DE2131762B2 - FINAL CONTROL CIRCUIT - Google Patents

Description

comprises a conventional capacitor 109, generally designated by reference numeral 18, and a transformer designated generally with also further parts for connecting the main parts / designated by reference numeral 20 of the trigger circuit. The transformer 18 has a sättigba semiconductor switch device 104, which here as an npn- c core 22 on which a primary winding 24, 5 transistor is shown, a pair of output electrodes ί a secondary winding 26 and a feedback HO and 112 and a control electrode 114. The development 28 is wound. The primary winding 24 has input electrodes 110 and 112 are connected to the capacitor * · a first terminal 30, which is connected via a conductor 106 between a grounded terminal 116 32 to a terminal 34 . The second and cathode electrodes 90 of the controlled SiIi connection 36 of the primary winding 24 are connected in series via an io ziumrectifier 86. A semiconductor diode 38 with the emitter electrode 40 of the terminal 118 for a key switch can be connected to a transistor amplifier 20. The collector source of positive potential are connected, electrode 42 of the transistor amplifier 20 is connected to which the positive terminal of the storage battery is connected to a point of fixed potential (earth). One of the engine can be. The connection 118 is connected via the connection of the feedback winding 28 is also a resistor 120 and a diode 122 with one if connected to the connection 36 , while the connection point 124 between the output or other connection 44 of the feedback winding 28 collector electrode 110 of the semiconductor switching device via a resistor 46 to the base electrode 48 device 104 and one terminal of the capacitor 106 of the transistor amplifier 20 is connected. The connected. The connection 118 for the key connection 34 can be connected to the positive connection of an ao switch is further connected via a resistor 126 to the DC storage battery which normally belongs to the ungrounded connection 128 of the circuit breaker of the motor. The nega- contacts 108 in connection. This ungrounded antive terminal of the battery is connected to earth. Terminal 128 is further connected to a connection point. A first terminal 50 of the secondary winding 26 130 between the first terminal of a resistor of the transformer 18 is via a conductor 52 with as stands ϊ32, the anode of a diode 134 and the first terminals 54 and 56 of a pair of method a diode 136 in connection. The other capacitors 58 and 60 are connected. The condensate connection of the resistor 132 is connected via a capacitor 58 and 60 are the essential part of the demator 138 and via a conductor 140 with the energy storage circuit 12. The other connection 62 VefbSfldüiigspüfiki or connection 76 in connection, the secondary winding 26 is with the help of a parallel A capacitor 142 is connected via the other connection of a resistor 64 and a diode connections of the diodes 136 and 138, ie via their 66 to the other terminal 68 of the capacitor cathode and anode, respectively. A resistor 144 58 connected, the terminal 68 forming a junction connecting point between the junction point. The cathode electrode of the diode resistor 132 and the diode 134 with the base 66 are connected to the connection point or the connection or control electrode 114 of the semiconductor switching device connection 68 via a conductor 70. A part 104. A resistor 146 is connected between the connection of a resistor 72 and a control electrode 114 and the grounded connection diode 74 is connected between the connection point or 116 of the semiconductor switching device 104,
the connection 68 and the other connection 76 of the control circuit 17 of the system for on / off, wel capacitor 60 arranged, wherein the connection 76 40 is rather enclosed by a dashed line, also forms a connection point. has a first transistor amplifier 148, a discharging circuit 14 for the energy has a zweiien transistor amplifier 150 and coupling load on soft in this case from the Primärwick- resistors 152, 154 and 156 on. The resistor 78 of the induction or ignition coil of the ignition system 152 couples the collector electrode of the transistor system, a resistor 80 being connected in parallel to amplifier 148 with a connection point 158 of the primary winding 78. The parallel between the anode of the diode 134 and a connection of resistor 80 and primary winding 78, the end of the resistor 144. The coupling resistor is connected via a conductor 82 to the terminal 56 and stand 154 connects the emitter electrode of the transi via a conductor 84 to earth. In the storage amplifier 150 with a ground connection 160. The discharge circuit is also a controlled silicon DC 50 ground connection 160 is contained via a diode 162 with the rectifier (SCR), which is generally connected to the connection 118 for the key switch. Reference numeral 86 is denoted and an Anodenelek- Finally, the coupling resistor 156 connects electrode 88, a cathode electrode 90 and the collector electrode of the transistor amplifier 150 control electrode 92 has. The anode electrode to the base electrode of the transistor amplifier 88 is 148. point via a conductor 94 with the connection 55 the emitter electrode of the transistor amplifier 148 or the terminal 76 is connected. The cathode is connected to the positive Anelcktrode 90 with the help of a conductor 164 hangs via a diode 96 with a circuit of the battery,
grounded terminal 98 together. The connection 98 The connection point or connection 36 is further connected via a diode 100 to the connection between the primary winding 24 and the feedback point or connection 76. Next 60 processing winding 28 of the transformer 18 is connected via a resistor 102, the control electrode 92 connects a capacitor 37 with a connection point of the controlled silicon rectifier 86 with the 39, with which a first terminal grounded terminal 98. of a resistor 41 and the anode electrode of an In the Trigger circuit 16, which is connected by a striped diode 43. The cathode of the diode 443 is surrounded by a chelated line, is a semiconductor circuit, generally denoted by 65 and the connection point or terminal 76 with reference numeral 104.

Einridiiung, a capacitor 106, the interrupter After the details of the switching elements and

contacts 108 of the ignition system with an optional, their connections have been shown in detail

7 8

are, the mode of operation of the preferred should now be equal to the residual charge on the capacitor 60,

Embodiment of the invention are considered. the flowing through the secondary winding 26 flows

The general purpose of this system is current through diode 66 and diode 74 to charge

in this. an intermediate voltage during ignition of the capacitors 60 and 58. The parallel to

cycle of the engine ignition system, which 5 of the diode 66 connected resistor 64 serves as

during the next ignition cycle over "the ignition bleeder resistor for the capacitor 58 to one

coil is discharged. The intermediate voltage has a charging of the capacitor in the direction of the induced

of such magnitude that it is caused by the direct transforma- tion voltage during the current flow in the primary

tion of the voltage through the ignition coil to allow sufficient winding. This enables a FHe-

There is ignition voltage on the spark plugs. With this i ° ßen of the secondary current in the direction of the diode pole

Arrangement, the ignition coil will then have a pulse immediately after the transformer

transformer instead of a coil with transformer saturation caused interruption of the

tion, as is the case with known systems. Current flow through the primary winding. The effect

First it should be assumed that the positive resistor 64 as a bleeder resistance reduces tive connection of the battery used in the system then the cut-off voltage, which is connected to the primary circuit with the connection 34, is returned during the winding and via the over-negative connection of the battery is connected to earth between the emitter and collector of the transistor. The power generation circuit 10 operates to the effect that amplifier 20 is applied to an acceptable level, so that battery power is converted into an intermediate voltage, thereby avoiding a voltage breakdown of the transistor which is higher than the *>. .
Voltage of the battery. This higher voltage is in the energy storage circuit 12 is preferably a highly conductive low voltage for later discharge through the primary winding 78 transistor, z. B. a high-current germanium transider ignition coil is stored. The energy generation disturbance By using the semiconductor diode 38 in a circle comprises the transformer 18 and the semiconductor * 5 series with the emitter-base circuit of the transistor of the transistor or transistor amplifier 20. Transistor amplifier 20 contributes to any fault current

When the key switch of port 118 is switched on, it is switched on as a pre-load a current flows through the reverse direction, which incurred another fault 41 and the diode 43 and lets the capacitor flow obstructed. The semiconductor diode 38 is used 60 so. as indicated by the polarity designations in 3o, a fixed residual voltage Fie.l is indicated. If the capacitor is to be provided on> n the feedback circuit in order to

. * ·. * ... _f,. , "H ^ rhrichrn are by the danger of a resonance of the inductance of the

a way like that in the iolßendcn DescnncDcn wliucu _ ....

is discharged via "the discharge circuit 14, the primary winding with the capacitance in the circuit and the

Via the capacitor 37 to catch a current pulse from the occurrence of natural oscillations to a minimum connection 34 of the battery through the primary winding 35.
24. the capacitor 37 and the

SS ^ SSfnÄ- * SS S ₁ St Jm'lSCR) 86. whereby ⁸ the capacitor & according to each-StromflS through the primary circuit induces the ignition process w, edc, aul the desired potential

ac tension in the K ^^ g ™ ^ * "'' ^ ftdemL 72 serve, in addition to the charge

! ATE AS Ä S53S ^{60 bld} '

! ATE soiAS Ä SL53S35

... -τ- r „ί ,,, Λ riift Her Transi- auscescnaiiei wiru.

information on the transformer ^ that the! ^^ ^ _{pri? g the}

super strong 20 «" ^. ^^^^ dV 45 switched resistor 80 is a protective resistor,

TH ^an H ff sera current flow through which a discharge path for the capacitors m ... MCh thereby "a larger £ ™ ^m " _{g 58 and 60 for the case that the Plimärwick provides} .

the expensive 32 ^d «^ ™ ^ ^^ Trtnsistorver- lung 78 is opened or switched off. The Wen oyun Hey E ^m itter-Kollektontrtcke d 'ra _{resistance 80 fet so mt that the teuert £}

Stauers 20. So .st to ^c ^^ ^d \ f _T ^ _e JX _e 50 silicon rectifier 86 during a maximum lun ^ winding and the tra s.Mo atf | Period of time and with a minimum of Verrin _g to chan _E

Wc ,, working to eme fastSat ^ uig ^ _A ^ _the ^^ ^^^^

formators 18 with sf ^ ™. ^ ™haben ^ and the so that the energy generation circuit does not trigger

Stroin flow through * c ^p nmar ».cklun ^ _Transforma . ^ _n ,, _{while the} capacitors 58 and 60 on a transistor amplifier 20 have a substantial voltage _{at point 55.} With a

torkcm near ^d " ^S f" e ^u "8 '^ y ^ - ₂ 8 generated bordered charge on the capacitors will you

which is ^{reduced by the R} _t ^uckko g ^u Sch. Cut-off voltage in the primary winding of the

Feedback current ¹ J ^ Jf ¹ J, _aeT | _tr om hears formators 18 at the end of the regeneration cycle

The 1 rans.stor then switches off, _{brought to a minimum by h} f _{er durch dne} \.

on dh d primary winding YES to Sdhhl

^^ _{g rdu}

on. through the primary winding YES to _We " _{6o voltage breakdown of} the transistor of the transistor

During this Penode the rain ^ ^ _st prevent orverstärkers 20th

^ ^ _St prevent orverstärkers 20th

young before the ^ ^f ° ™ ^ Ser stream. As soon as the control and discharge circuit 14 which before

Secondary winding 26 a * J "JJ? ™ _{M info} i _ge enclosed by a dashed line, dieni

the current through the P "P ^^ p" f _märwi cklung in order to dissipate the saturation on the capacitors 58 and 6C, the in oer r _secondary wind. 65 stored charges through the primary winding

Ductively stored energy aui ua ^ ^^ _{7g def ignition coil when the} ^^ ne SiTizrara-

treatment 26 is transformed and "« · "" J ⁸ J, " _Kon capacitor rectifier 8δ is controlled to be conductive. In detail

66 and the conductor 70 to the _condenser 58 flows when the controlled silicon rectifier 8 «

58. If the charge aur aem - «wvwroi

9 10

is switched on and thus a lower impedance is represented by the resistor 126 and the diode 134 and represents the charge on the capacitor 60 for charging the capacitor 142. A current flows on circuit 76 through the conductor 94 and from the anode through the resistor 144 and through the base electrode 88 to the Kathodenelcktrodc 90 of the controlled emitter path, ie from the control electrode 114 erten silicon rectifier 86, through the diode 96 5 to the output electrode 112 of the semiconductor switch and the conductor 84, through the primary winding 78 of the direction 104 , which is connected in parallel to the resistor 146 ignition coil and the conductor 82 to the other terminal. The various values of the switching 56 of the capacitor 60. By using the elements are chosen so that there is a rise in the diode 96. whose cathode is connected, as shown, to the earth conductivity of the transistor or the semiconductor. A negative pulse to the trigger ίο switching device 104 results, which a fast like the controlled silicon rectifier in the conductive current flow from earth through the resistor 102, the tendency to be used. Control electrode 92 to the connection point on the silicon controlled rectifier 86 is switched on cathode side of the silicon controlled rectifier, when the cathode electrode of the DC 86. by the capacitor 106 and the transistor richtcrs a negative pulse from the capacitor 106. 15 or the semiconductor switches direction 104 to the earth in the trigger circuit 16 is supplied. ensures. Once the capacitor 106 discharges, when the cathode electrode is open, the output or collector electrode 90 of the silicon controlled rectifier 86 remains a negative pulse applied to the transistor or semiconductor switching device, a current from the generator 104 im essentially at ground potential in order to connect to terminal 98 through the resistor connected to control electrode 20, that changes in the voltage from trode 92 of the rectifier key switch prevent re-triggering of the controlled 102. As mentioned above, this switches the controlled silicon rectifier 86 in open bottom silicon rectifier and allows the flow breaker contacts 108 cause a much larger discharge current from said When the breaker contacts 108 again geKondensator 60 closed by the rectifier and 25 is the charge on the Kondie primary winding 78 of the ignition coil. capacitor 142, the line in which the Bastskreis Since the ignition coil by itself is inductive, the transistor or the Halbleiterschaltcinrich.ung 104 can not directly maintain the current flowing after the decision for a predetermined limited period of time, Uli charge capacitors 58 and ÖÖ stop. The current "comes to rest around the breaker contacts" continues to flow until a peak countervoltage 30 and thereby difficulties to switch off occurs on the capacitors 5S and 60. In this case, which would otherwise occur due to contact bouncing. Only the capacitor 60 reverses the direction after this point The flow of current through the transi-diode 102 ceases until it is charged in the forward direction to a disturbing voltage or the semiconductor switching device 104. voltage which is a function of the FIGS the diode 134 blocks any current flow back to this vibration cycle recovered un- the interrupter contacts. When the Halbleiterverbrauchten energy. While the counteracted switching device turned off 104, the Konsetzten current flow is the controlled silicon capacitor 106 again in the above-described rectifier 86 non-conductive made and since the way across the resistor 120 and the diode 122 pulse removed from its control electrode 92 has been charged 4 °. The diode 122 gives a blocking effect, is. it turns off and keeps the remaining charge on the which allows the capacitor 106, the capacitor 60. The capacitor 58 is, however, loaded highest on this circuit during the period of in the reverse direction, closed to the removal breaker contacts 108 applied from i bergangsspannungen of the Assume energy generation voltage. This gives an advantage to support supply circle 10. Resistor 132 45 in cold weather, especially when starting the engine, and capacitor 138 act to decrease when the battery voltage is at its lowest point just prior to the initiation of the re-application of potential to the controlled one.

Silicon rectifier 86 for the purpose of triggering. The diode 136 serves as a shunt for signals I am reliably triggering the controlled high potential, which ensures the high spark positive required by the distributor during equalization 86 under all operating conditions 5 ° of the periods. a trigger circuit 16 with negative potential could be returned. She shooks the impulse provided. As shown, the diode 134 resists voltage breakdown. Btt Triggerkieis of the resistor 120. The diode some motor vehicles may be recycled to the condenser 106. resistor 102 to the ignition circuit 122. residual stress when the engine of the diode 96 and the Halbleiterschalteinrichrung runs 55th This can be fed to the voltage comparison circuit 104, which generates a basic ignition pulse which is generated by the charging lamp, while the resistor 126, the lower part of the instrument panel works, the breaker contacts 108, the diode 134, the diode 136, and shows the charging process in the power generation system the resistor 144. the resistor 146 and the d -s motor is used. It has been shown that "this capacitor 142 can have the conductive state of the half- &> voltage a sufficiently high value, control conductor shading device 104. A sufficient charging current in the capacitor When the key switch of the terminal 118 106 is switched on for further ignition of the controlled silicon A current also flows through the rectifier 86. In order to overcome this difficulty resistor 120 and the diode 122 through the capacitor, the control circuit 17 for on-off capacitor 106 and the diode 96 around the capacitor 65 are seen. The control circuit 17 contains a span 106 to load the interrupter contacts 108 voltage comparison circuit, which scans when the closed stad. Weao dk interrupter contacts of voltage from the key switch are present, a current flows from the terminal 118 of the correct reference value : rt compared to the battery

11 12

voltage drops. When this occurs, current flows con - The in FIG. 2 time delay circles

Continuous to the base of the transistor or the semi-conductor switch device 104 and prevents sin over a certain low speed range of the reloading of the capacitor 106, which decelerate the Sy motor and are switched off above the gcgebestem. 5 effectively cut off the speed range.

When the key switch is on, a transistor 166 is in the base circuit of the

a current through the junction between the base and transistor or the half-transistor switching device 104 emitter of the transistor amplifier 150 and brings the added. As a result, the emitter-collector is in a conductive state. Since in the base circle section of the transistor 166 in series between the transistor there is no resistor is io resistor 144 and the base or control electrode of the voltage across the resistor 154 in the transistor or essential 114 Halbleiterschalteinrichchen equal to the battery voltage. A resistor 104 is connected. The base electrode of the transistor 151 is used to stabilize the "off" state of the stors 166 is connected with the aid of a conductor 168 with a transistor amplifier 150 when the key switch connection point 170 , with which a ter to the terminal 118 is open, and the diode 162 15 first connection of a resistor 172 and one shunt for induced junction resistance 174 is connected. The other Ansignale which open when the key switch circuit of the resistor 172 is connected to earth may occur, to a destruction of the transis- while the other terminal of the resistor to prevent storverstärkers 174,150. with the emitter connection of a transistor 176 when the voltage of the key switch is substantially bound. The base electrode of the transistor 176 Hch drops below the battery voltage, a current is connected via a resistor 178 to the connection from the terminal 34 of the battery through the crossover point 130 . The collector electrode of the gang between the emitter and base of the Transistorver- transistor 176 is connected via a variable amplifier 148, through the resistor 156, through the resistor 180 with the connection of the key collector-emitter path of the transistor amplifier 25 switch. Finally, a 150 connects and through the resistor 154 to the earth capacitor 182 the collector electrode of the transi-circuit 160 flow. This results in a flow of current interfering with 176 with connection point 130.
through the emitter-collector path of the transistor - The transistor 166 is when the inter-

Amplifier 148 through resistor 152 and breaker contacts 108 do not conduct until the voltage through resistor 144 to the base circle of Tran 30 across resistor 172 is sufficiently small. to sistor or the semiconductor switching device 104. The- a sufficient current flow from the lower current flow is under the assumed conditional breaker contacts 108 through the diode 134, through continuous and prevents charging of the resistor 144, through the junction between capacitor 106, since the normal charging current for emitter and bpsis of transistor 166 and through the capacitor 106, which normally through 35 resistor 172 to give ground. The flow of current flows through the resistor 120 and the diode 122, via emitter-base path through the transistor 166, the collector-emitter path of the transistor or decreased by the emitter-collector path of the semiconductor switching device 104 to ground next to the transistor 166 Imr ° .danz shown so that one is closed. If the voltage of the key base current for the transistor or the semiconductor switch is zero, no current can be provided from the key switch device 104 . With a switch to the capacitor 106 flow, and the tran- such base current, the transistor or the transistor amplifiers 148 and 150 only need to be conductive between the semiconductor switching device 104 and operate at a predetermined voltage level of the key in the context of FIG. 1 below the battery voltage in such a way as to cause the controlled T: silicon voltage level to fire, which is necessary for triggering the controlled rectifier 86,
Erten silicon rectifier 86 into conduction inlet A delay in the conduction of transistor

was no longer enough to work. 166 is caused by a charge on the con-

It should be noted that by connecting capacitor 182 through transistor 176 and circuitry from terminal 34 of the battery to resistors 174 and 172 flows when sub-junction 158 of capacitor 50 breaker contacts 108 are close to battery voltage 142 and 142 the resistor 152 is common, this (breaker contacts open). The resistor 178, capacitor 142 as a filter for all transitions causes the transistor 176 to be conductive when pulses of short duration act, which are opened in the key contacts 108 and switching circuit are introduced, and to conduct non-conductive when the break contacts gedes transistor amplifier 148 could lead when 55 are closed.

the engine is running and overall the breaker contacts when the breaker contacts 108 closed

are closed. becomes the connection point of the capacitor

In some applications, it may as desires 182 and be of the resistor 178 to ground potential, prove worth seeing, means for controlling and the capacitor 182 is a Geschwindes point in time in the cycle at which the overall load velocity 60 represented by the RC-Zeh controlled silicon rectifier 86 is ignited, pre-constant of resistor 180 and the capacitor watch, so as to determine the possibility of a "quiescent" or "tor 182" . Assuming that the charge is to have delayed ignition of the motor. FIG. 2 shows that on capacitor 182 is sufficient to add the manner in which a small number of parts to the voltage across resistor 172 of the blocking system of Figure 1 can exceed 65 layer voltage of transistor 166 to this feature In Figure 2, transistor 166 will be kept non-conductive with portions identical to those shown in Figure 1 until capacitor 182 is nearly discharged n have the same reference numerals as in FIG. 1 referred to. is. The capacitor 182 continues to deliver power until it

13 14

is loaded in reverse. With this inverted lasis the transistor 186 conducts and a current through the

tion becomes when the quiescent time is insufficient to the base-emitter piece of transistor 186 and through

Achieving a charge in the forward direction on the capacitor 182, a diode 198. the Kollck-

Capacitor 182 is a delay in the trigger-emitter section of transistor 176 and the

like the transistor or the semiconductor switching device 5 resistors 172 and 174 can flow to earth. the

development 104 occur. The resistor 174 is a stabilizing effect on the discharge of the capacitor 182 is

The setting and limiting resistor to control the as described above. The collector circuit of the transit

Of charge flow from capacitor 182 to ground. stors 186 keeps current flowing through the transistor

The "provided by the circuit of Fig. 2" is maintained. Once the capacitor 182 is discharged, the delay is in cranking and at low, and thereby conduction of transistor 166 and speed is useful in providing an ignition delay firing the circuit allows the current to flow through the capacitor 182 until it is charged in reverse starting and controlling the exhaust output in reverse. If the capacitor prevents idling. The circuit can thus be reversed The transistors are switched off so that it switches off at every desired rotation and the capacitor 182 begins: < Point control during acceleration and Ar- through the resistor 180. the condensate Adopt earth, load. If the loading speed iiUT ^ Jk -;,! One factor in balancing circuit 20 is. around a charge in the forward direction,. ·. ■: afterwards Fig. 2 is the rest time, ie the duration. To reach capacitor 182, it is /; ■, ■, κτ .. during which the breaker contacts between occurrence of a delaying effect do '.-:>, ν_, _1Γι the ignitions expressed in degrees of the breaker contacts in the next / i: -. . ,, k., partial power or as a percentage of the time between opening. When the charging speed wedge njn:, · ... the ignitions are closed. The execution «- 25 is enough to create a La-Jung in Vorwärtsrichtuivj : tn \ , Umform nach Fig. 3 shows a similar circuit for effecting capacitor 182, the Si /!>.;! Umg for controlling the ignition timing of the controlled Si has no effect on the ignition timing. Since the silicon rectifier 86. in which, however, the quiescent recharge of the capacitor 182 in \ ui \ v: -
time is no longer a factor for the comparison. In Fig. 3 direction begins as soon as it is discharged. hu,! ic are again those parts which, even together, have no effect on the delay; context with F i g. 1 and 2 have been described. The diode 198 \ prevents. that the other way round. um with the same reference numerals as used in these two applications of the capacitor 182 immediately across the WVki figures. stands 192 and 190 and the transition from the B.- ,,

"The circuit according to Fig. 3 is the na-h Fig. 2 is discharged to the collector of transistor 176,
quite similar, with the exception of an added 35 circuit which od the preferred Ausluhzusätzlichen pair of transistor amplifiers: r approximate shape of the invention forms and wherein an transistors 184 and 186. Transistors 184 un i transistorized control of the trigger circuit for the 186 may provide an apparatus With multiple Üh.r- controlled silicon rectifiers used, or alternatively two devices with two gives more positively shaped pulses for triggering and transitions. The emitter electrode of the transit 40 has the advantage of "holding off" the invhstors 184 is connected to the connection point 130 and the most voltage available during starting. The base electrode is connected via a resistor 188 to the Collective conventional capacitor across the sub-gate electrode of transistor 184 is connected to the base bred contacts in the ignition system, whereby the electrode of transistor 186 and via a resistor system 190 easily from a "discharge ignition" is connected to earth. Conventional ignition for maintenance of the system trode of transistor 186 can be switched to the base electrode. Further is connected by a fixed of transistor 184. A resistor 192 delay in restoring the charge connects the emitter electrode of transistor 186 to capacitor 106 the effect of a contact with it its base electrode e, and the emitter electrode 5 ° bouncing is not only screened out, but also completely unteides transistor 186 is pressed with a first terminal. Double ignition of the controlled suicide capacitor 182 for the time delay converters is therefore avoided. In addition, the circuits for modifying the ignition timing

The collector electrode of transistor 186 is at the point shown in FIG. 2 and 3 a special delay

except for the connection to the base electrode of the 5S riinpfunktinn. which to adapt to the special

Transistor 184 is adjustable via a resistor 194 and the requirements of the motor.

a capacitor 196 connected to ground. While a preferred embodiment of the

As mentioned above, the circuit of FIG. 3 invention has been described and illustrated is

the circuit according to FIG. 2 very similar. In addition, it is clear to the person skilled in the art that various modifications

the transistors 184 and 186 are provided in order to be able to ^{carry out 6o functions and changes,}

the beginning of the recharge of the capacitor 182 if, for example, a positive earth system is desired

to enable, as soon as it is initially due to the ("mi- it is advantageous to connect the capacitor 60 via

nens the breaker contacts has been discharged. a controlled half-clock switch (SCR) 86

When the breaker contacts open, an earth flows instead of through the primary winding of the ignition

Stroni through the junction between the emitter and 65 coil. In this way, damp

Base of transistor 184. through resistor 194 speed or fault current wcgc to earth on the primary

and capacitor 196 to ground. This causes the ignition coil to not discharge the winding

that the transistor 184 lead via its collector to the Ba capacitor 60 between the ignitions.

it 15, _p ., _vcd er negative or positive under

lek- ΐ

The ΐ Einric

ί is t

nsi- ΐ _this ! smooth drawings

sior ΐ

• ei- j

ge ■;

en ■; int
gate

Claims (8)

Patent claims: 1. Ignition control circuit for an internal combustion engine with a voltage or energy generation circuit, which with a direct current source with a first potential for generating a Output voltage is connected to a much higher potential, one to the output of the voltage or energy generation circuit related energy storage circuit to at least temporarily storing an electrical charge. Facilities with a triggerable Switching device for switching the energy storage circuit in series with the primary winding an induction coil and one responsive to the opening and closing of the ignition breaker contacts Trigger circuit for supplying no trigger signals to the triggerable switching device such that the 1 in the energy storage circuit flows through the primary winding for a predetermined period of time when the triggerable switching device receives a trigger signal, characterized in that the voltage or energy generating circuit (10) has a sättigjaren transformer (18) with a Primary and a secondary winding (24, 26) and devices for direct connection of the Primary winding with the direct current source with the one potential (34) contains, and that the Trigger circuit (16) comprises a semiconductor switching device (104) having a pair of output electrodes (110, 112) and a control electrode (114), a first connected in series with the pair of output electrodes and a control electrode Capacitor (106), a second in series with the pair of output electrodes and the triggerable switching device switched capacitor, devices for connecting the Control electrode with the ignition breaker contacts (108), and devices for charging the second capacitor to a predetermined voltage when the ignition breaker contacts (108) are closed and for making the semiconductor switching device conductive when the ignition breaker contacts are open. 2. The ignition control circuit of claim 1, wherein the saturable transformer comprises a primary winding, a secondary winding and a feedback winding, a semiconductor current control device with a first and a second electrode and a control electrode, means for connecting the first and second electrode in series with the primary winding and across a source of direct current by means for connecting the feedback winding (28) to the control electrode (48) so that when flowing of a current pulse through the primary winding (24) creates a voltage in the feedback winding (28) is generated to prevent an additional current from flowing through the primary winding (24) and to enable the semiconductor power control device in a regenerative manner and a To generate voltage of high potential across the secondary winding. 3. ignition control circuit according to claim 2, characterized in that the energy storage circuit (12) is connected to the secondary winding (26) and at least one capacitor (58. 60) with first and second connections, means for connecting one of the connections (54, 56) with one connection (50) of the secondary winding (26) and one which conducts current in one direction Means (66, 74) which the second connection with the other connection (62) of the Secondary winding connects. 4. ignition control circuit according to claim 1, 2 or 3, characterized in that the triggerable Switching device from a controlled silicon rectifier (86) with a first and second Electrode and a control electrode (92) consist: the first and second electrodes in friction: connected to the primary winding of the induction coil (781 and the energy storage circuit (12) -, are and means for connecting the; · control electrode with the. Trigger circuit (16) provided are. 5. ignition control circuit according to claim 1, 2 or ", characterized in that the triggerable switching device comprises a triac which has a pair of output electrodes arranged in series; with the primary winding (78) of the induction coil and the energy storage circuit (12) happened α, and one connected to the trigger circuit Has control electrode. 6. ignition control circuit according to claim 1, 2 or ^:. characterized in that the control electrode (114) with the ignition breaker contacts. (108) connecting devices have a time delay network (Fig. 2 or 3) to the holder, the semiconductor shell device (104) in the non-conductive state for a predetermined period following the opening of the ignition breaker contacts. 7. ignition control circuit according to claim 1, characterized by one with the direct current source connectable terminal (118) of an ignition key switch, the ignition control circuit having a Comparator circuit (148, 150), which with the direct current source and the connection (118) of the ignition key switch is connectable to sense when the voltage at the terminal of the ignition key switch falls below a predetermined threshold value, and means (158) for connecting the output of the comparator circuit to the trigger circuit (16) for suppression of its operation as long as the voltage at the ignition key switch is less than the Threshold is. 8. Apparatus according to claim 7, characterized in that the comparator circuit contains a first and a second semiconductor amplifier (148, 150) each with a pair of output electrodes electrodes and a control electrode, means for switching the pair of output electrodes of the first semiconductor amplifier (148) in series between one terminal of the direct current sources and the trigger circuit (16), means for switching the output electrodes of the second Semiconductor amplifier (150) between the control electrode of the first semiconductor amplifier (148 and the second connection of the direct current source! and means for connecting the rudder electrode of the second semiconductor amplifier (150) tet. that during an ignition control cycle of the system with the connection (118) of the ignition key switch an intermediate voltage is generated, which then ters. via the ignition coil during the following ignition control cycle is discharged. The intermediate tension 5 has a much higher potential than the potential the battery of the motor, but it is also much less than that across the secondary winding of the Ignition coil developed voltage. This intermediate The invention relates to an ignition control voltage has such a value that the spark plug circuit for a Bronn engine with a tension io z the engine sufficient ignition voltage through di- tion or energy generation circuit, which with the right transformation of the voltage levels through the a direct current source with a first potential ignition coil is supplied, so that the ignition coil in the to generate an output voltage with essentially a pulse transformer instead of a coil lent higher potential is connected to one who works with transformation. Output of the voltage or energy generation 15 The system according to the invention has the advantage Kreises related energy storage dal 'with different battery states of charge a circuit for at least temporarily storing an electrical essentially constant energy transmission Charge, facilities with a tripgerba- can be maintained. “Veiter makes the ver. cn switching device for switching the energy turn of a transistorized trigger circuit for storage circuit in series with the primary winding 20 to discharge the stored energy an induction coil and a semiconductor switch used on the open and the ignition coil Closing the ignition breaker contacts respond to the formed pulse for triggering, growing Trigger circuit for supplying trigger signals, which in turn generate a high level during the start signal to the triggerable switching device in such a way that sens makes available ignition voltage available, that the charge in the energy storage circuit is predetermined for a further by providing a variable time Period of time through the primary winding delay control for the Tiiggerkreis a special flow. if the triggerable switching device reaches another "delay" function, which for Trigger signal received. Adaptation to the special requirements of the mo- Such an ignition control circuit is e.g. already gate adjustable. by the United States patent specification 3,383,555 been. the trigger part of the circuit is a diode in the small The invention is based on the object of a capacitor circuit to the trigger during central regeneration of one of the voltage changes described above to stabilize which select-ignition control circuit occurring directly from the DC power source and around accordingly or battery to achieve a full recovery 35 the highest battery voltage during the crank generation to achieve during each ignition cycle, to detect the occurrence in order to achieve optimal triggering whereby this property cannot be ensured by vibrating. Tensions, which are necessary for the formation of pulses According to the invention, an adaptation is made to the lead that at high speeds normally bouncing of the ignition breaker contacts by the fact that not to a full recovery of discharge 40 in the base circuit of the trigger transistor a delay tension should be restricted. tion is provided to generate a dead time. Of the This task is done with an ignition control circuit. Trigger circuit is blocked until this bouncing is over of the type described at the outset according to the invention. solved by the fact that the voltage or energy generator enables the inventive sygungskreis a sätiigbaren transformer with a 45 star, unused energy from the ignition coil for each primary and a secondary winding and Einrich- to recover the following cycle.
Embodiments of the invention are shown in the drawing with the direct current source with the one potential for direct connection of the primary winding and are described in the following, and that the trigger circuit comprises a half described. In the drawing shows
Conductor switching device with a pair of output elec- 5 ° F i g. 1 is a schematic cut-away diagram of a frontrcden and a control electrode, a first embodiment of a capacitor discharge series with the pair of output electrodes and ignition ignition circuit according to the invention,
a control electrode switched capacitor, Fig. 2 a variable ignition delay circuit, ge a second in series with the pair of output electrodes suitable for use in the trigger network and the triggerable Sehalteinrichtung ge 55 of Fig. 1, and switched capacitor, devices to connect F i g. 3 an alternative arrangement for the variable that of the control electrode with the ignition interrupter blen ignition delay circuit according to FIG. 2. contacts and facilities for charging the two Tn F i g. 1 of the drawing is a schematic th capacitor to a predetermined voltage. Circuit diagram of the capacitor discharge ignition circuit when the ignition breaker contacts closed shows 60. This circle includes one with a dashed and are enclosed to make the half-liter switched line conductive device when the ignition breaker contacts are often enclosed in a dashed line fen are. Energy storage circuit 12, one with a dashed line Developments and expedient execution line enclosed discharge circle 14, one with a Forms of the invention emerge from the trigger circuit 16 enclosed by a dashed line chcn2bis8. and one enclosed in a closed line The invention is concerned with a solid-state control circuit 17 for on / off. Capacitor discharge ignition unit, which works as part of the system