US2385616A

US2385616A - Sequence control system

Info

Publication number: US2385616A
Application number: US493066A
Authority: US
Inventors: Eaton John
Original assignee: General Electric Co
Current assignee: General Electric Co
Priority date: 1943-07-01
Filing date: 1943-07-01
Publication date: 1945-09-25
Anticipated expiration: 1962-09-25

Description

Sept. 25, 1945. EATON 2,385,616

SE UENCE coNTfioL SYSTEM Filed July 1, 1943 Fig.2.

TIMER 4 f R HEATH? 7 START 74 TIME LOCK our H c Ifivefitor':

John Eaton, b x/ 6M4,

His Attorney.

Patented Sept. 25, 1945 2,385,616 SEQUENCE coN'raoL SYSTEM John Eaton, Schenectady, N. Y., asslgnor to General Electric Company, a corporation of New York Application July l, 1943, Serial No. 493,068

11 Clalmsi The invention relates to sequence control systems, particularly automatic combined timing and condition responsive sequence control systems, suitable for controlling oil burners or other devices which require an automatic safety lock out in case a prerequisite condition is not established within a predetermined time interval after starting operation of the device to control another condition.

My prior Patents 2,085,577 and 2,278,252, and also my application Serial No. 493,008, filed concurrently herewith, disclose and claim certain improvements in sequence control systems of the above type.

One of the objects of the present invention is to further improve sequence control systems of the above type by providing an improved form of I electrical safety lockout.

A more specific object is to provide an improved form of control system employing an electrically heated thermal timer and a pair of electrically differentiated relays selectively energized for providing a combined time and condition responsive sequence control and a safety lockout.

A further object is to provide an improved series and multiplex shunt circuit combination for enabling the thermal timer'and the pair of electrically difierentiated relays to provide not only automatic safety lockout but also undervoltage protection, and insure that the control will start the burneror other device controlled thereby only when all of the control elements have returned to their initial starting position.

Other objects and advantages of the invention will appear in the following description of the accompanying drawing in which Fig. 1 is a schematic circuit diagram of an oil burner control system embodying the improvements of the present invention; and Figs. 2, 3, 4, and 5 are simplifled line diagrams of the control circuits of Fig. 1 showing more clearly the series and multiplex shunt control connections established during start time, run and lockout phases of operation of the burner control system shown in Fig. 1.

In Fig. 1 the oil burner I0 is shown as of the usual type having a driving motor ll provided with an operating winding l2. The combustible mixture of oil and air provided by burner l0 .upon energization of th operating winding I2 is ignited by means of the ignition transformer 13 and the ignition arc electrodes ll.

The burner It is operated automatically under stat, or'responsive to any other condition that is to be regulated by operation of the burner ll.

The automatic operation of burner III also is under the control of a safety condition responsive switch II which, in the form shown, is responsive to the absence and presence of combustion and has the expansible tube ll located to be heated when combustion is established for operating the slip clutch contact arm it from the cold position C in which it is shown to the hot position H.

A thermal timer 2. having an electric heater 2| is arranged to open the timed switch T at the end of a predetermined heating interval, a snap action opening and closing of switch T being requisite condition responsive switch It, and the thermal timer 20 so as to be initially controlled by the master switch is and then selectively controlled by the prerequisite condition responsive switch and the thermal timer 20. The main relay A is provided with a main contact A1 for controlling the energization of the burner motor operating winding l2. Relay A also is provided with an auxiliary contact A: for controlling the opening and closing of one of the shunt circuits involved in the improved control system of the present invention.

The auxiliary relay R is provided with a main contact R1 for closing and opening the energizing circuit of the primary winding of the ignition transformer I3, which, it will be observed, is energized in parallel with the motor operating winding I! when both the relay switches A1 and R1 are closed. The auxiliary switch R: controls the opening and closing of another shunt circuit involved in the improved sequence control system of the present invention. This shunt circuit includes the lockout resistor LII.

In accordance with the present invention, the two relays A and R are provided with separate operating electromagnets electrically differentiated so as to have different minimum energization response, that is, relay A will drop out at a higher energization value than the value required to drop out relay R, both of the relays being biased to their drop-out positions in which they are' shown.

Dperation and auxiliary contacts.

ductor 32, master switch l5, conductor 33, the operating winding 34 of relay R, conductor 35, the normally closed time switch T, conductor 36, the prerequisite condition responsive switcharm 18 in its initial position C in which it is shown, conductor 31, the heater 2!, the operating winding 38 of relay A, and conductor 39, to the other supply line L2. If low voltage energization of the control circuits is desired, the circuit as just described may be energized from the secondary of a voltage reducing transformer having its primary permanently connected across the supply lines LI, L2.

Upon closure of the main series control circuit, which is separately shown in Fig. 2, by the master switch l5, the operating windings'of both relays A and R, together with the thermal timer healer 2! are simultaneously energized. I Both rela A and R pick up and close their respective main As a result of closure of the main contacts A1 and R1, the operating winding 12 of the oil burner motor is energized to start operation thereof to project a combustible mixture of oil and air from the burner nozzle. At the same time the ignition transformer is is energized in parallel with the motor operating winding i2 to establish an ignition are at the f shunts the flame detector cold contact C.

The improved control system continues in operation with the two shunt connections made, as shown in Fig. 3, during the predetermined heating time of the thermal itimer 20. Thus the opportunity is afforded for the oil burner to.;successfully establish combustion during this interval. I

In case combustion issuccessfully established,

then the combustion responsive switch 5 a will respond to move its contact arm l8 from the cold contact C to the hot contact H. The opening of the cold contact C, however, leaves the lookout resistor L0 still in shunt with the thermal timer contact T and the-auxiliary contact A2, as shown in Fig. 4. The closure of the flame detector hot contact H establishes a third shunt circuit ex= tending around the operating winding of relay R and the timer contact T. Thus, as soon as the closure of the hot contact H occurs, relay R is in efl'ect short-circuited and thereby deenergized.

As a result, relay R opens its main contact R1 todeenergize the ignition transformer 83. At the same time, relay R opens its {auxiliary contact R2 to open the lockout shunt circuit including the lookout resistor L0. This leaves the operating winding of the main control relay A ener= gized in series with the timer heater 2! with the burner running control circuit extending in series through the auxiliary contact Ag, the hot contact H of the flame detector and the master switch I5. Thus in case of voltage failure, relay A will become deenergized to stop operation of the burner I0 and also open the auxiliary contact A2 to insure that all the control elements return to their initial positions before the burner it can be restarted. Also if for some reason the burner combustion should fail so that the flame detector hot contact H opens, then relay A also becomes deenergized to stop the burner and opens its auxiliary contact A: to insure the same result. Likewise, whenever the master switch responds to open its contacts, relay A is deenergized to stop operation of the burner and insure return of all theparts to their initial positions.

In case combustion is not successfully established before the end of the predetermined heating period of the thermal timer 2!), then the flame detector cold contact C will remain closed and the hot contact H will remain open. As a result, when the thermal timer switch T is opened, as shown in Fig. 5, the lockout shunt circuit closed by auxiliary contact R2 and including the lockout resistor L0 becomes eifective to maintain the series energizing current of relay R through the heater 2| and the operating winding of relay A at a value which is below the minimum energization response value of relay A but above the minimum energization response value of relay R. Consequently, relay A will drop out and thus return its contacts to the circuit opening position in which they are shown in Fig. 1. The opening of contact A1 will stop the burner it while the opening of contact A: will remove the separate shunt circuit from the flame detector cold contact C. However, the timer heater it will remain effectively energized along with relay R so as to maintain the timed switch T open until the relay R is deenergized by opening of the circuit controlled by the master switch i 5. This may be accomplished by opening the main switch controlling the power supply lines Ll, L2. When relay R is thus deenergized, then its auxiliary contact R2 opens the shunt circuit through the lock out resistor Lil and restores all of the parts to their initial positions.

What I claim as new and desire to secure by Letters Patent oi the United States is:

1. In a control system, a pair of control devices having separate electrically differentiated electroresponsive operating means and an electric heater connected to be energized therewith in a series circuit having normally closed thermally actuated switching means therein opened by the heating action of said heater at the end of a limited heating period, and a current limiting shunt interconnected by one of said devices upon,

energization of said operating means thereof withg said switching means for preventing both de-g energization of said heater and said operating;

means of said one device and efiective energization of said operating means of the other control device upon said opening of said switching means. r

2. In a control system, a pair of control devices having separate electrically differentiated electroresponsive operating means, an electric heater connected to be energized in a series energizing circuit having said operating means therein and normally closed thermally actuated switching means therein opened by the heating action of said heater at the end of a limited'heating period, a current limiting shunt interconnected by one of said devices upon energization'of said operating means thereof with said switching means for preventing both deenergization of said heater and said operating means of said one device and effective energization of said operating means of the other control device upon said opening of said switching means, and means for shunting said shunt and said operating means of said one device to maintain both said heater and said operating means of said other control device effectively energized upon said opening of said switching means.

3. In a sequence control system, a pair of control devices having separate electrically diflerentiated electroresponsive operating means energized in a series circuit having an electric heater therein and electro-thermal time switching means heated thereby for opening said circuit at the end of a heating period, a current limiting shunt interconnected by one of said devices upon energization of said operating means thereof with said time switching means for preventing both deenergization of said heater and effective energization of said operating means of the other of said devices after said period, and condition responsive switching means for shunting said operating means of said one device and said time switching means during said period to maintain said operating means of said other device and said heater effectively energized thereafter.

4. In a sequence control system, a pair or control devices having separate electrically differentiated electroresponsive operating means and a heater connected to be energized in a series energizing circuit having condition responsive switching means for closing said circuit and normally closed thermo-electric time switching means actuated by said heater for opening said circuit at the end of a heating period, a current limiting shunt interconnected by one of said devices upon energization of said operating means thereof with said time switching means for preventing both deenergization of said heater and eifective energization of said operating means of the other of said devices after said period, and switching means responsive to a predetermined condition for shunting said operating means of said one device and said time switching means during said period to maintain said operating means of said other device and said heater eiiectively energized thereafter under the control of both said condition responsive switching means.

5. In a sequence control system, a pair of devices having separate electrically diiierentiated electroresponsive operating means and a heater connected to be energized in a series circuit having a pair of separate condition responsive switching means for closing said circuit and normally closed thermo-electric time switching means thereby energized for opening said circuit at the end of a heating period, a current limiting shunt interconnected by one of said devices upon energization of said operating means thereof with said time switching means for preventing both deenergization of said heater and effective energization of said operating means of the other of said devices after said period, a switch actuated by said other device upon energization of said operating means thereof for shunting one of said condition responsive switching means, and separate connections controlled by said one condition responsive switching means for shunting said operating means of said one device and said time switching means during said period to maintain said operating means of said other device and said time switching means effectively energized thereafter under the control of both said condition responsive switching means.

6. In a sequence control system, a pair of control devices having separate electrically differentiated electroresponsive operating means having a series energizing circuit provided with a pair of separate condition responsive switching means for closing said circuit and normally closed thermo-electric time switching means thereby energized for opening said circuit at the end of a heating period, a current limiting shunt interconnected by one of said devices upon energization of said operating means thereof in shunt with said time switching means for preventing both deenergization of said time switching means and eifective energization of said operating means of the other of said devices after said period, a switch actuated by said other device upon energization of said operating means thereof for shunting said circuit around one of said condition responsive switching means, and separate connections controlled by said one condition responsive switching means for shunting said operating means of said one device and said time switching means during said period to maintain said operating means of said other device and said time switching means effectively energized thereafter under the control of both said condition responsive switching means.

7. A sequence control system having, in combination, a pair of control devices having separate electrically differentiated electroresponsive operating means, one responsive to a lower energization than the other, a thermal timer having electrical heating means connected to be energized in series circuit with said operating means above the energization response of said operating means of said'one device.

8. A sequence control system having, in combination, a pair of relays, each having a separate operating electromagnet one having a lower dropout energization than the other, a thermal timer having electrical heating means connected to be energized in a series circuit with said operating electromagnets to pick up both said relays for a limited period and having a timed switch for opening said circuit at the end of said period, and a circuit for shunting said switch to maintain said heating means energized after said period, said shunt circuit including a switch closed by said one relay upon pick-up thereof and a resistor for reducing the energizing current of said heating means upon opening of said timed switch to a value below the dropout energization of said operating electromagnet of the other of said relays and above the drop-out energization of said operating electromagnet of said one relay.

9. A sequence control system having, in combination, a pair of control devices having separate electrically differentiated electroresponsive operating means, one responsive to a lower energization than the other, a thermal timer having electrical heating means connected to be energized in a series circuit with'said operating means and having a timed switch for opening said circuit at the end of a predetermined heating period, a condition responsive switch connected in series with said timed switch for opening said circuit under predetermined conditions,

and a circuit for shunting both said timed switch and said condition responsive switch to maintain said heating means energized independently of both said switches after said period, said'circuit including a switch closed by one of said devices upon energization of said operating means thereof and a resistor for maintaining the energization of said heating means upon opening of said timed switchbelow the minimum energization response of said operating means of the other of said devices and above the minimum energization response oi said operating means of said one device.

I 10. A variable sequence control system having, in combination, a pair of control devices, a separate operating electromagnet for each device, said operating elctromagnets being responsive to ditierent minimum energizations, means for variably controlling the energization of said operating electromagnets including a thermal timer having electrical heating means connected to be I energized in series circuit with said operating electromagnets to effect joint operation oi said devices for a limited period and having a timed switch for openingsaid circuit at the end of said period, a shunt circuit for shunting said switch to maintain said heating means energized after said period, said shunt circuit including a switch closed by one of said devices upon ener= gization of said operating electromagnet thereof and a resistor for maintaining the energization of said heating means upon opening of said timed switch below the minimum energization response of said operating electromagnet of the other of said devices and above the minimum energization response of said operating electro= magnet 01 said one device and condition responsive switching means for short-circuiting both said timed switch and said one device to eflect the opening of said shunt circuit upon the ocaesaeie currence of a predetermined condition before operating electromagnet of said other device and said heating means effectively energized in series thereafter.

11. A sequence control system having, in combination, a pair of control devices, a separate operating electromagnet for each device, one responsive to a lower energization than the other, a thermal timer having electrical heating means connected to be energized in a series circuit with said operating electromagnets and having a timed switch for opening said circuit at the end of a predetermined heating period, a condition responsive two-way switch connected in series with said timed switch for closing said series circuit only in response to a predetermined condition, a first shunt circuit for shunting both said timed switch and said condition responsive switch to maintain said heater energized after said period, said first shunt circuit including a switch closed by said one device upon energization thereof and a resistor for maintaining the energization of said heating means upon opening of said timed switch below the minimum energization response of said operating electromagnet of the other of said devices and above the minimum energization response of said operating electromagnet of said one device and a second shunt circuit closed by said two-way switcharound said timed switch and said operating electromagnet of said one device in response to the occurrence of a different predetermined condition before the end of said period for efiecting the opening of said first shunt circuit and maintaining said operating electromagnet of said other device and said heater energized in'series thereafter.

JOHN EATON.