DE3411402A1 - INTERMITTENT FUEL INJECTION ARRANGEMENT - Google Patents

Abstract

1. An arrangement for the intermittent actuation of a control member on an Otto engine, in which the beginning of the actuation operation can be controlled during each crankshaft period, wherein characteristic values are stored in address locations of a characteristic family storage means (18) which can be called up by rotary speed values and by other operating conditions,wherein during each crankshaft revolution angle pulse (line, 5, 21) which are synchronous in respect of crankshaft angle, and a reference pulse (line 9, 23) are produced, from which a trigger pulse for the beginning is derived, wherein an address counter (20) is connected with its reset input to the reference pulse line (23) and with its counting input to the angle line (21), wherein the characteristic family storage means (18) is connected on the one hand to the multi-bit address line array (22) of the address counter (20) and on the other hand to a multi-bit-line of an operating condition selector (19), wherein a time base counter (28) is connected to the cut-in input (26) of the characteristic family storage means (18) and prepares the storage means (18) during a predetermined time base, wherein a trigger pulse is applied to the reset input of a counter (12) for actuation of the control member and therein the O-output (15) of the counter (12) directly controls a control stage (16) for the actuating member, characterized by the following features : a) the actuating member is a valve control stage (16) for the injection system ; b) an overflow output (25) of the address counter (20) is connected to the blocking input (24) thereof ; c) the characteristic family storage means contains multi-bit storage words for representing the injection duration ; d) connected on the output side of the characteristic field storage means (18) is an intermediate storage means (13) into which the selected multi-bit storage word of the characteristic family storage means (18) is transferred upon expiry of the time base ; and e) the intermediate storage means (13) supplies a preload value for an injection counter (12) and a clock oscillator supplies counting pulses for the injection counter.

Description

Dr. Werner Häßler q / Λ 1 Λ Γ \ ¹ J

Patent attorney

Asenberg f> 2 February 13th

5P «C Lüdenscheid A 84 014

An.racs3de.rin: company

Atlas Fahrzeugtechnik GmbH
Harrow Path 26
5980 Werdohl

Arrangement for intermittent fuel injection description

The invention relates to an arrangement for the intermittent fuel injection in a gasoline engine, wobri ά ^ ν Einspritzbegirn and / or the injection duration wHhrend each Kurbt-lwellenperiodo controllable si nd.

A chain-field-dependent control of the triggering pulse for the ignition Training is already described in DE-PS 31 28 922.

The object of the invention is a characteristic-dependent control dts Start of injection and / or the injection duration, the map according to Load levels and other drive parameters as well as according to speed level fen is divided.

This object is achieved according to the invention by the following;

a) w * you «- 'and every turn of the crankcase will be kurbeJwelleti

Chronic angle pulses and a reference pulse generated from which »viii 1.5 Trigger pulse for the start of injection is derived;

b) an address number indicator is connected to the reference pulse line with its reset input and with its input to the VIiii1 <elimpuls3eitung connected:

c) an overflow output of the address indicator is connected to dea: locking gateg di ^a same ·

d) an addressable map memory is connected on the one hand to aiö multi-bit address fitting group of the address selector and on the other hand to a multi-bit line of an operating status filter

e) a Zeitbasi sz-Ibler is eidspei- with the enable input of the Kennf

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connected and provides the map memory during a given time base:

f) the map memory is followed by a buffer, In that the selected multi-bit memory word of the KcInftldspeicbers is accepted when the time base expires;

g) the buffer supplies a preload value for an injection meter, The trigger is at the reset input of the injection counter on, and a clock oscillator supplies the counting pulses for the Injector:

IC h) the Ü output of the injection meter controls the injection directly Lzventil.

The invention differs in this way in non-nearer ones Way of the prior art than the information defining the Valve opening time, i.e. the injection duration, in an address memory in Are stored in the form of C-bit words. These S-Bit foorte provide Timing stages are processed in your injection counter as preload values will. The injection duration specified in the injection counter corresponds to the respective 8-bit word. The o-Bit-Wox'te enable the definition of 256 time increments. for the injection duration.

These 8-bit words are, on the one hand, via speed increments and, on the other hand, Via load-dependent or operating parameter-dependent increments accessible.

If an address memory is used, 4096 address locations can be used 32 load increments and 128 speed increments or 64 load increments » and advance 64 speed increments. The load increments can also dependent on other operating parameters or by operating parameter values be replaced. Such operating parameters can affect the cooling water temperature, Jit air temperature and acceleration or deceleration values sain.

3C A load-dependent change in the time base is possible that the last address of the map memory, up to that of the Address counter counts, contains a preload value for the time base counter and that a decoding stage responsive to the last address controls the transfer of the preload value to the time base counter.

The invention also provides that a time pulse stage provides time pulses to the time base counter and that a blocking input of the Time pulse stage connected to the overflow output of the address counter is. This ensures that the clock pulses are provided properly and a secure blocking of the same after passing through the address identification

never ensured or the adjustment range.

The time base counter is therefore safe after the time base has expired locked that the output of the time pulse stage and the Ö output of the Timebasez "bleri? An" in *? Not-and-circuit are connected, their Output that supplies Z-vh.liippu.lsi · for the Z <= it base counter »

A safe and synchronous one. Transfer of the memory words from the Konnfrildspcicher in the buffer and the time base counter is achieved in that a data flip-flop with its data input at the Ö output of the time base counter and with its clock pulse input is connected to the Winkelicipulsleitung and that the Q output this data flip-flop with the switch-on input of the map memory and the Q output of the data flip-flop with detn '' takeover of the buffer connected is.

After an address characteristic has been run through, the characteristic memory is switched off in that the overflow output of the address counter is connected to the blocking input of the data flip-flop.

To ensure that the correct signal level is applied to the map memory, the 0 output of the data flipf3 op and the output of the decoding stage are connected to the switch-on input of the characteristic memory via a non-or circuit. As a result, the shutdown of the nuclear power storage will only take effect after a delay. So that the? Storage words can be transferred to the buffer or the "time base counter".

An adaptation of the injection duration to temporary operating conditions or at acceleration phases is possible because the valley oscil-lator is designed as a voltage-controlled oscillator, the frequency of which can be changed as a function of the operating parameters of the Otto engine is.

An over-revving of the motor will switch itself off as a result, dsf. for speed limitation a data flip-flop with its data input to the O output of the timebase zdblpr and with its clock input to the 1 overflow output of the addressz ' ^? hlers as well as its output is connected to the reset input of the buffer.

An embodiment of the invention is described below under Fezug. take on the adjacent bloc! - circuit diagram explained.

On a flywheel 1 sitting on the crankshaft of a gasoline engine there are markings 2 which normally; trained as teeth are, d. H. the existing teeth 2 of the starter tooth rim sitting on the flywheel 2 are used as markings. These teeth

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2 are detected in a sensor 3 so that tooth pulses are obtained. the Tooth impulses are shaped and doubled in a pulse shaper 4, see above that you get 5 Kinkelisipulse on the line, their angular distance is only half as large as that of the tooth pulses, so that there is a higher angular resolution.

The flywheel 1 has a reference mark 6, which also can be attached to a tooth. The Referenziuarkitrung 6 is in one Sensor 7 is detected, which may be combined with sensor 3 can. A pulse shaper 8 forms a reference pulse which is available on line 9. Add the angle size and the reference pulse b-a a switching stage 10 which, depending on the map, generates a trigger pulse on line 11, as described in detail in DE-PS 31 28 922 is described- This trigger pulse can be used simultaneously to Triggering the ". And impulse it serve.

The trigger pulse on line 11 sets within the scope of the invention the start of the injection duration with the aid of a fine injection counter 12 fixed. In the exemplary embodiment, the injection meter 12 is a Pre-loadable down counter, its pre-load value in a buffer 13 is stored, as will be explained in detail later. The buffer memory 13 has an acceptance input 36 and a reset input 40. When a signal at the takeover input 36 pending, the memory word pending on a multi-bit conductor group 41 is transferred to the buffer memory 13. The line 11 leads to the precharge input of the injection counter 12, so that when a trigger pulse occurs on line 11, the precharge value from the buffer 13 is adopted.

A clock oscillator 14 supplies clock pulses in the injection counter 12 can be counted. The injection counter 12 has a Η level at its 0 output 15, as long as it is output from the setting on the preload value pulses are counted up to the counter reading 0. So ~ as soon as the counter reaches 0, the 0 output switches to the !, - level around. This Η level acts directly on a valve control stage 16 for the injector or injectors, not shown. The output 15 is also to an AND circuit 17 with a negated output returned, so that the injection counter 12 is blocked for the clock pulses as soon as an L level occurs at output 15.

The preload values for the intermediate memory 13 are in a map memory 18 stored with an egg table old input 26. The map memory 18 is only then connected to the operating voltage and

thus ready for operation when the switch-on input 26 «has an L level. In the embodiment described, the field memory Vo is an address memory with 4096 S-Eit address locations. The address locations are distributed over 32 operating status stages, in particular load stages, each of which is assigned a speed characteristic with 128 speed incrtnents The load levels are evaluated in an operating state selector 19 and transmitted to the map memory 18 for address selection.

The speed increments are counted by counting a number of angular pulses in an address counter 20, which receives the angular pulse on the Win ^ tlirapul line 21 and provides 7-bit address signals for the 128 speed increments on the address line group 22. A memory address of the map memory 18 can therefore be selected for each of the 128 speed addresses of a speed characteristic curve as a function of the 32 load levels in each case. The 8-bit word stored therein is used by the injection counter 12 as a preload value _{5 of} the still to be described! bender way is transferred to the buffer 13. The Adreßz'Jh-Jer 20 has an overflow output 25, which switches to a Η level with the 128th angular pulse and is connected to a blocking input 24 via a regional stage 42, which represents the Adrt-ß-ZiTilfr with an L signal locks. In addition, this ~> her fed-up signal further switching stages, including the Betrithszu-standwihler 1 °.

A decoding stage 29 is connected to the address line group 22, which causes an AND connection of the seven output solutions. The representation of the decoding stage 29 is only schematic to understand. The decoding stage 29 gives with the 127.

Angle pulse from an output signal which is applied on the one hand to the precharge input 27 of the time base counter 28 and on the other hand to a Kichtoder -Rchaltung 30. The H output signal of the decoding stage 29 on the one hand switches on the map memory for a short time via the non-or circuit 30 and on the other hand causes the precharge input 27 of the time base timer 28 to send the memory in the relevant address space of the Ktsnnfcldspeichprs IP via the multi-bit conductor group 41 saved preload value. With the ¹ of Vorladewer- · tes in the Zeitbasisziiblers takeover occurs tin Η signal at the Ö-output 34th The time base error 28 gets Z ^ limpulse from a time pulse

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stage 31, which converts the pulses of a clock oscillator 32, e.g. into shares a fixed relationship. D. The counting pulses are due to a non-and circuit 33, the other input of which is connected to the O output 34 of the Time base counter 28 is connected. Counting pulses can only then be used get into the time base counter when the O-Ausgaisg has an H level .leads.

In addition, there is a data flip-flop 35 whose data input D to the O output 34 and its clock input Cl to the angular pulse line 21 is connected. The overflow outlet 25 of the meter is connected to a blocking input R of the data flip-flop 35 and a blocking input 37 of the time pulse stage 31 connected. The Q output of the data flip-flop 35 is connected to the Nicbtoder circuit 30, the Q output of the data flip-flop 35 is to the transfer input 36 of the buffer 13 connected. The Q signal, which occurs when the time base expires, causes the to be taken over in the map memory 18 stored memory word in the buffer memory 13. Since the not-or circuit 30 causes a delay, the memory word The intermediate memory is certainly generally taken over; if necessary, an additional delay can be provided.

The clock oscillator 14 for d * - n injection counters sets the maximum Injection duration fixed. The clock oscillator 14 is a voltage controlled Oscillator so that the frequency can be changed by a control voltage. The maximum frequency of the clock oscillator 14 is like this determined that when divided by 256, that is the maximum Vorladfcwert for the injection counter 12, which corresponds to the maximum injection duration. By supplying a control voltage, the oscillator frequency can and thus the injection duration can be changed. The control voltage can e.g. a correction voltage for the cooling water temperature of the motor, for acceleration phases and other operating parameters be.

The function of the arrangement can largely be compared to the previous one Description. In summary, the arrangement is triggered in each case by a reference pulse on the reference pulse guide 23. This reference pulse occurs with a reference phase of every revolution of the crankshaft on. This sets the address ZcMer 20 to 0. Of the overflow output 25 is switched to an L level, so that the Locks the time pulse stage 31 and the data flip-flop 35 canceled are. The output of the data flip-flop 35 carries a Q signal, so that the field memory 18 is switched on. The time base expires. Except-

The address counter 20 for counting the angle / pulse pulses on the pulse line 21 is provided for this purpose. The incoming angle pulses are counted. On the Adreßleitungsgruppe 22, the respective Winküladresseri be represented.

The time pulses are counted in the tent base counter 2fl , dr> r is already set to seirxr.n precharge value during the previous crankshaft revolution and has a Η level at the Ö output. As soon as the count reaches 0 and the time base has expired, the άύτ Ö output switches to an L level. The time base counter 28 is blocked via the non-and circuit 33. In addition, the data flip-flop 35 is switched over synchronously by the angle pulses 21, so that after the time base Kin Q signal occurs at the takeover input 36. This becomes the one corresponding to the respective angular address. Memory word of the KennfeJdspeichers in the 7 * 'ischenspeicher 13 taken over.

In this case also the operation state of agitators 19 a corresponding address for the Kcnrfeldspeicher available, asu dom the respective operating state corresponding memory word into the buffer 13 is transmitted.

When the last root address, in the example the address "127", occurs, the output of the decoding stage 2 has a ^C > level. As a result, the map memory 18 is switched on again for a short time, so that the address word stored in the relevant address is transferred as a preload value to the time base meter for the next working period. The Ü output of the time base counter is switched to a Η level. The data flip-flop 35 initially remains blocked via the blocking input R until a new reference pulse switches the overflow signal from the overflow output 25 to an L level.

After the address word defining the injection duration is stored in the buffer memory 13, which at the same time represents a precharge value for the injection counter 12, the precharge value is transferred to the injection counter 12 when a trigger pulse occurs on the line 11. The injection counter 12 then counts the clock pulses from the clock oscillator 14. The Ö output 15 has a Η level as long as in the Ein Injektzi ^; 12 pulses are counted here. After the preset number of clock pulses has been counted and the Zühlstandes 0 "has been reached, the level of output 15 changes to LP" gel. Output 15 directly controls valve control stage 16, which opens the injection valve.

The arrangement according to the invention is both for central injection

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zuDg as well as for single injection can be used.

The above-described embodiment of the invention works with a trigger pulse on line 11. This trigger pulse can be the? i: nd impulse. Kaη can J »also independently of the Zvindimpuls provide a trigger pulse for the start of injection.

According to the present description, the map memory is in 32 operating status or load incremental pension and 128 rotational speed increment ·? divided. > But there can also be a subdivision into 64 operating states— or provide load increments and 64 speed increments.

A further expansion of the present arrangement can be provided be that when the maximum speed allowed for the engine is reached, the injection is completely switched off by one To achieve speed limitation. This can be done, for example, by that the signal from the C output 34 of the Zeitbasist ^ ilers 28 with the Overflow signal for the highest level of the address counter 20 a data flip-flop 39, which when the maximum speed is reached (this is given if the time base is before the maximum level is reached of address number 20 has expired) provides a signal, which the buffer memory 13 via its reset input 40 on Set zero. As a result, the injection counter 12 has the value zero precharged so that it cannot deliver an injection timing signal.

It is also provided that in an additional circuit branch the idle speed is checked. When the idle speed drops below a Cretizwert, a control voltage is generated, which is applied to the voltage controlled clock oscillator 14 to to lower its frequency. As a result, the duration of the a ~ injection signal extended so that more fuel is injected. This increases the speed wit-the, so that a stabilizing Effect is achieved.

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Claims (9)

Asfmbcrg 62 March 19th Lüdenscheid A 84 01.4 Aniuelderin: Company Atlas Fahrzeugtechnik GmbH
Harrow Path 26
5980 Werdohl Arrangement for intermittent fuel injection Expectations Arrangement for intermittent fuel injection an Otto engine, the start of injection and / or the injection rate wlibrtnd are controllable for each crankshaft period by the following Ht. r'cmal e: a) During each revolution of the crankshaft, the crankshaft-angle angle becomes synchronous Kinkeliippulse as well as a reference pulse generated from which a Trigger pulse for the start of injection is derived; b) an address counter (20) is with "its: reset input to the reference pulse line (23) and with its counting path to ax angle pulse - IC line (21) connected; c) an Iborl on output (25) of the address counter (20) is with. the blocking <? input (24) of the same connected; d) an addressable map memory (18) is connected, on the one hand, to the Nehrhit address line group (26) of the address counter C20) and, on the other hand, an additional bit line of an operating state selector (19): e.) A time base counter (28) is connected to the switch-on input (26) of the Map memory (18) and provides the map memory during a given time base * f) the map memory (18) is followed by a buffer (13) switches the selected Mthrbit memory word into the expiry of the time base the% s code memory (18) is accepted; g) the intermediate memory (13) supplies a preload value for an injection counter (12), at the back input (11) of the injection counter the trigger pulse on, and a clock oscillator supplies counting pulses for the injection meter;
h) the Ö output (15) of the injection meter (12) controls the injection valve directly. 2. Arrangement according to claim 1, characterized in that dit each last address of the core field memory (19), up to the address counter (20) zMilt, a preload value for the time base counter (28) t-.nthKlt and that a Dccodif-run ^ s step responding to the last address (29) the transfer of the preload value to the tent base payer (2H) controls :. 3. Arrangement according to claim 1 or 2, characterized in that a Zeitirapulsstufo (31) supplies Zeit.impulse to the time base counter (28) and that a blocking input (37) of the Zeitiapulsstufe (31) to the overflow output (25) of the address counter (20 ) connected. 1.5 4. Arrangement according to claim 3, characterized in that the output of the 7 <t \ tlmpulsstufe (31) and the O-output (34) of the time base counter (2R) are connected to dint Nicbtund-SchaJ.tung (33), the output of which dit ^ iihlimpulsf. ^f i! r the. ?! eit.bas.i szclhler (28) Litie.rt. 5. Arrangement according to one of claims 1 to 4, characterized in that that a data flip-flop (35) with its; Data input (P) the Ö '~ output (34) of the tent base counter (2G) and its lactinipuuse input (Cl) is connected to the Wiaktlimpulsleitung (21) and that the Q output of this data flip-flop with the switch-on input (26) of the map memory (13) and the Q output of the Dattnflipfiop connected to the transfer ingang (3G) of the buffer (13) is. f>. Arrangement according to claim 5, characterized in that a Spt'rreinganjK (R) of the data flip-flop (25) to the Vberj on output (25) of the address meter (20) is connected. 7. Arrangement according to claim 5 or 6, characterized in that> the Q output of the data flip-flop (35) and the output of the r ^ coding stage (29) via a no-or circuit (30) with the switch-on input (26) of the map memory (18) are connected. 8. Arrangement according to a dt ^s r claims 1 to 7, characterized in that the clock oscillator (14) is designed as a voltage ^ controlled oscillator, the frequency of which can be changed as a function of operating parameters of the gasoline engine. 9. Arrangement according to one of claims 1 to 8, characterized in that for speed limitation eix \ data flip-flop (39) with its rifpä data input (P) at the Ö output (34) of the time base counter (2P) and rides its valley entrance (Cl) to the overflow exit (25) of the Adrel) -z'-hltrs as well as his exit at the rear entrance (40) of the Z \ visch «inspt.ichfcrs (13) is connected.