DE2903978C2 - - Google Patents

Description

State of the art

The invention relates to a device according to the genus Main claim. There are already such facilities from the DE-AS 25 04 843, from DE-OS 25 39 113, from DE-OS 28 50 534 as well as from DE-OS 28 51 336 known, which relates to ignition systems for Get internal combustion engines. According to this state of the art speed-dependent characteristics in a read-only memory (ROM) knows, the addresses are indicated by speed-dependent numerical values be spoken. The addressed memory contents are exited counts and the end of the count determines the process to be controlled, e.g. B. the ignition point or the beginning of the closing time, i.e. the beginning the primary current flow in the ignition coil.

It is an object of the present invention to set up the gat appropriate way to further develop that with minimal circuitry technical and program effort depending on a wide one of several predefined characteristic curves of the first parameter can be selected.

Advantages of the invention

The device according to the invention with the characteristic features the main claim has the advantage that a very multiple implementation of the influence of another parameter light becomes. The effort both in terms of circuitry, as well as per grammatical implementation is relatively low because it depends this parameter is only one of several default characteristics of the first parameter is selected. At the same time is however a quick control depending on the white given other parameters, so that even with simple control units quick response is to be achieved.  

By the measures listed in the subclaims are advantageous developments and improvements to specified invention possible. Particularly advantageous is the selection of the characteristic stored in storage matrices (support points) lines through the further parameters via analog-digital Converter or via an arrangement of threshold levels with graduated threshold values.

The specified facility is also particularly suitable for switching between several speed characteristics in Depending on the existing supply voltage to take.

drawing

Two embodiments of the invention are in the drawing shown and in the description below explained in more detail. It shows

Fig. 1 shows a first execution of the invention, for example with a switching between three characteristics by the supply voltage via an analog-to-digital converter,

Fig. 2 is a signal diagram to explain the operation and

Fig. 3 shows a second exemplary embodiment from the invention with a switchover between three speed characteristic curves by the supply voltage via an arrangement of threshold value stages.

Description of the embodiments

In the first embodiment shown in Fig. 1, a speed sensor assembly 10 consists of a rotating, preferably with the crankshaft of an internal combustion engine not shown Darge connected toothed disk 11 , the tooth marks are sensed by a pickup 12 from. The generated output frequency is converted into a binary number in a downstream frequency-number converter 13 and supplied to a microcomputer 14 . Instead of such a speed detection, any other speed detection is of course also possible that generates a speed-dependent numerical value. By means of this speed-dependent numerical value, three memory matrices 15, 16, 17 are selected in parallel in the microcomputer 14 , the speed-dependent numerical value serving in each case as an address. The selected memory contents are each supplied via switching devices 18, 19, 20 to a counting device 21 which has a counting frequency f . A command line 22 leads from the counting device 21 to an ignition output stage 23 , which usually has an electronic switch 24 in the primary circuit of an ignition coil 25 , in the secondary circuit of which at least one spark plug 26 is connected. The electronic switch 24 is controlled via the command line 22 .

The supply voltage present at a terminal 27 is also fed to the microcomputer 14 via an analog-digital converter 28 . There, the supply voltage generated by the analog-digital converter 28 is decoded dependent binary number in a decoding device 29 and actuates one of the switches 18 to 20 in dependence on this supply voltage.

The operation of the first exemplary embodiment shown in FIG. 1 consists in that, at a specific speed n, a specific address y is selected in each of the three memory matrices 15 to 17 . These memory matrices are usually designed as read-only memories (ROM), the number of which is determined by the storage capacity and the number of information to be stored. In the memory matrix 15 , a characteristic line is stored, which is required for a supply voltage of 10 volts. In the memory array 16, a corresponding characteristic for 12 volts, and in the memory matrix 17 for 14 volts.

It should also be noted that in a microcomputer 14 z. B. the decoder 29 and the switching devices 18 to 20 are of course not as such discrete. The selection of one of the stored values x 1 to x 3 is program-controlled, as is the query of the numerical value at the output of the analog-digital converter 28 . A circuit-based implementation as an alternative to a microcomputer is of course also conceivable.

Another application would be e.g. B. the application of the terminal 27 with a signal dependent on the negative pressure in the intake pipe of the internal combustion engine or with the signal of a knock sensor. In this case, the opening of the electronic switch 24 , that is to say the ignition timing, would be controlled via the command line 23 . A certain negative pressure or a certain knock signal would then lead to an adjustment of the ignition timing by switching over characteristic curves.

Another possibility is e.g. B. in setting the changeover points in an electronic transmission control by speed-dependent characteristics. The flow of another parameter could e.g. B. be a temperature-dependent signal at the terminal 27 , so that, for. B. with falling temperature, switching of characteristic lines takes place in the sense that the switching points are relocated to lower speeds.

The second exemplary embodiment shown in FIG. 3 is constructed in accordance with the first exemplary embodiment except for the analog-digital converter 28 . To simplify the illustration, however, many components have been omitted from the illustration. Thus, only the switching devices 18 to 20 are provided in the microcomputer 14 . The threshold levels 30 to 32 are assigned to different threshold values. If the respective threshold value (10 volts or 12 volts or 14 volts) is reached, an output signal is generated at the output of the threshold value stages 30 to 32 concerned . Is z. B. the supply voltage is higher than 14 volts, are at all outputs of the threshold value stages 30 to 32 1 signals, whereby the switching device 18 is actuated via the AND gate 35 , ie GE is closed. If the voltage is between 12 volts and 14 volts, the switching device 19 is actuated accordingly and if it is between 10 volts and 12 volts, the switching device 20 is closed. In the second exemplary embodiment, the decoding device 29 can of course also be included in the software in the microcomputer 14 .

Claims (5)

1. Device for controlling operating parameter-dependent processes, in particular the start of the closing time for ignition systems of internal combustion engines, with a computer and with at least one memory with data, the memory locations (addresses) of which are selected as a function of the respective value of a first parameter and whose selected memory contents be counted, the counting end triggering the process to be controlled, characterized in that the storage locations of the support points of at least two predetermined characteristic curves ( 15 to 17 ) of the first parameter can be selected in parallel by the first parameter (s) and that depending on speed the respective value of at least one further parameter (U) the selected memory content of one of the support points is released for counting. 2. Device according to claim 1, characterized in that the at least one further parameter (U) is converted into a numerical value by which one of the support points ( 15 to 17 ) is selected and released via a decoding device ( 29 ). 3. Device according to claim 1, characterized in that the at least one further parameter value (U) is supplied to a plurality of threshold value stages ( 30 to 32 ) with graduated threshold values, one of the support points ( 15 to 17 ) being selected as a function of the combination of their output values and released. 4. Device according to one of the preceding claims, characterized in that the first parameter is the speed (s) of an internal combustion engine. 5. Device according to claim 4, characterized in that a white further parameter is the supply voltage (U) and the process to be controlled is the start of the closing time for an ignition system ( 23 ).