft and provided with a stationary sensor member, wherein the output of one sensor member is connected to an input for setting the computer to the starting position and at the time interval former input, wherein the control input is connected to a control signal source and the switch output is connected to an actuator input, characterized in that one input of the additional switch (21) is connected to the time interval former output (1); the second input of the auxiliary switch (21) is connected to the output of the second sensing member (31), one output of the auxiliary switch (21) is connected to the input of the first counting stage (201) of the computer ( 2) and the second output is connected to the input of the second counter stage (202) of the computer (2), · and · the output (22) of the computer (2) and the output of one · sensing member (41) are connected to the control inputs of (6). Sweating according to claim 1, characterized in that the computer (2) is designed as a binary computer. Connection according to Claims 1 or 2, characterized in that the second counting stage (202) of the computer (2) can be connected to the second sensing member (31) via an additional switch (21).