US3814569A - Programing burner control device - Google Patents

Programing burner control device Download PDF

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US3814569A
US3814569A US00323576A US32357673A US3814569A US 3814569 A US3814569 A US 3814569A US 00323576 A US00323576 A US 00323576A US 32357673 A US32357673 A US 32357673A US 3814569 A US3814569 A US 3814569A
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burner
flame
control device
programing
relay
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US00323576A
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R Jacobsz
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Honeywell Inc
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Honeywell Inc
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    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F23COMBUSTION APPARATUS; COMBUSTION PROCESSES
    • F23NREGULATING OR CONTROLLING COMBUSTION
    • F23N5/00Systems for controlling combustion
    • F23N5/22Systems for controlling combustion with a time programme acting through mechanical means, e.g. using cams
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F23COMBUSTION APPARATUS; COMBUSTION PROCESSES
    • F23NREGULATING OR CONTROLLING COMBUSTION
    • F23N2227/00Ignition or checking
    • F23N2227/04Prepurge
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F23COMBUSTION APPARATUS; COMBUSTION PROCESSES
    • F23NREGULATING OR CONTROLLING COMBUSTION
    • F23N2227/00Ignition or checking
    • F23N2227/06Postpurge
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F23COMBUSTION APPARATUS; COMBUSTION PROCESSES
    • F23NREGULATING OR CONTROLLING COMBUSTION
    • F23N2227/00Ignition or checking
    • F23N2227/28Ignition circuits
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F23COMBUSTION APPARATUS; COMBUSTION PROCESSES
    • F23NREGULATING OR CONTROLLING COMBUSTION
    • F23N2229/00Flame sensors
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F23COMBUSTION APPARATUS; COMBUSTION PROCESSES
    • F23NREGULATING OR CONTROLLING COMBUSTION
    • F23N2231/00Fail safe
    • F23N2231/20Warning devices
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F23COMBUSTION APPARATUS; COMBUSTION PROCESSES
    • F23NREGULATING OR CONTROLLING COMBUSTION
    • F23N2233/00Ventilators
    • F23N2233/06Ventilators at the air intake
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F23COMBUSTION APPARATUS; COMBUSTION PROCESSES
    • F23NREGULATING OR CONTROLLING COMBUSTION
    • F23N5/00Systems for controlling combustion
    • F23N5/18Systems for controlling combustion using detectors sensitive to rate of flow of air or fuel

Definitions

  • the burnerleomrol 432/46 device ut1l1zes relay means which respond to the flame [5]] Int. Cl F23m 5/00 Sensor and initiating control, along i a number ⁇ 58] Field of Search 431/29, 26; 432/41, 46, of Cam Operated switches to provide the necessary 432/54 quencingof the device.
  • the burner control device utilizes a pair of flame relay contacts in the motor driven [56] References Cited cam circuit, and the safety switch heater circuit, so UNITED STATES PATENTS, that the present burner control device can monitor 7 proper operation of the burner during both the pre purge and the normal operating period of the burner 3,482,922 12/1969 Blacket't 431/26 system 8 Claims, 4 Drawing Figures ssl @gli 30' l4 4 r L, 3/ T 20 .1. 1 "(#1 2 r1 gfr f l Z3 ⁇ EFFIRE 1 "-2195 w l 8/ 82 -Cfi ,a3 1 50 ⁇ Tu Furs. "-77 T33?
  • Timer contacts each are shown with times of operation.
  • FIG. 2 is a diagrammatic representation of FIG. 1
  • burner control systems are widely used in the fuel burner system market. These programing type burner control devices normally utilize a motor driven cam arrangement which programs a number of cam operated switches. Along with the switch functions derived from the cams, two or more relays are normally used in response to various condition sensing and initiating'circuits. The most common devices utilize a relay for operating the load, such as the ignition transformer, pilot valve and main valve. The second relay normally responds to a flame sensor and is controlled through an amplifier circuit to cooperate with the cam operated switches and other relay contacts to provide the necessary safe sequencing control of a burner system. In some prior art devices the amplifier normally was a tube type of amplifier and required continuous energization of the filament circuit and the balance of the circuitry so that it could be operated promptly upon initiation of a burner cycle.
  • the present invention is directed to an improved programing burner control device.
  • the normal relay contacts and cam operated switches that energize the amplifiers flame relay have been replaced by a relay contact which energizes the solid state amplifier at the instant it is needed for use rather than keeping it in an energized, standby condition.
  • a pair of flame contacts are arranged so that the energizing circuit for the motor of the cam operated switches flows through one of the flame relay contacts during part of the operation to thereby stop the timer motor and allow the device to lock out on safety in the event of a false indication of a failure in the flame detector and amplifier circuit.
  • FIG. 2 is a bar chart showing the operating cycle plot-' ted against the programer time in seconds, and;
  • FIG. 3 is a graph of the position of the damper of the burner as plotted against the programer time in seconds.
  • FIGS. 1 and 1A a complete schematic diagram of a programing burner control device incorporated in a burner system is disclosed. Before a description of the actual embodiment, an explanation of some of the notations used in the drawing is believed warranted. All of the equipment which is external to the claimed burner control device are shown in phantom. The burner control device of the present invention, and the external equipment shown in phantom, constitute a complete burner system. All of the contacts of the programing timer and of the two relays contained in the device are shown at the time when the programer is at zero seconds of operation. For convenience in understanding the operation of the device, each of the timer contacts has shown next to it the appropriate opening and closing times of the contact.
  • FIG. 1 an entire burner system is disclosed as connected to a pair of conductors l and 11 which supply operating power to the system.
  • Conductor is connected to a conductor 12 of the burner control device while conductor 11 is connected to conductor 13 of the burner control device.
  • a conductor 14 connects conductor I2 through a group of limits and controller 15, and a conductor 16 to a terminal 17 of the burner con trol device.
  • the limits and controller are conventional safety limits and the starting controller for the burner system.
  • Conductor 21, a preignition interlock 22, and a conductor 23 to a terminal 24 provide a first path.
  • a normally open cam operated switch means or contact 25 In parallel with the preignition interlock 22 is a normally open cam operated switch means or contact 25.
  • the normally open cam operated switch means is driven. by a motor driven cam means indicated at 26, which contains a conventional synchronous type clock motor and shaft that rotates the number of cams that in turn operate various switch means.
  • a motor driven cam means indicated at 26 which contains a conventional synchronous type clock motor and shaft that rotates the number of cams that in turn operate various switch means.
  • Each of the various cam operated switch means later disclosed will be identified by a reference number and will have the opening and closing times noted on the drawings adjacent the contactitself.
  • the contact 25 is connected back via conductor 27 to the terminal 24.
  • Terminal 31 of the burner control device is connected through a normally open relay contact 1K2 to a conductor 32.
  • Conductor 32 is connected through a normally closed contact 33 of the timer which in turn is connected back to conductor 27.
  • Conductor 32 is further connected through a relay contact 1K1 and a normally closed timer contact 34 that is paralleled by a normally closed contact 2K3. The designation of the relay contacts firstly.
  • the [K1 relay is the first contact of the 1K relay itself.
  • the IK relay isdisclosed at 35 and is a relay that has two windings that are used for pull in, and the retaining energization of the relay. This general type of relay configuration and its operation cangenerally be found in the US. Pat. No. 3,082,813 to W. B. Hamelink, assigned to the assignee of the present invention.
  • the contacts 34 and 2K3 have a common juncture 36 at a safety switch heater 37 which in turn is connected by conductor 40 through a normally closed safety switch contact designated as SS2 and through a coil 41 that is a part the lKrelay 35.
  • the 1K relay has a further winding 42 that is connected to conductor 40 and to a junction 43 between a normally opened relay contact 2K4 and the normally open timer contact 44.
  • the junction of the contacts 44 and 2K4 is at 45 which is connected to the junction between the 1K1 relay contact and the timer contact 34.
  • the operation of the 1K relay and the safety switch heater along with the safety switch contact follow generally the teaching of the earlier mentioned Hamelink patent.
  • the safety switch is of a conventional design where the heater operates the switches, and wherein the switch members are then locked into the operated position until a manual reset button is pushed.
  • a safety switch contact designated SS1 is connected between the line 12 and a terminal 46 along with an alarm designated 47 and a conductor 48. When the switch SS1 closes, power is supplied to the alarm 47 to indicate that the safety switch has operated and that the device requires attention and reset.
  • a flame detector 50 is provided in the burner system and is connected between a pair of terminals F and G.
  • the F and G terminals are input terminals to a plug-in amplifier 51, which is a solid state amplifier, selected to amplify a flame detection signal from the flame detector 50.
  • the flame detector 50 can be a photocell, ultraviolet sensor, or flame rod and is matched to an appropriate solid state amplifier 51.
  • the amplifier 51 receives its energy from a transformer 52 of a conventional design having a primary 53.
  • the amplifier 51 further supplies, as its output, current to a 2K relay which is referred to as the flame relay.
  • the 2K or flame relay is deenergized in the absence of flame and is energized when the flame detector 50 senses the presence of a flame.
  • the primary winding 53 is connected by conductor 54 to conductor 13 and by conductor 55 to a parallel combination of the normally open 2K2 contact and the normally closed timer contact 56.
  • the 2K2 contact and the timer contact 56 connect to conductor 32 to supply energizing power to the transformer primary 53 after the system is put into operation by the closing of the controller 15.
  • the system can be put into operation concurrently with the operation of the controller since the plug-in amplifier 51 is all solid state. This same function could be accomplished by continuously energizing the filaments of a conventional tube type of amplifier, and then applying only the high voltage when the controller 15 was activated.
  • An ignition device 60 is connected at terminal 61 and at conductor 13, as is a pilot valve 62 connected to terminal 63 and conductor 13, along with a main fuel valve 64 connected to a terminal 65.
  • the ignition device 60, the pilot valve 62, and the main valve 64 all are common at the conductor 13 and are supplied with electric power through the 2K2 contacts when closed, or through the timer contact 56 when it is closed. This is accomplished by the use of a normally open timer contact 66, a normally open timer contact 67, and a further normally opened timer contact 68.
  • the sequencing of the timer contacts 66, 67, and 68 is substantially the same as that disclosed in the previous mentioned Hamelink patent or in the line of products sold by the assignee of the present invention and known as the R4150G flame safeguard programer. Since this type of arrangement is well known in the art. no further description will be directed to these devices but they will be mentioned only in connection with the description of operation.
  • Conductor 12 is connected through a parallel combination of the 1K3 contact and the normally opened timer contact 70.
  • This parallel combination supplies power to a conductor 71 that branches through the normally closed 1K4 contact, the normally closed timer contact 72, and the series pair of normally open timer contacts 73 and 74 along with the normally closed contact 2K1.
  • These three paths provide an energizing path to the conductor 75 which in turn connects the timer motor of the motor driven cam means 26 to conductor 13 to energize the timer motor when it is necessary for the timer contacts to advance in the program within the device.
  • a conductor 71 is further connected to a terminal 76 which provides line voltage to a conductor 77 to provide a burner motor 78 with power through to the conductor 13.
  • the burner motor 78 supplies air flow which in turn operates the air flow switch 30, along-with providing the necessary purge air flow and burner air for the overall burner system.
  • Terminal 76 is connected through a low fire interlock switch 80 to a terminal 81 and to junction 82 which is connected to a high fire interlock switch 83.'The high fire interlock switch in turn is connected to a terminal 84.
  • the terminal 84 is connected to a normally closed timer contact 85.
  • the device of FIG. 1 also in reality includes a portion disclosed in FIG. 1A.
  • the portion of the .circuit disclosed in FIG. 1A is a control circuit for a modulating control 87 and the motor 86 operated from the burner system.
  • the motor 86 is used to position dampers for control of the air flow between a high fire (full air flow capability) to a low fire (a minimum air flow capability) position.
  • the modulating control 87 associated with this provides the necessary rebalance for the position sensitive motor.
  • These devices are of a conventional design, and are used in the conventional manner in the present invention.
  • Four terminals 90, 91, 92 and 93 are provided along with the, conductors 94, 95, and 96.
  • a normally open timer contact 97 and a normally closed contact 98 Connected between terminals 93 and 91 is a normally open timer contact 97 and a normally closed contact 98. Connected between terminal 90 and terminal 91 is a normally open contact 99, whereas between the terminal 92 and a common junction between the contacts 97 and 98, is connected a normally closed contact 101.
  • This arrangement of contacts and wiring provides for the necessary positioning of the air flow damper within the burner system between the high and the low fire positions. A modulating operation in between the high and low positions is provided in the normal run condition. By normal run it is meant that the device is not sequencing to try and light the burner, but is allowing the burner to operate fully to provide the heat necessary to the control 87.
  • FIGS. 2 and 3 Before describing the operation of the system, FIGS. 2 and 3 will be described since their description will aid in understanding the present invention.
  • FIG. 2 there is disclosed a bar chart of the portion of the cycle versus the programer time in seconds.
  • the bar chart is substantially self explanatory.
  • the bar chart shows the device going through a prepurge period, ignition and pilot period, a main valve energized period, and then a modulating control between the startup and the satisfaction of heat to the controller 15.
  • the timer motor 26 ceases to operate and the system operation continues on until the heat supplied by the burner satisfies the demand at the controller 15.
  • shut down controller opening
  • the sequence picks up at 105 seconds and goes through a post purge period to 120 seconds.
  • the 120 second mark in fact again is the zero point, and the cycle is ready to start over again.
  • FIG. 3 discloses a graph of the burner damper position, between the high and low fire positions, as a function of the programer time in seconds.
  • the graph of FIG. 3 shows that the damper or burner starts in the low fire and then moves to the high fire position at 7 seconds, where it remains until 41 seconds. At 41 seconds it returns to the low fire position and stays at the low fire position during the entire low fire proof and ignition of the main valve.
  • the device at 95 seconds then goes into a modulating condition where the burner damper and operating level varies with demand until the controller 15 is operated to open circuit to shut the system down. At that time the modulation ceases and the device returns the damper to the low fire position at l 16 seconds so that the system is ready to start at the next call for heat.
  • controller 15 closes to supply electrical energy to the preignition interlock 22 through terminal 24. Power is then supplied through the normally closed switch 33 and the normally closed switch 56 to the conductor 55. This supplies the electrical energy to the transformer 52 to energize the plug-in amplifier 51 so that any flame detected at the flame detector 50 is appropriately amplified to control the 2K relay.
  • Energy is also supplied through the normally closed contact 2K3, through the safety switch heater 37 and the safety switch contact SS2 (which is normally closed), and through the 1K relay coil 41 to conductor 13.
  • the energy supplied to coil 41 pulls the relay 1K in at which time the contact 1K2 closes along with relay contact 1K3 and 1K1.
  • the 1K3 relay supplies energy on conductor 71 to the burner motor 78 to supply the air flow necessary to close the air flow switch 30.
  • energy is supplied to terminal 31, through the relay contact 1K2 which shunts the normally closed contact 33, to power the plug-in amplifier 51.
  • the contact (2 upon closing locks in the 1K relay during normal operation of the burner control device.
  • the timer contacts 73 and 74 along with the low fire interlock 80 and the high fire interlock 83 provide a continuous supply of energy to the timer motor 26 in a normal operating sequence. This allows the timer to progress through operation thereby closing the timer contacts 66, 67 and 68 in the proper sequence to create ignition, light the pilot, and then light the main burner.
  • the flame detector 50 In a normal sequence of operation the flame detector 50 is exposed to and will sense the operation of the pilot flame and the main burner.
  • the normally closed switch 72 In the prepurge sequence, the normally closed switch 72 has gone through a cycle of opening and closing, and will again have closed to complete an energizing circuit for the timer motor 26 thereby keeping the timer motor in operation even though the switch 2K1 opens at the time the flame detector senses the existence of flame.
  • the existence of flame at 60 seconds or shortly after closes the normally open relay contact 2K2 to provide a source of continuing energization for the transformer 52 and the plug-in amplifier 51, as well as for the ignition device 60, the pilot valve 62, and the main valve 64.
  • the energizing circuit for the safety switch heater 37 has been activated by closing the normally open contact 44 and will remain active until the flame detector 50 senses the existence of flame at which time the normally closed 2K3 flame relay contact opens. As long as switch 34 is open and the relay contact 2K3 is also open, no heating circuit is completed for the safety switch heater 37.
  • the modulating control 87 varies with temperature to move the wiper of the potentiometer to cause the motor 86 to in turn operate a modulating valve and damper to supply the proper level of burner operation. This will go on until the controller 15 opens, until some malfunction occurs which opens one of the limit switches, or a failure in the sensed flame occurs and is detected by the novel circuit configuration of the present invention.
  • the invention in the present application is directed to a unique function within the system which detects an abnormal type of operation.
  • the unit senses this malfunction and shuts the device down on safety. Any failure in the flame detector system which causes the 2K relay to be energized during a substantial portion of the prepurge cycle causes the safety switch heater 37 to be operably energized to time out on safety. This opens the safety switch contact SS2 and closes the safety switch contact SS1 to the alarm 47. Since the safety switch means of the present invention is a manual reset type of safety switch, this operation shuts down the system and causes an alarm to be given requiring the system to be reset manually.
  • the safety function is accomplished by the normally closed 2K1 relay contact opening, and the normally open 2K4 contacts closing.
  • the opening of the 2K1 contact during the prepurge portion of the cycle re-. moves the energizing circuit for the timer motor 26 and the timer stops operating.
  • the closing of the 2K4 relay contacts completes a circuit through contact 34 and the safety switch heater 37 to the winding 42 of the relay 1K.
  • the present arrangement provides with a simple set of contacts a safety feature that has not hitherto been available on programing types of burner control devices.
  • the present system provides for the monitoring of the flame detector circuit during the prepurge portion of the cycle, and thereby provides safety over a large portion of the operation of the programer.
  • the present system includes two other desirable features.
  • the use of the relay contact 2K2 in parallel with the normally closed timer contact 56 provides an energizing path for the plug-in amplifier 51 through the transformer 52 after the controller has closed. This means that the plug-in amplifier 51 and its associated equipment is energized only when the controller is calling for operation of the device and no unnecessary energy is drawn by this system. This can be accomplished with solid state systems or with tube type of equipment where the filaments only have been provided with a continuous source of heating current.
  • the present invention is very broadly directed to a safer type of flame safeguard burner control device for operating a burner system.
  • By utilizing flame responsive contacts in the safety switch circuit and the timer motor circuit it is possible to detect failures in the flame detection circuit prior to the end of the purge period thereby providing for a safe start up.
  • This is further reinforced by a circuit which provides for a guarantee that the fuel supply is at its proper position, that is that the high fire interlock switch has operated.
  • a programing burner control device adapted to be connected as part of a burner system which includes flame sensor means, ignition and fuel supply means, condition responsive interlocks, and initiating control means whereby said programing burner control device is adapted to be connected to a source of operating power when said interlocks and said control means are properly actuated, including: motor driven cam means and cam operatedswitch means with said switch means operated in a sequence to program said burner system in a predetermined operating mode; safety switch means including heater means and normally closed safety switch contacts with said heater means capable of opening said safety switch contacts upon said heater means being operatively energized for a period of time; load control relay means including a plurality of load control contacts with at least one of said control contacts controlling the energization of said motor driven .cam means upon initiation of operation of said burner system; amplifier means and flame relay means wherein said amplifier means is adapted to be connected to said flame sensor means with said flame relay means normally operated in response to said flame sensor means detecting the presence of flame; said flame relay means including a normally open contact which when
  • said flame relay means further includes a second normally open contact in parallel circuit with a first cam operated switch of said cam operated switch means; and said cam operated switch being normally closed during said prepurge portion of said burner system operation and an initial ignition portion of said burner system operation; said cam operated switch opening after said second flame contact has closed; said energized flame relay means insuring that said control device is energized; said second flame contact opening if the flame is lost to thereby deenergize said control device.
  • safety switch means further includes latching means with manual reset to latch said normally closed safety switch contacts in an open condition when said heater means has been energized sufficiently to open said closed safety switch contact means.
  • cam operated switch means includes second cam operated switch means which is adapted to complete a circuit through a high fire interlock switch to energize said motor driven cam means during said prepurge portion of said burner system operation to insure that said system is in a high fire operating mode.

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  • Engineering & Computer Science (AREA)
  • Chemical & Material Sciences (AREA)
  • Combustion & Propulsion (AREA)
  • Mechanical Engineering (AREA)
  • General Engineering & Computer Science (AREA)
  • Regulation And Control Of Combustion (AREA)
  • Control Of Combustion (AREA)

Abstract

A programing burner control device is disclosed which responds to a flame detector, condition responsive interlocks, and initiating control to properly sequence a fuel burner system through prepurge, ignition, burner operation, and post purge periods. The burner control device utilizes relay means which respond to the flame sensor and the initiating control, along with a number of cam operated switches to provide the necessary sequencing of the device. The burner control device utilizes a pair of flame relay contacts in the motor driven cam circuit, and the safety switch heater circuit, so that the present burner control device can monitor proper operation of the burner during both the prepurge and the normal operating period of the burner system.

Description

United States Patent 11 1 Jacobsz June 4, 1974 PROGRAMING BURNER CONTROL Primary Exumincr.lohn .l. Camby DEVICE Attorney, Agent. or Firm-Lam0nt B. Koontz; Alfred [75] lnventor: Roelof F. Jacobsz, Blaine, Minn. Feldman [73] Assignee: Honeywell Inc., Minneapolis, Minn. [57] ABSTRACT [22] Filed; Jam 5 197 A programing burner control device is disclosed which responds to a flame detector, condition responsive in- [211 l 323,576 terlocks, and initiating control to properly sequence a 7 fuel burner system through prepurge, ignition, burner {52] us. 0. 431/29, 431/26, 432/41, r mp P Purge P The burnerleomrol 432/46 device ut1l1zes relay means which respond to the flame [5]] Int. Cl F23m 5/00 Sensor and initiating control, along i a number {58] Field of Search 431/29, 26; 432/41, 46, of Cam Operated switches to provide the necessary 432/54 quencingof the device. The burner control device utilizes a pair of flame relay contacts in the motor driven [56] References Cited cam circuit, and the safety switch heater circuit, so UNITED STATES PATENTS, that the present burner control device can monitor 7 proper operation of the burner during both the pre purge and the normal operating period of the burner 3,482,922 12/1969 Blacket't 431/26 system 8 Claims, 4 Drawing Figures ssl @gli 30' l4 4 r L, 3/ T 20 .1. 1 "(#1 2 r1 gfr f l Z3 {EFFIRE 1 "-2195 w l 8/ 82 -Cfi ,a3 1 50 {Tu Furs. "-77 T33? il'ffL-i l I 5 A I I) l J. 7 l l :fiinl 5 as 84 1 l g i. l 35 euRuEnl E moron .1 l"' g LI ,54 l
J l. L-& l l l [mwlrmmr] l l/ 4/ l3 1 F T PATENTEBJUN 41914 $814,569
SHEET 2 0f 2 FIG 1A,
F |Modulating Control Q T l (Condition I .El Sensitive) 3 i Equipment External to Burner Control Device (shown dashed)- All Contacts Shown at Time 0 Seconds.
Relay Contacts N.O. 4- NIL-PF Timer Contacts N.O.-l l N.C.=H\
Timer contacts each are shown with times of operation.
FIG, 2,
Pre Purge Main Valve Cycle Post Purge lnterlm |Proot H.F.| [if] i Pilot 0 7 36.5 49.5 53.5 '20 Programmer Time in Seconds Burner coi d sl' 7 4| Modulation Hlgh me I MW I L] J Low Flre O 49.5 95 us I20 Programmer Time in Seconds FIG, 3.
PROGRAMING BURNER CONTROL DEVICE BACKGROUND AND SUMMARY OF THE INVENTION Programing types of burner control systems are widely used in the fuel burner system market. These programing type burner control devices normally utilize a motor driven cam arrangement which programs a number of cam operated switches. Along with the switch functions derived from the cams, two or more relays are normally used in response to various condition sensing and initiating'circuits. The most common devices utilize a relay for operating the load, such as the ignition transformer, pilot valve and main valve. The second relay normally responds to a flame sensor and is controlled through an amplifier circuit to cooperate with the cam operated switches and other relay contacts to provide the necessary safe sequencing control of a burner system. In some prior art devices the amplifier normally was a tube type of amplifier and required continuous energization of the filament circuit and the balance of the circuitry so that it could be operated promptly upon initiation of a burner cycle.
The present invention is directed to an improved programing burner control device. The normal relay contacts and cam operated switches that energize the amplifiers flame relay have been replaced by a relay contact which energizes the solid state amplifier at the instant it is needed for use rather than keeping it in an energized, standby condition. A pair of flame contacts are arranged so that the energizing circuit for the motor of the cam operated switches flows through one of the flame relay contacts during part of the operation to thereby stop the timer motor and allow the device to lock out on safety in the event of a false indication of a failure in the flame detector and amplifier circuit.
BRIEF DESCRIPTION OF THE DRAWINGS FIG. 2 is a bar chart showing the operating cycle plot-' ted against the programer time in seconds, and;
FIG. 3 is a graph of the position of the damper of the burner as plotted against the programer time in seconds.
DESCRIPTION OF THE PREFERRED EMBODIMENT In FIGS. 1 and 1A a complete schematic diagram of a programing burner control device incorporated in a burner system is disclosed. Before a description of the actual embodiment, an explanation of some of the notations used in the drawing is believed warranted. All of the equipment which is external to the claimed burner control device are shown in phantom. The burner control device of the present invention, and the external equipment shown in phantom, constitute a complete burner system. All of the contacts of the programing timer and of the two relays contained in the device are shown at the time when the programer is at zero seconds of operation. For convenience in understanding the operation of the device, each of the timer contacts has shown next to it the appropriate opening and closing times of the contact.
In FIG. 1 an entire burner system is disclosed as connected to a pair of conductors l and 11 which supply operating power to the system. Conductor is connected to a conductor 12 of the burner control device while conductor 11 is connected to conductor 13 of the burner control device. A conductor 14 connects conductor I2 through a group of limits and controller 15, and a conductor 16 to a terminal 17 of the burner con trol device. The limits and controller are conventional safety limits and the starting controller for the burner system.
At terminal 17, a pair of parallel paths are provided. Conductor 21, a preignition interlock 22, and a conductor 23 to a terminal 24 provide a first path. In parallel with the preignition interlock 22 is a normally open cam operated switch means or contact 25. The normally open cam operated switch means is driven. by a motor driven cam means indicated at 26, which contains a conventional synchronous type clock motor and shaft that rotates the number of cams that in turn operate various switch means. Each of the various cam operated switch means later disclosed will be identified by a reference number and will have the opening and closing times noted on the drawings adjacent the contactitself. The contact 25 is connected back via conductor 27 to the terminal 24.
A further part of the initial energizing path for the de-,
vice includes an air flow sensitive switch 30 that is connected between the terminal 24 and a further terminal 31. The air flow responsive switch closes to short the terminals 24 and 31 together when sufficient air flow has been proved in the burner system, as is well known in the art. Terminal 31 of the burner control device is connected through a normally open relay contact 1K2 to a conductor 32. Conductor 32 is connected through a normally closed contact 33 of the timer which in turn is connected back to conductor 27. Conductor 32 is further connected through a relay contact 1K1 and a normally closed timer contact 34 that is paralleled by a normally closed contact 2K3. The designation of the relay contacts firstly. indicates the particular relay and then the number of the contact of that particular relay.- For example, the [K1 relay is the first contact of the 1K relay itself. The IK relay isdisclosed at 35 and is a relay that has two windings that are used for pull in, and the retaining energization of the relay. This general type of relay configuration and its operation cangenerally be found in the US. Pat. No. 3,082,813 to W. B. Hamelink, assigned to the assignee of the present invention.
The contacts 34 and 2K3 have a common juncture 36 at a safety switch heater 37 which in turn is connected by conductor 40 through a normally closed safety switch contact designated as SS2 and through a coil 41 that is a part the lKrelay 35. The 1K relay has a further winding 42 that is connected to conductor 40 and to a junction 43 between a normally opened relay contact 2K4 and the normally open timer contact 44. The junction of the contacts 44 and 2K4 is at 45 which is connected to the junction between the 1K1 relay contact and the timer contact 34.
As previously indicated, the operation of the 1K relay and the safety switch heater along with the safety switch contact follow generally the teaching of the earlier mentioned Hamelink patent. At this point it is only necessary to indicate that once the conventional safety switch heater is energized by current flowing through it, it is capable of opening the normally closed safety switch contact SS2 and closing an alarm contact designated as SS1. The safety switch is of a conventional design where the heater operates the switches, and wherein the switch members are then locked into the operated position until a manual reset button is pushed. As was just mentioned a safety switch contact designated SS1 is connected between the line 12 and a terminal 46 along with an alarm designated 47 and a conductor 48. When the switch SS1 closes, power is supplied to the alarm 47 to indicate that the safety switch has operated and that the device requires attention and reset.
A flame detector 50 is provided in the burner system and is connected between a pair of terminals F and G. The F and G terminals are input terminals to a plug-in amplifier 51, which is a solid state amplifier, selected to amplify a flame detection signal from the flame detector 50. The flame detector 50 can be a photocell, ultraviolet sensor, or flame rod and is matched to an appropriate solid state amplifier 51. The amplifier 51 receives its energy from a transformer 52 of a conventional design having a primary 53. The amplifier 51 further supplies, as its output, current to a 2K relay which is referred to as the flame relay. The 2K or flame relay is deenergized in the absence of flame and is energized when the flame detector 50 senses the presence of a flame. Unfortunately, occasional flame detector malfunctions cause the 2K relay to be energized when it should not be energized, and the present invention is directed to an arrangement which overcomes this false indication and shuts the system down in a safe manner. A description of that function will be provided after a description of the complete device has been outlined.
The primary winding 53 is connected by conductor 54 to conductor 13 and by conductor 55 to a parallel combination of the normally open 2K2 contact and the normally closed timer contact 56. The 2K2 contact and the timer contact 56 connect to conductor 32 to supply energizing power to the transformer primary 53 after the system is put into operation by the closing of the controller 15. This differs from the conventional, prior art devices which have a continuously energized amplifler circuit. In the present invention, the system can be put into operation concurrently with the operation of the controller since the plug-in amplifier 51 is all solid state. This same function could be accomplished by continuously energizing the filaments of a conventional tube type of amplifier, and then applying only the high voltage when the controller 15 was activated.
An ignition device 60 is connected at terminal 61 and at conductor 13, as is a pilot valve 62 connected to terminal 63 and conductor 13, along with a main fuel valve 64 connected to a terminal 65. The ignition device 60, the pilot valve 62, and the main valve 64 all are common at the conductor 13 and are supplied with electric power through the 2K2 contacts when closed, or through the timer contact 56 when it is closed. This is accomplished by the use of a normally open timer contact 66, a normally open timer contact 67, and a further normally opened timer contact 68. The sequencing of the timer contacts 66, 67, and 68 is substantially the same as that disclosed in the previous mentioned Hamelink patent or in the line of products sold by the assignee of the present invention and known as the R4150G flame safeguard programer. Since this type of arrangement is well known in the art. no further description will be directed to these devices but they will be mentioned only in connection with the description of operation.
Conductor 12 is connected through a parallel combination of the 1K3 contact and the normally opened timer contact 70. This parallel combination supplies power to a conductor 71 that branches through the normally closed 1K4 contact, the normally closed timer contact 72, and the series pair of normally open timer contacts 73 and 74 along with the normally closed contact 2K1. These three paths provide an energizing path to the conductor 75 which in turn connects the timer motor of the motor driven cam means 26 to conductor 13 to energize the timer motor when it is necessary for the timer contacts to advance in the program within the device.
A conductor 71 is further connected to a terminal 76 which provides line voltage to a conductor 77 to provide a burner motor 78 with power through to the conductor 13. The burner motor 78 supplies air flow which in turn operates the air flow switch 30, along-with providing the necessary purge air flow and burner air for the overall burner system. Terminal 76 is connected through a low fire interlock switch 80 to a terminal 81 and to junction 82 which is connected to a high fire interlock switch 83.'The high fire interlock switch in turn is connected to a terminal 84. The terminal 84 is connected to a normally closed timer contact 85.
The device of FIG. 1 also in reality includes a portion disclosed in FIG. 1A. The portion of the .circuit disclosed in FIG. 1A is a control circuit for a modulating control 87 and the motor 86 operated from the burner system. The motor 86 is used to position dampers for control of the air flow between a high fire (full air flow capability) to a low fire (a minimum air flow capability) position. The modulating control 87 associated with this provides the necessary rebalance for the position sensitive motor. These devices are of a conventional design, and are used in the conventional manner in the present invention. Four terminals 90, 91, 92 and 93 are provided along with the, conductors 94, 95, and 96.
Connected between terminals 93 and 91 is a normally open timer contact 97 and a normally closed contact 98. Connected between terminal 90 and terminal 91 is a normally open contact 99, whereas between the terminal 92 and a common junction between the contacts 97 and 98, is connected a normally closed contact 101. This arrangement of contacts and wiring provides for the necessary positioning of the air flow damper within the burner system between the high and the low fire positions. A modulating operation in between the high and low positions is provided in the normal run condition. By normal run it is meant that the device is not sequencing to try and light the burner, but is allowing the burner to operate fully to provide the heat necessary to the control 87.
Before describing the operation of the system, FIGS. 2 and 3 will be described since their description will aid in understanding the present invention.
'In FIG. 2 there is disclosed a bar chart of the portion of the cycle versus the programer time in seconds. The bar chart is substantially self explanatory. The bar chart shows the device going through a prepurge period, ignition and pilot period, a main valve energized period, and then a modulating control between the startup and the satisfaction of heat to the controller 15. Once the system reaches 105 seconds of operation, the timer motor 26 ceases to operate and the system operation continues on until the heat supplied by the burner satisfies the demand at the controller 15. At shut down (controller opening), the sequence picks up at 105 seconds and goes through a post purge period to 120 seconds. The 120 second mark in fact again is the zero point, and the cycle is ready to start over again.
FIG. 3 discloses a graph of the burner damper position, between the high and low fire positions, as a function of the programer time in seconds. The graph of FIG. 3 shows that the damper or burner starts in the low fire and then moves to the high fire position at 7 seconds, where it remains until 41 seconds. At 41 seconds it returns to the low fire position and stays at the low fire position during the entire low fire proof and ignition of the main valve. The device at 95 seconds then goes into a modulating condition where the burner damper and operating level varies with demand until the controller 15 is operated to open circuit to shut the system down. At that time the modulation ceases and the device returns the damper to the low fire position at l 16 seconds so that the system is ready to start at the next call for heat.
OPERATION If power supplied on conductors l2 and 13, and all of the limits and interlocks are properly positioned, the
controller 15 closes to supply electrical energy to the preignition interlock 22 through terminal 24. Power is then supplied through the normally closed switch 33 and the normally closed switch 56 to the conductor 55. This supplies the electrical energy to the transformer 52 to energize the plug-in amplifier 51 so that any flame detected at the flame detector 50 is appropriately amplified to control the 2K relay.
Energy is also supplied through the normally closed contact 2K3, through the safety switch heater 37 and the safety switch contact SS2 (which is normally closed), and through the 1K relay coil 41 to conductor 13. The energy supplied to coil 41 pulls the relay 1K in at which time the contact 1K2 closes along with relay contact 1K3 and 1K1. The 1K3 relay supplies energy on conductor 71 to the burner motor 78 to supply the air flow necessary to close the air flow switch 30. Upon closing the air flow switch 30, energy is supplied to terminal 31, through the relay contact 1K2 which shunts the normally closed contact 33, to power the plug-in amplifier 51. The contact (2 upon closing locks in the 1K relay during normal operation of the burner control device. The timer contacts 73 and 74 along with the low fire interlock 80 and the high fire interlock 83 provide a continuous supply of energy to the timer motor 26 in a normal operating sequence. This allows the timer to progress through operation thereby closing the timer contacts 66, 67 and 68 in the proper sequence to create ignition, light the pilot, and then light the main burner.
In a normal sequence of operation the flame detector 50 is exposed to and will sense the operation of the pilot flame and the main burner. In the prepurge sequence, the normally closed switch 72 has gone through a cycle of opening and closing, and will again have closed to complete an energizing circuit for the timer motor 26 thereby keeping the timer motor in operation even though the switch 2K1 opens at the time the flame detector senses the existence of flame. The existence of flame at 60 seconds or shortly after closes the normally open relay contact 2K2 to provide a source of continuing energization for the transformer 52 and the plug-in amplifier 51, as well as for the ignition device 60, the pilot valve 62, and the main valve 64. At 57 seconds the energizing circuit for the safety switch heater 37 has been activated by closing the normally open contact 44 and will remain active until the flame detector 50 senses the existence of flame at which time the normally closed 2K3 flame relay contact opens. As long as switch 34 is open and the relay contact 2K3 is also open, no heating circuit is completed for the safety switch heater 37.
As soon as the system reaches seconds, the operation is in full normal modulating control. The modulating control 87 varies with temperature to move the wiper of the potentiometer to cause the motor 86 to in turn operate a modulating valve and damper to supply the proper level of burner operation. This will go on until the controller 15 opens, until some malfunction occurs which opens one of the limit switches, or a failure in the sensed flame occurs and is detected by the novel circuit configuration of the present invention.
ABNORMAL OPERATION The invention in the present application is directed to a unique function within the system which detects an abnormal type of operation. In the event that the flame detector 50, plug-in amplifier 51, or the 2K relay operates in a manner to close the 2K relay contact during the prepurge portion of the cycle, the unit senses this malfunction and shuts the device down on safety. Any failure in the flame detector system which causes the 2K relay to be energized during a substantial portion of the prepurge cycle causes the safety switch heater 37 to be operably energized to time out on safety. This opens the safety switch contact SS2 and closes the safety switch contact SS1 to the alarm 47. Since the safety switch means of the present invention is a manual reset type of safety switch, this operation shuts down the system and causes an alarm to be given requiring the system to be reset manually.
The safety function is accomplished by the normally closed 2K1 relay contact opening, and the normally open 2K4 contacts closing. The opening of the 2K1 contact during the prepurge portion of the cycle re-. moves the energizing circuit for the timer motor 26 and the timer stops operating. At the same time the closing of the 2K4 relay contacts completes a circuit through contact 34 and the safety switch heater 37 to the winding 42 of the relay 1K. As was explained in the previously mentioned I-Iamelink patent this creates a heating cycle for the safety switch heater 37 and causes the safety switch contacts SS2 to open and lock themselves in an open condition.
It is thus apparent that the present arrangement provides with a simple set of contacts a safety feature that has not hitherto been available on programing types of burner control devices. The present system provides for the monitoring of the flame detector circuit during the prepurge portion of the cycle, and thereby provides safety over a large portion of the operation of the programer.
In addition to the function above noted for safety, the present system includes two other desirable features. The use of the relay contact 2K2 in parallel with the normally closed timer contact 56 provides an energizing path for the plug-in amplifier 51 through the transformer 52 after the controller has closed. This means that the plug-in amplifier 51 and its associated equipment is energized only when the controller is calling for operation of the device and no unnecessary energy is drawn by this system. This can be accomplished with solid state systems or with tube type of equipment where the filaments only have been provided with a continuous source of heating current.
The present invention is very broadly directed to a safer type of flame safeguard burner control device for operating a burner system. By utilizing flame responsive contacts in the safety switch circuit and the timer motor circuit it is possible to detect failures in the flame detection circuit prior to the end of the purge period thereby providing for a safe start up. This is further reinforced by a circuit which provides for a guarantee that the fuel supply is at its proper position, that is that the high fire interlock switch has operated. These and other aspects of the present invention will become obvious when the present specification is considered in light of the appended claims.
The embodiments of the invention in which an exclusive property or right is claimed are defined as follows:
1. A programing burner control device adapted to be connected as part of a burner system which includes flame sensor means, ignition and fuel supply means, condition responsive interlocks, and initiating control means whereby said programing burner control device is adapted to be connected to a source of operating power when said interlocks and said control means are properly actuated, including: motor driven cam means and cam operatedswitch means with said switch means operated in a sequence to program said burner system in a predetermined operating mode; safety switch means including heater means and normally closed safety switch contacts with said heater means capable of opening said safety switch contacts upon said heater means being operatively energized for a period of time; load control relay means including a plurality of load control contacts with at least one of said control contacts controlling the energization of said motor driven .cam means upon initiation of operation of said burner system; amplifier means and flame relay means wherein said amplifier means is adapted to be connected to said flame sensor means with said flame relay means normally operated in response to said flame sensor means detecting the presence of flame; said flame relay means including a normally open contact which when closed completes a circuit for energizing said safety switch heater means in a prepurge portion of said burner system operation; and said flame relay means further including a normally closed contact which when opened interrupts power to said motor driven cam means in a prepurge portion of said burner system operation; said flame relay means operation causing said programing burner control device to stop the operation of said motor driven cam means with the concurrent heating of said safety switch heater means in the event of operation of said flame relay means during said prepurge portion of operation to safely stop said burner system.
2. A programing burner control device as described in claim 1 wherein said relay means are electromagnetic relays.
3. A programing burner control device as described in claim 2 wherein said amplifier means is capable of full operation immediately upon application of electrical power by way of operation of said initiating control means.
4. A programing burner control device as described in claim 3 wherein said flame relay means further includes a second normally open contact in parallel circuit with a first cam operated switch of said cam operated switch means; and said cam operated switch being normally closed during said prepurge portion of said burner system operation and an initial ignition portion of said burner system operation; said cam operated switch opening after said second flame contact has closed; said energized flame relay means insuring that said control device is energized; said second flame contact opening if the flame is lost to thereby deenergize said control device.
5. A programing burner control device as described in claim 4 wherein said amplifier means is a solid state amplifier.
6. A programing burner control device as described in claim 3 wherein said amplifier means is a solid state amplifier.
7. A programing burner control device as described in claim 6 wherein said safety switch means further includes latching means with manual reset to latch said normally closed safety switch contacts in an open condition when said heater means has been energized sufficiently to open said closed safety switch contact means.
8. A programing burner control device as described in claim 7 wherein said cam operated switch means includes second cam operated switch means which is adapted to complete a circuit through a high fire interlock switch to energize said motor driven cam means during said prepurge portion of said burner system operation to insure that said system is in a high fire operating mode.

Claims (8)

1. A programing burner control device adapted to be connected as part of a burner system which includes flame sensor means, ignition and fuel supply means, condition responsive interlocks, and initiating control means whereby said programing burner control device is adapted to be connected to a source of operating power when said interlocks and said control means are properly actuated, including: motor driven cam means and cam operated switch means with said switch means operated in a sequence to program said burner system in a predetermined operating mode; safety switch means including heater means and normally closed safety switch contacts with said heater means capable of opening said safety switch contacts upon said heater means being operatively energized for a period of time; load control relay means including A plurality of load control contacts with at least one of said control contacts controlling the energization of said motor driven cam means upon initiation of operation of said burner system; amplifier means and flame relay means wherein said amplifier means is adapted to be connected to said flame sensor means with said flame relay means normally operated in response to said flame sensor means detecting the presence of flame; said flame relay means including a normally open contact which when closed completes a circuit for energizing said safety switch heater means in a prepurge portion of said burner system operation; and said flame relay means further including a normally closed contact which when opened interrupts power to said motor driven cam means in a prepurge portion of said burner system operation; said flame relay means operation causing said programing burner control device to stop the operation of said motor driven cam means with the concurrent heating of said safety switch heater means in the event of operation of said flame relay means during said prepurge portion of operation to safely stop said burner system.
2. A programing burner control device as described in claim 1 wherein said relay means are electromagnetic relays.
3. A programing burner control device as described in claim 2 wherein said amplifier means is capable of full operation immediately upon application of electrical power by way of operation of said initiating control means.
4. A programing burner control device as described in claim 3 wherein said flame relay means further includes a second normally open contact in parallel circuit with a first cam operated switch of said cam operated switch means; and said cam operated switch being normally closed during said prepurge portion of said burner system operation and an initial ignition portion of said burner system operation; said cam operated switch opening after said second flame contact has closed; said energized flame relay means insuring that said control device is energized; said second flame contact opening if the flame is lost to thereby deenergize said control device.
5. A programing burner control device as described in claim 4 wherein said amplifier means is a solid state amplifier.
6. A programing burner control device as described in claim 3 wherein said amplifier means is a solid state amplifier.
7. A programing burner control device as described in claim 6 wherein said safety switch means further includes latching means with manual reset to latch said normally closed safety switch contacts in an open condition when said heater means has been energized sufficiently to open said closed safety switch contact means.
8. A programing burner control device as described in claim 7 wherein said cam operated switch means includes second cam operated switch means which is adapted to complete a circuit through a high fire interlock switch to energize said motor driven cam means during said prepurge portion of said burner system operation to insure that said system is in a high fire operating mode.
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Cited By (17)

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US4035135A (en) * 1976-02-05 1977-07-12 Honeywell Inc. Postpurge pilot burner sequencing means
US4101258A (en) * 1977-05-25 1978-07-18 Honeywell Inc. Fuel burner sequencing device with safety checking means
US4102630A (en) * 1976-11-23 1978-07-25 Sundstrand Corporation Burner control system
US4145179A (en) * 1976-11-29 1979-03-20 Hitachi, Ltd. Combustion control system
US4168949A (en) * 1977-09-26 1979-09-25 Honeywell Inc. Flame signal stabilization circuit
US4180380A (en) * 1976-04-13 1979-12-25 United Gas Industries Limited Electrical controls for heating appliances
US4451227A (en) * 1983-01-03 1984-05-29 Honeywell Inc. Flame safeguard sequencer having switch test functions
US4451226A (en) * 1983-01-10 1984-05-29 Honeywell Inc. Flame safeguard sequencer having safe start check
US4451225A (en) * 1983-01-31 1984-05-29 Honeywell Inc. Flame safeguard sequencer having interlock checking means
US4482312A (en) * 1979-06-20 1984-11-13 Electronics Corporation Of America Burner control system
US4999792A (en) * 1989-01-27 1991-03-12 Honeywell Inc. Method and apparatus for automatic fuel changeover
US5360335A (en) * 1992-10-22 1994-11-01 Honeywell Inc. Fuel burner control system with selectable standing pilot mode
US20030003411A1 (en) * 1999-05-20 2003-01-02 Potter Gary J. Low fire start control
US20070287111A1 (en) * 2004-06-01 2007-12-13 Roberts-Gordon Llc Variable input radiant heater
US20080127963A1 (en) * 2006-12-01 2008-06-05 Carrier Corporation Four-stage high efficiency furnace
US20100024244A1 (en) * 1999-05-20 2010-02-04 Potter Gary J Heater and controls for extraction of moisture and biological organisms from structures
US8726539B2 (en) 2012-09-18 2014-05-20 Cambridge Engineering, Inc. Heater and controls for extraction of moisture and biological organisms from structures

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Cited By (19)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US4035135A (en) * 1976-02-05 1977-07-12 Honeywell Inc. Postpurge pilot burner sequencing means
US4180380A (en) * 1976-04-13 1979-12-25 United Gas Industries Limited Electrical controls for heating appliances
US4102630A (en) * 1976-11-23 1978-07-25 Sundstrand Corporation Burner control system
US4145179A (en) * 1976-11-29 1979-03-20 Hitachi, Ltd. Combustion control system
US4101258A (en) * 1977-05-25 1978-07-18 Honeywell Inc. Fuel burner sequencing device with safety checking means
FR2401383A1 (en) * 1977-05-25 1979-03-23 Honeywell Inc MEANS OF SEQUENCING FOR OIL BURNER
US4168949A (en) * 1977-09-26 1979-09-25 Honeywell Inc. Flame signal stabilization circuit
US4482312A (en) * 1979-06-20 1984-11-13 Electronics Corporation Of America Burner control system
US4451227A (en) * 1983-01-03 1984-05-29 Honeywell Inc. Flame safeguard sequencer having switch test functions
US4451226A (en) * 1983-01-10 1984-05-29 Honeywell Inc. Flame safeguard sequencer having safe start check
US4451225A (en) * 1983-01-31 1984-05-29 Honeywell Inc. Flame safeguard sequencer having interlock checking means
US4999792A (en) * 1989-01-27 1991-03-12 Honeywell Inc. Method and apparatus for automatic fuel changeover
US5360335A (en) * 1992-10-22 1994-11-01 Honeywell Inc. Fuel burner control system with selectable standing pilot mode
US20030003411A1 (en) * 1999-05-20 2003-01-02 Potter Gary J. Low fire start control
US7568908B2 (en) 1999-05-20 2009-08-04 Cambridge Engineering, Inc. Low fire start control
US20100024244A1 (en) * 1999-05-20 2010-02-04 Potter Gary J Heater and controls for extraction of moisture and biological organisms from structures
US20070287111A1 (en) * 2004-06-01 2007-12-13 Roberts-Gordon Llc Variable input radiant heater
US20080127963A1 (en) * 2006-12-01 2008-06-05 Carrier Corporation Four-stage high efficiency furnace
US8726539B2 (en) 2012-09-18 2014-05-20 Cambridge Engineering, Inc. Heater and controls for extraction of moisture and biological organisms from structures

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