US3890579A

US3890579A - Ignition system and components thereof

Info

Publication number: US3890579A
Application number: US526586A
Authority: US
Inventors: Elmer A Carlson
Original assignee: Deutsche ITT Industries GmbH
Current assignee: TDK Micronas GmbH; ITT Inc
Priority date: 1974-03-04
Filing date: 1974-11-25
Publication date: 1975-06-17
Anticipated expiration: 1992-06-17

Abstract

A system for igniting, by a spark, the main burner of a gas fired device without the use of a pilot light from, for example, 12 or 24 volts. A unique oscillator provides the spark power and voltage. The oscillator also supplies the power to open the gas valve. A capacitor momentarily opens the valve. The valve is maintained open when a flame is present at the main burner.

Description

United States Patent Carlson 1 June 17, 1975 IGNITION SYSTEM AND COMPONENTS 3,465,207 9/1969 Merdian, Jr, 331 111 THEREOF 3,528.0 9/[970 Palmer Ct 3i y y 33 [/1 11 $546,488 l2/l970 Motto, Jr. 33l/l ll [75] Inventor: Elmer A. Carlson, Agoura, Calif. 3,588,912 6/1971 Hackett 331/166 [73] Assignee: International Telephone and xelsgraph Corporauon New York Primary E.wminer-.lohn Kominski Attorney, Agenl, r Firm-A. Donald Stolzy [22] Filed: Nov. 25, 1974 [21] Appl. No.: 526,586

Related US. Application Data [57] ABSTRACT [62] Division of March 1974' A system for igniting, by a spark, the main burner of a gas fired device without the use of a pilot light from, [52] 33l/Hl' for example, [2 or 24 volts. A unique oscillator prol t Cl 2 6 vides the spark power and voltage. The oscillator also 66 H7- supplies the power to open the gas valve. A capacitor 1 0 earc 1 momentarily opens the valve. The valve is maintained open when a flame is present at the main burner.

[56] References Cited UNITED STATES PATENTS 4 Claims, ll Drawing Figures 3,045,148 7/]962 MCNulty et al 33l/l ll v10 I 37 T t6 \l l? i 91 l I 121. .c l P 5 FUEL VALVE l 119 :23 I a r L J I lit PATENTEIJJUMH 1915 3,880,579

SHEET 3 FIGS i I 1 1 128 127 i L i i i I l I l I I I I i i i 1 I A a IGNITION SYSTEM AND COMPONENTS THEREOF BACKGROUND OF THE INVENTION This is a divisional application of copending application Ser. No. 447,889 filed Mar. 4, 1974. The benefit of the filing date of said copending application is, therefore, hereby claimed.

This invention relates to combustible fuel ignition systems, and more particularly, to a system for pilotless ignition and components thereof.

In the past, the use of a pilot burner has been rela tively safe but does waste a significant amount of gas.

SUMMARY OF THE INVENTION In accordance with the present invention, the abovedescribed and other disadvantages of the prior art are overcome by providing a system for igniting a main burner and a spark oscillator therefor.

In accordance with another feature of the invention, a fuel valve is turned on momentarily, and then shut off if combustion fails to take place.

The above-described and other advantages of the present invention will be better understood from the following detailed description when considered in connection with the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS In the drawings which are to be regarded as merely illustrative:

FIG. 1 is a block diagram of a fuel combustion systern;

FIG. 2 is a block diagram of a portion of the system shown in FIG. 1;

FIG. 3 is a block diagram of a power supply;

FIG. 4 is a schematic diagram of a spark ignitor and fuel valve control system;

FIG. 5 is a top plan view of a flame rod and a main burner;

FIG. 6 is a view of a switch;

FIG. 7 is a view of a diode;

FIG. 8 is a graph of a waveform characteristic of the operation of the oscillator of the present invention;

FIG. 9 is a schematic diagram of an alternative embodiment of the present invention;

FIG. 10 is a schematic diagram illustrative of the operation of the circuit of FIG. 9; and

FIG. 11 is a schematic diagram of still another embodiment of the present invention.

DESCRIPTION OF THE PREFERRED EMBODIMENTS Fuel combustion apparatus is illustrated in FIG. 1 including a fan motor 34 which drives both a combustion fan 35 and a bonnet fan 36. A sail switch is indicated at 37. An inlet conduit is illustrated at 38 connected to a main burner 39 by a fuel valve 40. A normally closed bonnet switch is illustrated at 41. A normally open bonnet switch is illustrated at 42.

Fan motor 34 is turned on by normally open bonnet switch 42 when the temperature in the bonnet is sufficiently high. The normally closed bonnet switch 41 turns off the power except for the fan motor when the temperature of the bonnet exceeds a safe value. Both of the

bonnet switches

41 and 42 are temperature operated.

Everything shown in FIG. I is conventional. Combustion chamber fan motor 34 drives out whatever gas may be filling this chamber prior to ignition. The sail switch 37 is located in an air duct from the bonnet fan 36 or from the combustion chamber fan 35, but preferably, the latter. Sail switch 37 is normally open and is closed when the air velocity is at or above a predetermined magnitude.

One embodiment of the system of the present invention may be operated from a 12 or 24 volt power supply as indicated at 43 in FIG. 3 having a positive terminal 44 and a negative terminal 45.

Plus and minus signs are employed to indicate a connection to a respective terminal to power supply 43 except in the case of amplifier 46 shown in FIG. 4 where the plus and minus signs are employed respectively to indicate the noninverting and inverting inputs of the amplifier 46.

The system of the present invention is employed to be operated by a thermostat 47 shown in FIG. 2 having a thermostatic switch operator 48 that closes a switch 49 when the temperature in the space to be heated falls below a predetermined or set point temperature. Switch 49 has a pole 50 and a contact 5]. Pole 50 is connected to power supply terminal 44 which is posi tive. A junction is provided at 52. The normally closed bonnet switch is shown again at 41. Switch 41 has a pole 54 and a contact 55. Contact 51 and pole 54 are connected to junction 52. A relay 56, having a coil 57, has one end connected from switch contact 55 to neg tive power supply terminal 45. The normally open bonnet switch 42 is again shown in FIG. 2. Fan motor 34 has the same number and is connected from a junction 59 to the negative terminal 45 of power supply 43. Switch 42 has a pole 60 and a contact 61. Relay 56 operates a pole 62 which has a contact 63.

Poles

60 and 62 are connected to the positive power terminal 44.

Contacts

61 and 63 are connected to junction 59. A junction 64 is connected from junction 52. A junction 65 is connected to a spark ignitor 66 which is, in turn, connected to the negative terminal 45 of DC. power supply 43. A resistor 67 is connected between

junctions

64 and 65. The same is true of sail switch 37.

Spark ignitor 66 has an output lead 69 connected to fuel controller 70. Spark ignitor 66 also has an output lead 71 connected to a junction 72 that is, in turn, connected to controller 70. A lead 73 connects junction 72 to ground.

Spark ignitor 66 is shown in FIG. 4 with utilization means including a controller 70. Various junctions are illustrated in FIG. 4 including

junctions

130, 131, I35, I36 and 137. Junction 131 is connected to the negative terminal 45 of DC. power supply 43. Junctions and 131 are connected together. As shown in FIG. 4, switch 49 is again shown and is connected from the positive terminal 44 of DC. power supply 43 to junction 135. Sail switch 37 is again shown with a diode 139 in FIG. 4, the same being connected in series in that order from junction 135 to junction 137, diode 139 being poled to be conductive toward junction 137.

A diode 138 is connected between

junctions

135 and 136, and is poled to be conductive in a direction toward junction 136. A smoothing capacitor 134 is connected between

junctions

130 and 136. Another smoothing capacitor 133 is connected between

junctions

130 and 137. Resistor 67 is again shown in FIG. 4 and is connected between

junctions

136 and 137.

The purpose of

diodes

139 and 138 is to prevent the oscillator of the present invention from driving the DC. power supply 43.

In accordance with the first embodiment of the present invention, DC. power supply 43 may be a battery or a half wave of full wave rectifier which may be or is connected to the line of an A.C. voltage source. In other words, DC. power supply 43 may also be a converter.

The circuit of FIG. 4 has various

other junctions

74, 75, 77, 78, 79, 80, 81, 82, 83, 84, 85, 86, 87, 88, 89, 90 and 91.

Junctions

74, 75 and 137 are connected together. A resistor 92 is connected between junction 74 and a second base 107 of a unijunction transistor 104. A resistor 93 is connected between junctions 77 and 78. A transformer 94 is provided having a primary winding 95 and a secondary winding 96. Primary winding 95 is connected betweenjunctions 75 and 77. A sili con-controlled rectifier (SCR) is illustrated at 97 hav ing an anode 98, a cathode 99 and a gate 100. Anode 98 is connected from junction 77 to junction 81 through cathode 99. A capacitor 101 is connected between

junctions

75 and 81. A resistor 79' of one ohm, more or less, is connected between

junctions

79 and 80. Gate 100 is connected from junction 80. A capacitor 102 is connected from junction 78 to junction 79.

Junctions

79 and 82 are connected together. A diode 103 is connected between

junctions

81 and 82, and poled to be conductive in a direction toward junction 82. Unijunction transistor 104 is provided with an emitter 105 and a first base 106 in addition to a second base 107. First base 106 is connected to junction 80. Emitter 105 is connected from junction 78. Another transformer 108 is provided having a primary winding 109 and a secondary winding 110. Primary winding 109 is connected from junction 82 to junction 131. In FIG. 4, the secondary winding 110 is connected between junc tions 83 and 84, junction 84 being grounded.

The purpose of the

transformers

94 and 30 are to provide for spark ignition and valve control, respectively.

Transformers

108 and 94 has conventional (in themselves) ferrite cores 108' and 108", respectively. Core 108' is not conventional in the system. Core 108" is conventional in a spark ignitor. Core 108' prevents unwanted valve actuation upon oscillator failure. Core 108 also provides a good low impedance device for coupling the 1,000 Hz. signal to utilization means 70'.

As will be explained, it is an outstanding feature of the present invention that spark ignitor 66 includes an oscillator which provides a continuous spark when the thermostat calls for it whether or not gas is supplied. Moreover, the oscillator provides a voltage across primary 95 from capacitor 101 which is of the order of 80 volts when the power supply 43 supplies 12 volts D.C., filtered or not.

One end of transformer secondary 96 is connected to a spark electrode 111 which sparks to a main burner 112, shown in plan in FIG. 4, that is grounded from junction 85 therewith. A flame rod 113 is located over main burner 112 to be in contact with the flame and to close a fuel valve indicated at 114 when no flame exists. A capacitor 115 is connected between

junctions

83 and 86. Flame rod 113 is positioned contiguous to main burner 112 but spaced therefrom in a position to be in contact with the flame. Flame rod 113 is connected to junction 86. A further junction 116 is provided from which a diode 117 is connected to junction 83 and is poled to be conductive in a direction toward junction 83.

Junctions

84, 88 and 89 are all connected together and are connected also to one end 118 of the coil 119 of fuel valve 114. Preferably,

diodes

120 and 120" are connected from the other end of coil 119 to junction 91, and are both poled to be conductive toward junction 91. A voltmeter V10 for monitoring is connected from the anode of diode 120' to ground.

Preferably, diode 120 is packaged with fuel valve 114 so that use thereof may not be made except in accordance with the present invention. A resistor 120 is connected between

junctions

86 and 87. A resistor 121 is connected between junction 87 and 88. Junctions 87 and are connected together. A capacitor 122 is connected between junctions 90 and 116. A capacitor 123 is connected between

junctions

116 and 89. A lead 124 is provided which is the power input lead of amplifier 46. Lead 124 is connected from junction 116.

Junction 96 is connected to the noninverting input of amplifier 46. Junction 91 is connected to the inverting input of amplifier 46. Amplifier 46 has a gain of unity.

Amplifier 46 may be any conventional amplifier, but is preferably one which has short circuit (milliampere region) protection such as the one disclosed as model pLA741 in Fairchild Semiconductor Integrated Circuits Catalog (November, 1971). Short circuiting of valve 114 is, therefore, permitted for testing.

OPERATION In the operation of the circuit of the present invention, in FIG. 4, thermostat switch 49 closes. Sail switch 68 is not yet closed. A trickle charge is provided through resistor 67 charging capacitor 101. When sail switch 37 closes, the oscillator is connected directly across the line. Resistor 67 is shorted out.

Resistors

92 and 93, unijunction 104 and capacitor 102 provide delayed firing of SCR 97. SCR 97 is not fired until capacitor 102 is adequately charged, i.e., the standoff ratio of unijunction 104 is reached. Unijunction 104 the fires SCR 97. This connects capacitor 101 directly across the primary of transformer 94 through SCR 97.

It is an outstanding feature of the present invention that the ratio of the resonant frequency of capacitor 101 and primary 95 of transformer 94 is perhaps times greater than the resonant frequency of capacitor 101 with the primary 109 of transformer 108. It is for this reason that SCR 97 is cut off at 90 electrical degrees. In this case, the circuit resonates at the lower frequency determined by the capacitane of the capacitor 101 and transformer primary 109.

Once the oscillator has started, the starting mechanism and structures including unijunction 104 and the circuit elements connected therewith and also resistor 97 have nothing to do with the operation.

When capacitor 101 and transformer primary 109 resonate, the resonant action terminates when the capacitor 101 charged to its maximum value with junction 75 being positive with respect to junction 81. This is true even though a power supply charging current back through the power supply would be possible. The reason this does not exist is that diode 103 prevents such further oscillation.

It is when the SCR 97 tires that the high frequency discharge of the energy of capacitor 101 in transformer primary 95 causes the spark to be generated between electrode 111 and main burner 112.

In FIG. 4, when the oscillator oscillates, junction 116 through the charge placed upon capacitor 123 causes junction 116 to have a potential of perhaps 12 volts negative with respect to ground. At the same time, capacitor 122 momentarily opens fuel valve 114 by the connection to amplifier 46 from junction 96. Diode I17 acts as a half wave rectifier to charge capacitor 123.

Resistors 120' and 121 act as a voltage divider.

Flame rod 113 acts either as a normally open switch 125 illustrated in FIG. 6 or as a diode 126 and resistor 126' as illustrated in FIG. 7.

Capacitor 115 prevents the diode 126 from shorting secondary 110 of transformer 108.

After momentary actuation of valve 114 through charging of capacitor 123 and through the use of capacitor 122, if the burner 112 is lit as shown in FIG. 5, flame rod 113 becomes the diode 126 and resistor 126' which allows a half wave rectified negative voltage to be placed across resistor 120' and resistor 121 to keep fuel valve 114 open. Filtering is provided by resistor 120' and

capacitors

122 and 123 in series.

The approximate voltage across a capacitor 23 shown in FIG. 9 is shown in FIG. 8.

An oscillator constructed in accordance with the present invention is illustrated in FIG. 9 including a DC. source of potential 21, an inductor 22, a siliconcontrolled rectifier (SCR) 24, a diode 25 and an inductor 26 connected in a manner identical to similar components shown in FIG. 4.

The oscillator of FIG. 9 has three different successive modes of oscillation. When SCR 24 is cut off, the circuit of FIG. 9 looks as shown in FIG. 10, where diode 25 is illustrated as a resistor 25'. The resistance of diode 25 may be considered zero or infinite depending upon whether or not it is forward or back biased, respectively.

When SCR 24 is fired, the circuit of FIG. 9 looks the same as in FIG. 10 except that in FIG. 9, inductor 22 is, when SCR 24 is fired, connected in parallel with capacitor 23 at

junctions

27 and 28 shown in FIG. 10.

If the resistance of 25' in FIG. 10 is zero, it is well known that i, I, sin (m t up) (I) where,

i, is the variable circuit current,

t is time,

I is the maximum circuit current, and

(0,, is the radian frequency of oscillation.

I,, being defined by cu, L,

(0 L d1= arctan and -Continued where C is the capacitance of capacitor 23.

The first oscillation of the FIG. 10 circuit can start (t =0) at E,, z 0 and I =0, if desired, by closing the sail switch 37 shown in FIG. 4 (not shown in FIG. 10). The FIG. 10 circuit then can ring if underdamped. N0 advance trickle charge may be necessary if other circuit values are changed.

Due to the use of the diode 25, the circuit of FIG. 10 can never ring more than one cycle. The latter is due to the fact that diode 25 stops the ringing.

It is striking and unexpected that the peak voltage across capacitor 23 can and does grow for each of the lowest frequency cycles l/A +C (see FIG. 8) of voltage oscillation across capacitor 23. This growth can be from, for example, a little above about 12 or 24 volts to about volts peak-to-peak. The peak-to-peak voltage across capacitor 23 is limited by the losses and re sistances in the circuit of FIG. 9 not shown therein. The growth of the voltage across the capacitor 23 will be explained in the following.

For a beginning, assume E, 0 and 4) I 0 at From equation (1), i I sin (n t, 7

where,

E nna a The voltage across capacitor 23 is then I e,,=' Ii,dl+C 9) From equation (7),

n|n e, Cw cos mud-C. ([0) When at then [M l Cm 13) From equations (l0) and (I3),

lm e, cm" (I cost-: 1 (l4) Diode 2S always stops the oscillation of the FIG, 10 circuit when e,, is at a positive peak with the polarity shown in FIG. 10. This peak is Zlm, r G06 From equations (8) and 14),

E 2E (l6) In FIG, 9, when capacitor 23 reaches E the voltage across inductor 26 reverses and lead 29 from junction 30 to SCR gate 31 fires SCR 24 because the connection of inductor 26 to junction 30 places SCR gate 31 at or about the potential of cathode 32 thereof.

When SCR 24 tires, the circuit looks the same as FIG except inductor 22 is connected between

junctions

27 and 28 as indicated at 22'.

The circuit of FIG. 10 with inductor 22 added may be analyzed as follows by applying Kirchoffs law twice.

As stated previously, the circuit of FIG. 9 has three successive modes of operation, namely:

A. SCR 24 is cut off;

B. SCR 24 is fired and the capacitor voltage e begins at peak E and C. SCR 24 is fired and the capacitor voltage e, is

equal to E to start with (time 1,, 0). ([7) The inductor 22 and the capacitor 23 have a current in mode (B),

sinam l8) where.

i is the current,

L, is the inductance of inductor 22, and

r is time.

The voltages 6 and e, across inductor 22 and the capacitor 23 are then t,= Simml, (2a) 5 Vmm The next equation to develop for the next mode of operation is the capacitor current at and after the ca- ]0 pacitor voltage e is at and after e E. 30

f L 1;- C r dge-L, d (3!) i, i i (32 di. at at,

dr dl d1 (33) i i E= C L m n d d (34) l a It, an L. (as) where,

E is the battery voltage, C is the capacitor capacitance, 3O

1 IS the capacitor current (see arrows in FIG. 10), i, is the current through inductor 26, i is the current through inductor 22, L, is the inductance of inductor 22, 35 L is the inductance of the inductor 26, and

r is time. Equation (34) combines (31 and (33). Equation (36) combines (34) and (35).

l L, di,

= LC I at, L m 36 0 1' l L, C LIC ]l 3] at; 1 1

Defining,

Llc

I l w. LC (40) Equation (38) easily integrates by known methods to as N f w, i, c. (43) When and i is determined as follows.

During the prior phase,

E i, ML sin to l, (45) e E. cos am, 4

where E is the starting peak voltage in the first phase.

E cos 01,1, T

at t,, 0, the magnitude of i is Combining (43), (44) and (48),

B L: WI! 2 2 l E' E E c, (mg) (50) With (52), (49) easily integrates to s l 2 k 1%) (51) where,

E E, E a! z -l w IL: (52) and 1 ll arctan 01 E:

at, l L. T I d: (54) i is negative.

dr' L, T- ficosm wrwc, (s)

a COS :2 E Cu! C, (5

(1 COS QE- C, E Cm d4 E n, cos :11- a cos( r A.) (58) d! L L,Cw, LCm g E n. cos y :1 L, Cl w, [fir-sin (w,1,.+ 1 1,.) c.I (59 E Z m m uh (60) -Continued l iwzl (61) CL m2 l i- I M t 1 When A- (62) t and To find 1,, 1, when i 0, d) I11,- 1r (65) The peak resulting voltage across the capacitor is p ku) o 2 k0 (66) Where I i W (66D E E, 4 (cos [3 cos 1110 k sin fi 7 cos B l (68) sin [3 0 (69) l cos nll T (70) Er R E (71) The voltage gain G is then o l R 72 This places the capacitor and battery with voltage polarities to add E to the capacitor voltage each time the oscillator goes through all three of its phases.

Note in an only voltage equation The capacitor voltage E if turned negative, adds to E This is done in the oscillator while the diode prevents charging the battery during capacitor voltage polarity reversal.

I00 is not necessarily optimum for all circumstances or maximum gain. k may be varied from above 100 to much lower, e.g., to near k l or k 2, However, if k is too low, the SCR will not cut off. With no losses, k must be about Maximum gain may be achieved at widely varying values other than k 100. Many of the other values set forth herein may also be widely varied.

In FIG. 8, period C shows a half cycle of operation at frequency (a The same is true of half cycle D. e is voltage across

capacitors

23 and 101. t is time. What appears to be another half cycle of operation is illustrated as A or B in FIG. 8. This is not true. As explained previously, if line 127 is zero volts, the line 128 is 12 volts or E.

Within the periods A and B, abo e the line 128, the frequency is m Below the line 128, the frequency is w The frequency during the periods C and D is (o As a fail safe measure, two capacitors may be connected in series between junctions and 116 and in lieu of the one capacitor 122 in FIG. 4.

The phrase source of DC. potential" or any equiva- -a 1 tan a lent thereto is hereby defined to include, but not be limited to, a battery, a half wave rectifier, filtered or not, and a full wave rectifier, filtered or not.

The phrase inductor means or any equivalent 5 thereto and the phrase inductor device or any equivalent thereto, is hereby defined to include, but not be em "m -i- V in "in Find 1. from 21L limited to, an inductor and/or a transformer Fat a With losses considered, the capacitor voltage E is E= mmLC W approximately (E azrz) (75) The second phase is +a e ao sin (w t 11 where,

where 15 R R, (76) R E R E 9 'u R +R 2 2 R 15 the L, resistance, L, R is the L resistance, R is the capacitor circuit resistance, R" i R: where RI R! LIL! L. 1., l R, R. I (77) L,.C 4L,

1' u l1 mm (78) q,,, 2L

1 11 R9 (79 Note if R: R; 2L (80) [a K2 l et 1 (R 8 then, in general, L,C 41,,

L1 L 10,0o0 (82) K,- R

. RE E E d The gain G 15 thus RI R2 5 l an a 1 G: R fl t a l (83) 1+K, where R: Lif- (SM is very small if K 10,000

The maximum capacitor voltage E is approximately Also Ee 2'2 R l e "21+ 1'1 (85) R 1 3 and 1 For maximum gain, R,, R and R should be as small as possible. L should be as large as possible. C should L be as small as possible. If L is large, gain is increased. l K However, if L, is too large, the SCR will not cut off.

To prove i 0 at B nfor losses, in the first phase 2| E h! KE mi E( e \1 [w m L (a 1 sinwm, (86) .0 IS third quadrant. 1 is negative Ill 1 m 1 I10 at! Inn (87) new ,simwfiwflanq a Find 1, from finding e C W This integrates by formula. Where if tion.

20.: l0.:r and n): ":10 lao i is negative. IP30 is third quadrant. Thus,

C, and

(Ill) From +K'E R,,' w Lm cos m, (1 l9) 5 where,

R, R R (1201 I i w aaosin p3 (l2l) R anno nc gm --L I l R. :0 4 z 2K l5 R, X [I e L a; e' 3o 'sinuu I11 (I22) The worst case is 'iao 0 (124) Thus, when 1' 0, (a is negative) 25 w t. L

1 e ([25) PR -e" m' sinw l If 00 is 180 to l88 and Ll l and (I26) who: 1 (I27) "so em- K an tlu) a ler l ["so'ml [1- ml =1: (129) 1 K' u amlm) ]=1r (I30) l so sul Kg Because amtzo l (13]) approximately adam) K TI ([32) Thus, if

almost exactly ln FIG. 11, an AC. source of potential is illustrated. Source 140 is connected across the primary 141 of a transformer 142 having a secondary 143 with upper and

lower leads

144 and 145, respectively.

Utilization means 70" are also illustrated in FIG. I] which may be identical to utilization means 70 illus trated in FIG. 4.

A transformer 146 is illustrated in FIG. 11 having a primary winding 147 and a secondary winding 148. Secondary winding 148 is connected to utilization means 70". If desired, transformer 146 may be identical to transformer 94 shown in FIG. 4.

Also shown in FIGv I1 is a transformer 149 having a primary 150 and a secondary 151. Secondary 151 is also connected to utilization means 70". If desired, transformer 149 may be identical to transformer 108 shown in FIG. 4.

Junctions

152, 153 and 154 are shown in FIG. 11. A switch 155 of a thermostat is connected in series between transformer secondary lead 144 and junction 152. A capacitor 156 is connected between

junctions

152 and 153. A silicon-controlled rectifier 157 is illustrated in FIG. 11 having an anode 158, a cathode 159 and a gate 160. Anode 158 is connected from the lower end of transformer primary 147, the upper end thereof being connected to junction 152.

Cathode 159 is connected to junction 153. A diode is provided at 161 having an anode 162 connected from junction 153 and a cathode 163 connected to junction 154.

Gate 160 is connected to junction 154.

Transformer primary 150 has one end connected to junction 154 and its other end connected to lead 145 of transformer secondary 143.

Although the circuit of FIG. 11 looks much like and may employ many components identical to respective ones in the oscillator of the present invention illustrated in FIGS. 2, 3, 4, 9 and 10, the circuit of FIG. 11 is not an oscillator. It is operated strictly by the AC. input thereto supplied thereto by source 140 through transformer 142.

The phrase means providing an A.C. or other sourcc of potential or an equivalent phrase is hereby defined for use herein and for use in the claims to mean one or more conductive leads or otherwise.

The phrase utilization means" is hereby defined for use herein and for use in the claims to mean means 70' or means 70" or the electrode means of a spark ignitor or otherwise.

Notwithstanding the foregoing,

transformers

108 and 94 may have cores other than ferrite cores which are either conventional or not.

What is claimed is:

1. An oscillator comprising: first, second and third junctions; a source of DC. potential having positive and negative leads; first and second inductor means; a capacitor; a silicon-controlled rectifier (SCR) having an anode, a cathode and a gate; and a diode, said positive lead being connected to said first junction, said first inductor means being connected from said first junction to said SCR anode, said capacitor being con nected between said first and second junctions, said SCR cathode being connected to said second junction, said diode being connected between said second and third junctions and being poled to be conductive toward said third junction, said second inductor means being connected from said third junction to said negative lead, said SCR gate being connected from said third junction.

2. Apparatus for periodically producing first signal portions of a higher frequency and for periodically producing second signal portions alternately with said first signal portions, said second signal portions being of a frequency lower than said higher frequency, said apparatus comprising: means for providing a source of potential including first and second leads; a circuit connected between said first and second leads, said circuit including first, second and third junctions, first and second inductor means, a capacitor, a silicon-controlled rectifier (SCR) having an anode, a cathode and a gate, and a diode, said first lead being connected to said first junction, said first inductor means being connected from said first junction to said SCR anode, said capacitor being connected between said first and second junctions, said SCR cathode being connected to said second junction, said diode being connected between said second and third junctions and being poled to be conductive toward said third junction, said second inductor means being connected from said third junction to said second lead, said SCR gate being connected from said third junction; and utilization means coupled to said circuit.

3. The invention as defined in claim 2, wherein at least one of said inductor means includes a first transformer having a primary winding connected in said circuit, and a secondary winding connected to said utilization means.

4. The invention as defined in claim 3, wherein the other of said inductor means includes a second transformer having a primary winding connected in said circuit, and a secondary winding connected to said utilization means.

Claims

1. An oscillator comprising: first, second and third junctions; a source of D.C. potential having positive and negative leads; first and second inductor means; a capacitor; a siliconcontrolled rectifier (SCR) having an anode, a cathode and a gate; and a diode, said positive lead being connected to said first junction, said first inductor means being connected from said first junction to said SCR aanode, said capacitor being connected between said first and second junctions, said SCR cathode being connected to said second junction, said diode being connected between said second and third junctions and being poled to be conductive toward said third junction, said second inductor means being connected from said third junction to said negative lead, said SCR gate being connected from said third junction.