US3424944A

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Publication number: US3424944A
Application number: US593042A
Authority: US
Inventors: Ole K Nilssen
Original assignee: Ford Motor Co
Current assignee: Ford Motor Co
Priority date: 1966-11-09
Filing date: 1966-11-09
Publication date: 1969-01-28
Anticipated expiration: 1986-01-28
Also published as: DE1539207A1; GB1135370A

Description

Jan. 28, 1969 0. K. NILSSEN 3,424,944

ELECTRONIC IGNITION SYSTEM USING MULTIPLE THYRISTOBS Filed Nov. 9, 1966 Sheet of 2 0L E K N/L SSEN F/G-Z INVENTOR.

Jan. 28, 1969 1 0. K. NILSSEN 3,424,944

ELECTRONIC IGNITION SYSTEM USING MULTIPLE THYRISTORS Filed Nov. 9,. 1966Sheet 2 of 2 F/GA 0L 5 K. N/L SSEN INVENTOR.

AT7URNEV5 United States Patent 3,424,944 ELECTRONIC IGNITION SYSTEM USING MULTIPLE THYRISTORS Ole K. Nilssen, Livonia, Mich., assignor to Ford Motor Company, Dearborn, Mich, a corporation of Delaware Filed Nov. 9, 1966, Ser. No. 593,042 US. Cl. 315-409 8 Claims Int. Cl. Hb 37/02, 41/36 This invention provides an electronic ignition system for an internal combustion engine in which a first thyristor controls current flow through an ignition coil primary winding and a second thyristor turns off precipitously the first thyristor in timed relationship to the engine. The ignition system can be made inexpensively from rugged components suitable for use in engine compartments and maintains initial accuracy throughout its long service-free life.

Most present day ignition systems for internal combustion engines use breaker points to control directly the electrical current through the ignition coil primary winding. The sudden change in current occurring when the breaker points open induces voltage in the coil secondary winding that is distributed to the appropriate spark plug. The average life of the breaker points is held to about 10,000 miles of vehicle operation by the high amounts of current and its highly inductive nature. Electronic ignition systems in which the breaker points control electronic switching devices that in turn control the current through the coil primary have been used on a limited scale along with a few more recent breaker-less electronic systems. High costs and the delicate nature of the components in these electronic systems combined with the harsh engine compartment environment prevent widespread commercial acceptance of these prior art systerns.

This invention provides an electronic ignition system made almost entirely of rugged, inexpensive components. Relative to many prior art systems, the number of components also is reduced, thereby decreasing even further the initial investment. The ruggedness of the components insures excellent service-free accuracy lasting in many cases throughout the life of the basic engine components.

In an ignition system of this invention having a source of electrical energy and a coil with a primary winding and a secondary winding, a first thyristor is connected in series with the coil primary winding, a second thyristor has its cathode coupled to the cathode of the first thyristor, and a capacitor couples the anodes of the thyristors. A transformer has its primary winding in series with the coil primary winding and its secondary winding connected to the capacitor. A two-stage trigger a-ctuatable by rotating parts of the engine turns on the first thyristor during one stage. Current begins in the coil primary winding and the transformer primary winding, inducing a charge on the capacitor from the latter.

When the trigger switches to its second stage, the second thyristor turns on to discharge the capacitor through the first thyristor in a direction that turns off the first thyristor precipitously, thereby abruptly halting the flow of current through the coil primary winding. Voltage thereby in the coil secondary winding is applied to an appropriate spark plug. The trigger then returns to its first stage and the above cycle repeats itself.

Details of construction and operation along with other advantages of this ignition system are presented below in connection with the drawings in which:

FIGURE 1 is a schematic diagram of an ignition system of this invention using breaker points as the trigger;

FIGURE 2 is a schematic diagram of a breakerless ignition system of this invention using an oscillator con- 3,424,944 Patented Jan. 28, 1969 trolled by a rotating vane as the trigger and as a charging means for the capacitor;

FIGURE 3 is a perspective view of the rotating vane used in the trigger of the FIGURE 2 schematic; and

FIGURE 4 is a cross-sectional view alongline 44 of FIGURE 3 showing additional structural details of the rotating vane and a feedback transformer used in the oscillator.

Construction 0] FIGURE 1 A battery serving as the source of energy is represented generally by thenumeral 10 in FIGURE 1.Battery 10 has apositive terminal 12 connected through an ignition switch 14 to apositive buss lead 16. Thenegative terminal 18 ofbattery 10 is connected tonegative buss lead 20 and to ground at 22.Battery 10 typically produces a no load potential of about 12 volts.

An ignition coil 24 having aprimary winding 26 and a.

secondary winding 28 has one side ofsecondary winding 28 connected to ground at 30. The other side ofsecondary winding 28 is connected to the rotating arm 32 of a distributor assembly 34. Ann 32 sequentially connects one of a plurality ofspark pulgs 36 tosecondary winding 28.

One side of coilprimary winding 26 is connected through aresistor 38 tobuss lead 16. The other side of coilprimary winding 26 is connected to the dotted terminal of the primary winding 40 of asaturable core transformer 42. Alead 44 connects the undotted terminal of winding 40 with theanode 46a of a silicon controlledrectifier 46, the first thyristor.Cathode 460 ofrectifier 46 is connected tobuss lead 20.

Secondary winding 48 oftransformer 42 has its undotted terminal connected tolead 20 and its dotted terminal connected to the anode 50a of adiode 50. Alead 52 connectscathode 50c ofdiode 50 withanode 54a of a silicon controlledrectifier 54, the second thyristor. Cathode 540 ofrectifier 54 is connected tolead 20. Acapacitor 56 has one side connected tolead 44 and the other side connected to lead 52 socapacitor 56couples anode 46a withanode 54a.

A trigger indicated generally by thenumeral 58 comprises acam 60 rotated through conventional gearing by the engine. Dotted line 62 represents the conventional mechanical connection betweencam 60 and arm 32. Anarm 64 having a contact 66 at one end is movable bycam 60 so contact 66 moves into and out of touch with anadjacent contact 68. Alead 70 connectsarm 64 with one side of aresistor 72 that has its other side connected tolead 20.

Contact 68 is connected to a lead 74 that is connected through a resistor 76 to lead 16. Acapacitor 78 has one side connected to lead 74 and its other side connected to a lead 80 that is connected through aresistor 82 to lead 20. Gate 46g of controlledrectifier 46 is connected tolead 70 and gate 54g of controlledrectifier 54 is connected to lead 80.

Operation of FIGURE 1Windings 40 and 48 are arranged intransformer 42 so current into a dotted terminal of a winding induces current going out of a dotted terminal of the other winding.

Assume that ignition switch 14 is closed and the engine is turned over socam 60 moves contact 66 into touch withcontact 68. The positive voltage inlead 70 is applied to gate 46g, thereby turning on controlledrectifier 46. Conventional current begins inresistor 38, coilprimary winding 26, transformer primary Winding 40, and controlledrectifier 46. This current is low initially because of the self-inductance of winding 26 but eventually the current increases to a value limited byresistor 38, typically about one ohm.

The current through winding 40 induces a current at the dotted terminal of winding 48 that is applied throughdiode 50 to the side ofcapacitor 56 connected withlead 52. A typical primary winding 40 has turns of 16 AWG wire, and a typicalsecondary winding 48 has 100 turns of AWG wire.Diode 50 can be No. 1N1564 and auseful capacitor 56 is one having a rating of 0.5 microfarad at 150 volts. Current continues intocapacitor 56 untiltransformer core 42 saturates.Transformer 42 is saturable so the charge built up oncapacitor 56 is constant regardless of engine speed. Ordinarily,capacitor 56 attains a charge of about 120 volts.

Continued turning ofcam 60 eventually separates contact 66 fromcontact 68.Resistors 72 and 76 typically are about 50 ohms each, respectively, when a 12 volt battery is being used, so the amount of current broken bycontacts 66 and 68 is very low. Ascontacts 66 and 68 separate, the voltage in lead 74 rises rapidly to battery terminal voltage and the voltage inlead 70 drops rapidly to ground potential. The increased voltage in lead 74 produces a positive pulse that is applied throughcapacitor 78 to lead 80 and to gate 54g of controlledrectifier 54. This pulse turns on controlledrectifier 54 and the charge built up oncapacitor 56 is applied through controlledrectifier 54 to thecathode 46c of controlledrectifier 46, thereby turning off controlledrectifier 46. The collapsing field in coil 24 produces a secondary voltage in secondary winding 28 that fires theappropriate spark plug 36. Current in winding 26 reverses its direction momentarily so electron current now passes into the dotted terminal of winding 40, thereby resetting the saturable core oftransformer 42.

Subsequently,cam 60 moves contact 66 into touch again withcontact 68. The potential of lead 80 falls while the potential inlead 70 rises to some positive value that is applied to gate 46g, thereby turning onrectifier 46 to begin again current throughresistor 38, winding 26, winding 40, andrectifier 46.

Construction of FIGURES 2, 3 and 4 Numerals introduced in FIGURE 1 are used to designate the same components in FIGURE 2. In addition, the connection of components numbered 10 through 38 is the same in the FIGURE 2 circuit as the FIGURE 1 circuit and will not be repeated here. In FIGURE 2, lead 44 connects coil primary winding 26 directly toanode 46a of controlledrectifier 46.Cathode 460 is connected to buss lead 20.Capacitor 56 is connected betweenlead 44 and lead 52 that connects withanode 54a of controlledrectifier 54. Cathode 540 ofrectifier 54 is connected to buss lead 20.

Trigger 58 in the FIGURE 2 circuit comprises an electronic oscillator made up of atransformer 84 and a transistor 86.Transformer 84 has a substantiallycircular core 88 that has agap 90 therein. A primary winding 92, secondary winding 94, and tertiary winding 96 are wound oncore 88.

A lead 98 is connected through a resistor 100 to lead 16. The dotted terminal of primary winding 92 is connected to lead 98 and the undotted terminal of winding 92 is connected to the collector 86c of transistor 86. Emitter 86e connects with aresistor 102 that is connected through aninductor 104 to buss lead 20.

Secondary winding 94 has its dotted terminal connected to base 86b of transistor 86. The undotted terminal of winding 94 is connected to a lead 106 that is connected through aresistor 108 to lead 16 and to theanode 110a of adiode 110. The cathode 110s ofdiode 110 is connected to lead 20.Diode 110 preferably has a relatively high capacitance so it constitutes a low AC impedance fromlead 106 to lead 20.

Tertiary winding 96 has its undotted terminal connected to lead 20 and its dotted terminal connected to the anode 50a ofdiode 50.Cathode 50c ofdiode 50 is connected to lead 52 and is thereby connected both tocapacitor 56 andanode 54a.

Gate 46g of controlledrectifier 46 is connected through a resistor 112 to lead 20 and through a capacitor 114 to a lead 116 that connects with emitter 86e. Gate 54g ofrectifier 54 is connected through aresistor 118 withlead 20 and through a capacitor 120 withlead 98. A capacitor 121 connects lead 98 withlead 20.

Atiming device 122 comprises a cup-shapedvane 124 mounted on ashaft 126.Shaft 126 is driven by conventional means from the engine camshaft (not shown) and dottedline 128 represents a mechanical connection betweenshaft 126 and arm 32.Vane 124 has aweb 130 made of a diamagnetic material such as brass and containing a plurality ofcutouts 132, only one of which is shown in FIGURE 2.Web 130 moves throughgap 90 whenvane 124 is rotated byshaft 126. As shown in FIGURES 3 and 4,vane 124 rotates in a bowl-shapedhousing 134.Transformer 84 is mounted on aplate 136 located near the floor ofhousing 134 in a position whereweb 130 passes throughgap 90.

Windings

92, 94 and 96 are wound oncore 88.Core 88 is mounted in ashield 138 and is held in place by conventional fasteners 140.Core 88 ordinarily is made of ferrite. If desired,plate 136 can comprise a printed circuit board and the other components of the circuit can be mounted on the circuit board withinhousing 134.

Operation of FIGURES 2, 3 and 4 Transistor 86 is of the NPN type, a typical useful transistor being No. 2N3053. When ignition switch 14 is closed, positive voltage is applied through resistor 100, lead 98 and winding 92 to collector 86c and throughresistor 108 and winding 94 to base 86b.Resistors 100 and 108 typically are about 100 and 1000 ohms, respectively.Diode 110, typically No. 1N4001, andresistor 108 bias transistor 86 slightly into conduction. The bias, however, is insufficient to sustain oscillation while the diamagnetic material ofweb 130 is ingap 90. Such bias is desirable because it ensures sufficient transistor gain to sustain oscillation when an additional voltage increment is induced in secondary winding 94.

When acutout 132 moves intogap 90, feedback occurs from primary winding 92 to secondary winding 94 to induce additional positive voltage on base 86b. Typically,gap 90 is about 0.055 inch, winding 92 is 10 turns of 30 AWG wire, and winding 94 is 12 turns of 30 AWG wire. The additional voltage increases the forward bias on base 86b sufficiently so transistor 86 increases conduction. The conduction increases current through winding 92 which in turn increases the induced voltage at base 86b to further increase conduction of transistor 86. Transistor 86 continues to increase its conduction until it saturates.

At saturation, the increase in current through winding 92 stops and the induced increment of voltage at base 86b disappears. Base 86b suddenly becomes negative with respect to emitter 86e, and the current through transistor 86 falls rapidly to a very low value.

The falling current through winding 92 induces a negative voltage at base 86b that keeps transistor 86 off until the negative voltage is dissipated. At this point, conduction of transistor 86 begins again and the above cycle is repeated in an oscillatory manner as long as acutout 132 is ingap 90. Oscillation frequency is determined primarily by the inductance of winding 92 and is at least several kilocycles per second, preferably ranging as high as several megacycles per second. During oscillation, when current through transistor 86 falls, current though resistor 100 passes into capacitor 121 which is selected so the current through resistor 100 is substantially constant. Thus, the voltage inlead 98 is constant during oscillation. A typical value for capacitor 121 is 0.1 microfarad at 25 volts.

The voltage at emitter 862 and in lead 116 rises when transistor 86 is conducting and falls when transistor 86 is turned off, thereby oscillating along with transistor 86. When oscillation begins, a pulse applied through capacitor 114 to gate 46g turns on controlledrectifier 46. Resistor 112 typically is about 1000 ohms and capacitor 114 typically is about 0.01 microfarad at volts.Rectifier 46 then conducts current throughresistor 38 and coil primary winding 26. Gate 54g of controlledrectifier 54 is negative or Zero andrectifier 54 is off during oscillation.Resistor 118 typically is about 5000 ohms and capacitor 120 typically is about 0.1 microfarad at 10 volts.

Current through winding 92 during oscillation induces current in winding 96 passing out of the dotted terminal. This induced current is applied throughdiode 50 tocapacitor 56. Sincerectifier 54 is off, this current builds up a voltage oncapacitor 56. When current through winding 92 decreases during oscillation,diode 50 blocks the negative voltage induced at the dotted terminal of winding 96 fromcapacitor 56.

As the diamagnetic material ofweb 130 moves intogap 90, the gain oftransformer 84 declines until the induced voltage in winding 94 falls below the level necessary to sustain oscillation. The presence ofWeb 130 ingap 90 also decreases the self-inductance of winding 92 which increases the oscillation frequency. This increased frequency in turn increases the inductance ofinductor 104 which typically is about 0.01 microhenry, thereby increasing the impedance provided byinductor 104. Preferably, transistor 86 is selected so its gain decreases significantly with the increase in frequency resulting from the changed self-inductance of winding 92.

The decreasing gain oftransformer 84 and transistor 86 plus the increased impedance offered byinductor 104 operate in cascade to stop oscillation precipitously. Current through resistor 100 drops suddenly, thereby raising the voltage inlead 98 and applying a positive pulse through capacitor 120 to gate 54g. This pulse turns onrectifier 54.

Rectifier 54 then applies the positive potential built up oncapacitor 56 tocathode 460 ofrectifier 46. Since the voltage disappeared from gate 46g when oscillation ceased, the positive potential ofcapacitor 56 turns offrectifier 46 rapidly. Current through coil primary winding 26 drops rapidly, thereby inducing voltage in coil secondary winding 28 that fires aspark plug 36.

Subsequently, anothercutout 132 moves intogap 90 and oscillation begins again in transistor 86. Gate 46gv again becomes positive turning on controlledrectifier 46. If desired, a capacitor can be connected in parallel withdiode 110 to decrease further the AC impedance between secondary winding 94 and ground.Vane 124 can have a planar or some other shape and can be made of paramagnetic or ferromagnetic material. The oscillator can be designed so no oscillation takes place when acutout 132 is ingap 90, and movement of the material ofweb 130 intogap 90 begins oscillation.Transformer core 88 can be split into two C-shaped portions facing each other across dual gaps to increase the change in feedback whenweb 130 moves between the portions. Note thattransformer 88 performs the dual functions of providing feedback for the oscillator and chargingcapacitor 56.

Silicon controlled rectifiers are preferred as

thyristors

46 and 54 because their ruggedness enables them to function accurately in an engine compartment for long periods of time. The amount of current broken bycontact points 66 and 68 can be as low as 0.1 ampere so the life of breaker points made from commercially available materials is extended to the life of the basic engine 6 components. Service life of the breakerless system of FIGURE 2 is even longer.

What is claimed is:

1. In an ignition system for an internal combustion engine having a source of electrical energy and a coil with a primary winding and a secondary Winding, means for inducing an ignition voltage at the coil secondary winding comprising a first thyristor in series with the coil primary winding,

a second thyristor having its cathode coupled to the cathode of said first thyristor,

a capacitor coupling the anodes of said first and second thyristors,

a two-stage trigger means actuatable by rotating parts of said engine, said trigger means turning on said first thyristor when in one of the stages,

transformer means for charging said capacitor when said first thyristor is on, and

circuitry for turning said second thyristor on when said trigger means switches to its other stage, said second thyristor discharging said capacitor through said thyristors to turn said first thyristor ofi rapidly.

2. The ignition system of claim 1 in which thyristors are silicon controlled rectifiers and the trigger means comprises an oscillator connected across said source of electrical energy, said transformer means being coupled to oscillation from said oscillator.

3. The ignition system ofclaim 2 in which the oscillator comprises a transistor and the transformer means provides a feedback connection from the output circuit to the input circuit of said transistor.

4. The ignition system of claim 3 in which the transformer means comprises a core having a gap therein and said trigger means comprises a web moving through the gap of said core to start and stop oscillation.

5. The ignition system of claim 4 in which the web is a diamagnetic material.

6. The ignition system of claim 1 in which said thyris tors are silicon controlled rectifiers, the trigger means comprises breaker points connected across said source of energy and movable into and out of touch with each other, and the transformer means comprises a saturable transformer.

7. The ignition system of claim 6 in which the saturable transformer has its primary winding in series with the coil primary winding and said first silicon controlled rectifier.

8. The ignition system of claim 7 in which the transformer secondary winding is connected through a diode to said capacitor.

References Cited UNITED STATES PATENTS 3,045,148 7/1962 McNulty et al. 315183 3,049,642 8/1962 Quinn 315206 3,051,870 8/1962 Kirk 315209 X 3,078,391 2/1963 Bunodiere et al. 315-209 X 3,260,251 7/1966 Lange 315209 X 3,280,810 10/1966 Worrell et al 315-209 X JOHN W. HUCKERT, Primary Examiner.

R. F. POLISSACK, Assistant Examiner.

US. Cl. X.R.

Claims

1. IN AN IGNITION SYSTEM FOR AN INTERNAL COMBUSTION ENGINE HAVING A SOURCE OF ELECTRICAL ENERGY AND A COIL WITH A PRIMARY WINDING AND A SECONDARY WINDING, MEANS FOR INDUCING AN IGNITION VOLTAGE AT THE COIL SECONDARY WINDING COMPRISING A FIRST THYRISTOR IN SERIES WITH THE COIL PRIMARY WINDING, A SECONDARY THYRISTOR HAVING ITS CATHODE COUPLED TO THE CATHODE OF SAID FIRST THYRISTOR, A CAPACITOR COUPLING THE ANODES OF SAID FIRST AND SECOND THYRISTORS, A TOW-STAGE TRIGGER MEANS ACTUATABLE BY ROTATING PARTS OF SAID ENGINE, SAID TRIGGER MEANS TURNING ON SAID FIRST THYRISTOR WHEN IN ONE OF THE STAGES, TRANSFORMER MEANS FOR CHARGING SAID CAPACITOR WHEN SAID FIRST THYRISTOR IS ON, AND CIRCUITRY FOR TURNING SAID SECOND THYRISTOR ON WHEN SAID TRIGGER MEANS SWITCHES TO ITS OTHER STAGE, SAID SECOND THYRISTOR DISCHARGING SAID CAPACITOR THROUGH SAID THYRISTOR TO TURN SAID FIRST THYRISTOR OFF RAPIDLY.