DE2335999A1 - CONTROL SYSTEM FOR ENGINE - Google Patents

Description

COHAUSZ & FLORACK

PAT B NT TO WALTSB Otto 4 DÜSSELDORF SCHUMANNSTR, 97 O * 3 "5 KQQQ

PATENT LAWYERS: Dipl.-lng. W. COHAUSZ Dipl.-Ing. W. FLORACK Dipl.-Ing. R. KNAUF · Dr.-lng., Dipl.-Wirtsdi.-lng. A. GERBER

The Lucas Electrical Company Limited

Well Street

GB-Birmingham "July 13, 1973

Engine Control System The invention "relates to a control system for an engine.

A system according to the invention is characterized by at least two converters which generate outputs which depend on the values of the operating variables of the engine, a memory unit which the Outputs are fed and which generates a binary output which depends on the signals received from the transducers, a Control device which can be actuated according to the value of the binary output to control a function of the engine, and a binary converter, which couples the binary output with the control device and changes the number of bits in the binary output in such a way that that the smallest available change in function is reduced.

It goes without saying that if, without the converter, the storage unit has an n-bit binary output and the maximum fuel supply F ages, the smallest possible change in fuel F / 2 is ⁿ -1 because 2 has the highest number of different outputs from the memory unit, and these outputs have to deal with all engine conditions between O and F. Using the binary converter according to the invention, the smallest obtainable change is f / 2 -1, where m n. This arrangement allows smaller fuel changes to be made in areas where engine operating conditions are critical, but an imperative to do so is that Changes in other areas greater than F / 2 ⁿ -1 can be made. These other areas can be chosen so

a / ti - 2 -

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that larger fuel changes are not critical. Without the converter so all fuel changes are gradually the same. With the Some converters can be smaller, as long as others are larger, giving the designer flexibility in designing the system to shake hands. The invention can be used to control the amount of fuel injected or the timing angle of the spark plugs will.

The invention is explained in more detail below with reference to the drawings. In the drawings are:

Pig. 1 a block diagram,

Fig. 2 shows one form of a memory unit; and Fig. 3 shows one form of a binary converter.

According to FIG. 1, two converters 11, 12 are provided, the two operating variables of an engine to be controlled. The company sizes are from the group of throttle angle, manifold vacuum and engine speed are selected and supply input signals to a memory unit 13. The memory unit in this simplified example is assumed to generate a four-bit binary output which is fed to a binary converter 14. The converter I4 forms the Yier-Bi * output into a five-bit binary output, that of a control device 15 is fed, which the supply of fuel to the engine controls.

The storage unit I3 can be provided in various forms, however, in one embodiment shown in Figure 2, the four output lines from memory unit I3 are at 1Ja, 13b, 13c and 13d shown. The converter 12 generates an analog signal, which in this case is converted into a signal which one of the four lines 12a, 12b, 12c or 12d makes it live. The lines 12a to 12d are used to actuate four switches when they are energized 16a to I6d, and each switch 16a to I6d serves in the closed state for coupling one of four sets of four lines 17a, 17b,

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I 7g »170. to the output lines 13a, 13b, 13c and 13d. The converter

II also generates an analog output that is converted into a signal which makes one of the four lines 11a, 11b, 11c or 11d live, and each of the lines 11 crosses each of the lines I7 » connections between the two sets of lines are made by diodes. The diodes are represented by dots in Fig. 2, and only the diodes associated with the set of lines 17a are shown.

To understand the work of the storage unit, assume that the converter 12 detects an operating variable value such that the line 12a becomes live. Then switch 16a connects the lines 17a with lines 13a, 13b, 13 ° and 13d. Now suppose that the other operating variable has such a value that the converter 11 makes the line 11a live. If it is then assumed that the diode connection is represented by I and the absence of a diode connection by 0, the signals on lines 13a, 13b, 13c and 13d have the form 1000 changes so that the line 11b becomes live the signal on line I3 has the form 0101. When line 11c is live is, the signal is 0010, and when the line 11d is energized is, the signal is 1011, assuming of course that the other operating variable remains constant. If the from the converter 12 changes the operating variable detected, the connections on one of the lines 17b, 17c or 17d and the lines 13a, 13b, 13c land 13d forwarded. By setting up the diode connections accordingly The required outcome is thus obtained under the process conditions from the storage unit .. It is again underlined that the example shown is a simplified one and that in practice it is considerable more bits are used.

In order to understand the work of the binary converter I4, a Consider the situation in which the output from the storage unit I3 is fed directly to the control device 15. The control device 15 can be provided in a wide variety of forms, and it can be This is simply a pump that feeds fuel to an engine.

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+ et, where the amount of fuel supplied per injection is determined by the output of the pump, which for the sake of simplicity is considered to be proportional to the input to the pump. With a Vjer-Bi + output from the operating unit 1J, there are sixteen possible ? If? ~ Nals that can be fed to the pump 15, and therefore if the maximum pump output is F, the fuel supply can be made in the smallest steps of P / 1? be changed.

The downside of such an arrangement is that, while there may be a number of engine operating quantities where a smallest step of 3F / 15 is actually more accurate than required, there may be other engine operating quantities which it is advantageous to have to change the fuel do a step of less than FZ / l 5. The binary converter 14 gives the possibility to do this. In the example given, where there is a change from a Yier bit word to a five bit word, the smallest step becomes F / 3I. Bg of course there are still only sixteen outputs from the fc 'storage unit 13 and therefore if it is decided to provide a Jdirtt of P / 51 for certain engine conditions, there must be other conditions where the step is greater than F / 15. The effect of this can be seen in the table below, which is a simplified possible example.

Memory unit output: 01 2 3 4 5 6 7 8 9 10 11 12 I3 1Λ I5 binary converter output: 0 1 2 3 / \ ? 6 7 9 11 53 15 19 2J ? F J1

This table expresses the binary numbers in decimal notation and how As can be seen, when working with the storage unit output, the small fuel step is F / 15> but when working with the binary converter output to control the pump for the first half of the range the smallest fuel step F / 3I, and then follows a range where the smallest step is 23? / 31, and then an area where the smallest step is 43? / 3i ". At the expense of a relatively small one Area "where the smallest step is enlarged is obtained so a considerable area in which the smallest step reduces is. It is of course unlikely that the outcome will be in the in the

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The method given in the table is set up, however, as above mentioned, the use of the binary converter enables the designer achieving flexibility in the design of the system, with the increased accuracy being used at the point where it is needed.

Fig. 5 is a block diagram showing the converter 14 which, in this example, operates with four FOTD gates 21, 22, 25, 24 and with seventeen NODER gates J1 through ^ »a-rTo. The foamy white input terminals 51 to 54 which receive a signal from the memory unit 13, and it has output terminals 61 to 65 'for supplying an input to the control device I5.

The following table presents the conditions of the circuit in negative Logic.

Output from 13 output from

1111-11111

1110 11110

1101 '11101

1100 11100

1011 11011

1010 11010

1001 11001

1000 11000

0111 10110

Φ110 10 100

0101 10010

0100 10000

0011 01100

0010 01000

0001. 00100

0000 00000

How to ethern, the output from the storage unit I3 begins,

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written in positive logic, with 0 in reference numbers and ends at 15 »while the output from circuit 14 starts with 0 and ends at 31 ·.

In the case of the HTOD gate circuit, each of the inputs must be connected to a HTOD gate circuit 1 so that the KTJUD gate circuit has a zero output generated. If any of the inputs is not 1, the output isb

In the case of EODER gates, each of the inputs must be 0, so the gate produces an output of 1. If any of the inputs is 1, an output 0 is created.

Keeping the foregoing in mind, the following illustrates Table how the circuit works for three of the sixteen numbers.

51 0 1 1

52 0 0 1

53 0 0 1

54 0 1 1

21a 1 0 0

22a 1 1 1

24a 1 1 0

23a 0 11

31a 0 1 0

32a 0 1 0

33a 0 0 0

34a 0 0 0

35a 0 0 0

36a 0 0 0

37a 0 0 O

38a 10 0

39a 1 0 0

40a 1 0 0

41a 1 0 0

42a 1 0 0

61 0 1 1

62 0 1 1

63 0 0 1

64 0 0 1

65 0 1 1

The output lines from the various gate circuits are through denotes the number of the gate circuit to which the letter a is added

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int, and if you remember the puncture of the gates calls back can be seen without further ado, how the signals are sent to the change different lines to get the required outputs from the gate circuits 40, 41 »42, AJ, 44 to the connections 61 to 65 to deliver.

It will of course be understood that numerous changes have been made in the circuit can be made to deliver the required output, and as already mentioned above, the exit itself is only simplified J? Orm, but in practice it is generally used be considerably more complex.

claim

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Claims (1)

claim Control system for an engine, characterized by at least two converters which generate outputs which depend on the values of operating variables of the engine output, a memory unit to which the outputs are fed and which generates a binary output, va.ch. it depends on the signals received by the transducers, a control device which can be actuated according to the value of the binary output to control a function of the engine, and a binary converter which couples the binary output to the control device and which Number of bits in the binary output changes in such a way that the smallest possible change in the function is ver ^ in ^ ert. 3Q988fi / C399