CA1280145C - Cooktop appliance with improved power control - Google Patents

Cooktop appliance with improved power control

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Publication number
CA1280145C
CA1280145C CA000559188A CA559188A CA1280145C CA 1280145 C CA1280145 C CA 1280145C CA 000559188 A CA000559188 A CA 000559188A CA 559188 A CA559188 A CA 559188A CA 1280145 C CA1280145 C CA 1280145C
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Canada
Prior art keywords
power
heating unit
voltage level
heating
rms voltage
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Expired - Fee Related
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CA000559188A
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French (fr)
Inventor
Thomas Roy Payne
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General Electric Co
Original Assignee
General Electric Co
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Application granted granted Critical
Publication of CA1280145C publication Critical patent/CA1280145C/en
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    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02BCLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO BUILDINGS, e.g. HOUSING, HOUSE APPLIANCES OR RELATED END-USER APPLICATIONS
    • Y02B70/00Technologies for an efficient end-user side electric power management and consumption
    • Y02B70/30Systems integrating technologies related to power network operation and communication or information technologies for improving the carbon footprint of the management of residential or tertiary loads, i.e. smart grids as climate change mitigation technology in the buildings sector, including also the last stages of power distribution and the control, monitoring or operating management systems at local level
    • Y02B70/3225Demand response systems, e.g. load shedding, peak shaving
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y04INFORMATION OR COMMUNICATION TECHNOLOGIES HAVING AN IMPACT ON OTHER TECHNOLOGY AREAS
    • Y04SSYSTEMS INTEGRATING TECHNOLOGIES RELATED TO POWER NETWORK OPERATION, COMMUNICATION OR INFORMATION TECHNOLOGIES FOR IMPROVING THE ELECTRICAL POWER GENERATION, TRANSMISSION, DISTRIBUTION, MANAGEMENT OR USAGE, i.e. SMART GRIDS
    • Y04S20/00Management or operation of end-user stationary applications or the last stages of power distribution; Controlling, monitoring or operating thereof
    • Y04S20/20End-user application control systems
    • Y04S20/222Demand response systems, e.g. load shedding, peak shaving
    • Y04S20/224

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  • Control Of Resistance Heating (AREA)

Abstract

COOKTOP APPLIANCE WITH IMPROVED POWER CONTROL
ABSTRACT
A cooking appliance adapted for energization by a standard domestic household power supply employs a power control arrangement which accommodates electric resistive heating units designed for operation at a maximum RMS voltage level less than the RMS voltage level of the output power signal of the domestic power supply. The power control system couples power pulses from the external power supply to the heating unit at one of a plurality of available pulse repetition rates, each repetition rate establishing a corresponding RMS
voltage level for application of power to the heating unit. The repetition rate associated with the maximum user selectable power setting for the appliance is effective to apply an RMS voltage level to the heating unit which corresponds to the voltage level for which the heating unit was designed. When a heating unit is turned from Off to On the power control system overdrives the unit at full supply voltage for a brief transient heat up period to rapidly heat the unit to its radiant temperature. The duration of this heat up period is controlled as a function of the elapsed time since the unit was last turned Off.

Description

30~4~
PATENT - 9D-MA-16819 - Payne BACKEROU~ID OF THE INYENTION
This invention relates generally to glass-ceramic cooktop appliances and particularly to electronic power control systems for such apptiances.
Use of glass-ceramic plates as cooktops is well known.
Advantages of the smooth surface include pleasing appearance and easy cleanability. Glass-ceramic cooktop appliances using heating units which radiate substantially in the infrared region in combination with a glass-ceramic material which is transparent to such radiation provides the appearance and convenience advantages of conventional thermal conduction type glass-ceramic cooktops plus the additional advantage of greater energy efficiency and improved cooking performance due to a faster response to changes in user selected power settings.
- Infrared heating units employ resistance wire elements designed to radiate primarily in the 1-3 micron region of the electromagnetic spectrum. The total output power and watts density parameters for the heating elements in such units is dictated by cooking performance requirements. For domestic app7iances the power supply available in the home is aenerally the line voltage from the local power company. In the United States this is typically 120 and 240 volts. Resistance wire heating elements designed to provide the desired power and watts density at these voltages are constructed of relatively small diameter delicate expensive wire. Significant cost advantages could be enjoyed if the wire diameter could be increased thereby increasing the structural integrity of the wire and making it possible to use a less costly wire material. However, with the power and watts density constrained by cooking performance requirements, any increase in wire diameter must be compensated for by a decrease in voltage. In view of the high current required to provide the des1red .

PATE~T - 9D-MA-16819 - Payne power, a step-down transformer would be impractical from both a size and cost standpoint.
Thus, to enjoy the benefits of a less costly, ~ore reliable infrared heating unit there is a need for a cost effective practical energy efficient means of reducina the effective voltage apptied to the heating units to an effective voltage level less than a domestic line voltage.
Another consequence of increasing wire diameter is that the time required for the wire to reach its radiant temperature is increased. Infrared heating units, at least when operating at or near the maximum user selected power setting, glow brightly. ~his glow is perceivable by the user through the glass-ceramic cooktop. This glow can be advantageously used to provide prompt visual feedback to the user that the selected unit is operating properly. One such arrangement for rapidly bringing a heating element to its radiatina temperature to provide this feedback using commercially available heating elements made of molybdenum disilicide (~loSi2) or tungsten heating elements is disclosed in commonly assigned U.S. Patent 4,223,4g8. In that arrangement the unit is driven at the power level associated with the maximum user selectable power setting for a brief period when first turned on, reoar~ ess of the actual user selected setting to quickly heat the unit to its radiating temperature Since the heating element with the increased wire diameter was designed for operation at a lower effective or RMS voltaae, the heat up time can be reduced to an acceptable time by briefly over-driving the heating element at full line voltage. However, the overdrive time must be carefully limited to avoid over-stressing the wire. For example, if the unit is turned off and then on again before it has cooled sufficiently, applying the full line voltage for a time period ~hich ~'~.SO`1~5 PATENT - ~D-M~-1681g - Payne has no adverse affect on the wire when heating up from room temperature may damage the pre-heated wire. Use of wire temperature feedback information is impractically costly and complex. Thus, in a system in which the heating elements are designed primarily for operation at voltage levels less than the full line voltage, there is a need for a power control arrangement which can provide an overdrive capability for the elements when turned on but which can adjust the overdrive time to compensate for the past temperature history of the element.
In a multiple element cooktop appliance featuring heating units with elements designed for operation at a voltage stepped down from the normal line voltage, overdriving the elements at`full line voltaoe for short periods of time may draw excessive total current.
Household electrical service generally employs a SO amp breaker in the powe~ circuit for the main kitchen cooking appliances. In a four-unit cooktop appliance for example, the total current is limited by conventional design practice to a maximum level of 35 amps leaving 15 amps for the oven. Since this limit could be exceeded if one or more of the heating units is overdriven depending on the power levels being applied to the remaining units, there is a need for a power control arrangement which can adjust the overdrive power levels to maintain the totàl current drawn by the heating units within design limits, while still heating the units to radiating temperature relatively quickly to provide the desired visual feedback to the user.
It is therefore an object of the present invention to provide an electric cooking appliance comprising at least one electric heating unit and a power control system which applies an effective voltage level to the heating unit at the maximum user selectable power setting for the unit which is less than the ~lS voltage of the domestic power supply so as to accommodate in the appliance heating units designed for l~V1~5 ~ PATE~JT - 9D-MA-16819 - Payne maximum steady state operation at a voltage level less than the domestic supply voltage~
It is a further object of the present invention to provide a cooking appliance of the aforementioned type in ~hich the power control system is operative to overdrive the heating units when initially turned on by applying a voltage level higher than the maximum user selectable level for a brief transient heat up period, the duration of which is limited as a function of the elapsed time stnce the last occurring use of the particular heating unit to avoid overheating a heating unit which is not yet cooled down from its previous use.
It is yet another object of the present invention to provide a cooktop appliance of the aforementioned type in which the power control system is operative to reduce the power level applied to the surface units during operation in the transient heat up period as necessary to maintain the total current drawn by the appliance within predetermined limits.
SUMMARY OF THE INVENTIO~I
The present invention provides a cool~ina appliance adapted for energization by a standard domestic household power supply characterized by an output power signal with a predetermined RMS output voltage, the appliance comprising at least one electric resistive Heating unit designed for steady state energization at a maximum RMS
voltage level less than the RMS voltage level of the output power signal of the external power supply. User actuable input selection means enables tne user to select one of a plurality of power settings including an Off setting for the heating unit. Power control means responsive to the input selection means is operative to couple power pulses from the external power supply to the heating unit at one of a plurality of available pulse repetition rates, each user selectable i4~

PATENT - 9D-M~-16819 - Payne power setting having associated with it a corresponding power pulse repetition rate, each repetition rate establishing a corresponding RMS
voltage level for application of power to the heating unit. The repetition rate associated with the maximum user selectable power setting is effective to apply an R~S voltage level to the heating unit which corresponds to ~le voltage level for which the heating unit was designed. By this arrangement the appliance can be equipped with heating units designed for operation at a voltage levet less than the normal supply voltage, yet which prov;de the output power and watt density normally associated with heating units designed to operate at the normal domestic supply voltages.
In accordance with another aspect of the invention, the power control means includes timing reans for measuring the elapsed time since the unit was last turned off by the user, and means for detecting the transition from an Off power setting to one of the non-Off power settings. Upon detection of such a transition the power ccntrol means is operative to implement a power pulse repetition rate ~)ich establishes an RMS voltage level for the heating unit which is higher than the maximum user selectable level, and preferably equal to the RtlS
voltage level of the external power supply output signal, for a transient heat up period. The duration of this transient heat up period is controlled as a function of the elapsed time since the unit was last turned off as determined by the timing means whereby the heating unit is protected against damage from overheating in the event sufficient time has not elapsed for it to cool since its last occurring use.
In accordance with yet another aspect of the invention, particularly applicable to a cooking appliance comprising multiple heating units designed for steady state energization at a maximum ~MS

PATENT - 9D-MA-16819 - Payne voltage level less than the RMS voltage level of the power signal from the external supply, the power control means further comprises means for determining when the total current drawn by the heating units exceeds a predetermined reference limit and means for reducing the effective voltage level applied to each of the heating units to reduce the total current to less than this limit. In a preferred form of the invention, each of the power pulse repetition rates implementable by the control means is assigned numerical designator. The means for determining when the total current exceeds the reference limit compri`ses means for computing the sum of the numerical designators corresponding to the power pulse repetition rates then being applied to each heating unit and comparing this sum to a predetermined reference value corresponding to the maximum acceptable total currenè for the heating units. The control means is operative to lower the repetition rate being applied to each of the heating units until this sum is less than the reference value. The control means is further operative to extend the duration of the transient heat up period for heating units operating in the transient heat up mode when the repetition rate being applied to such units is lowered, so as to compensate for the reduction in the effective voltage level applied to the overdriven units so that the heating units are still heated to radiating temperature relatively quickly to provide the desired visual feedback to the user.
While the novel features of the invention are set forth with particularity in the appended claims, the invention both as to organi~ation and content will be better understood and appreciated from the following detailed description taken in conjunction with the drawings.
BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a perspective view of a portion of a cooktop illustratively embodying the power control system of the present PATENT - 9D-M~-16819 - Payne invention;
FIG. 2 is a sectional side view of a portion of the cooktop of Fig. 1 showing details of one of the heating units;
FIG. -~ is an enlarged top vie~l of a portion of the cooktop of Fig. 1 showing details of the heating unit;
FIG. 4 is a functional block diagram of the power control circuitry for the cooktop of Fig. l;
FIG. S illustrates power signals corresponding to various operator selectable power settings and a timing signal for sychroni2ing control system operat;on with the power signal;
FIG. 6 is a simplified schemat;c diagram of a control circuit illustratively embodying the power control system of the present invention as embodied in the cooktop of Fig. l;
; FIG. 7 is a flow diagram of the Scan routine incorporated in the control program for the microprocessor in the circuit of Fig. j~, . ,.~ . .
FIGS. 8A and 8B are flow diagrams of the Keyboard Cecode routine incorporated in the control program for the microprocessor in the circuit of Fig. 6;
FIG. 9 is a flow diagram of the Off Timer rDutine incorporated in the control program of the microprocessor in the circuit of Fig. 6;
FIGS. lOA and lOB are flow diagrams for the Instant Cn routine ;ncorporated in the control program of the microprocessor in the circuit of Fig. 6;
FIG. 11 is a flow diagram of the PSET routine incorporated in the control program of the microprocessor in the circuit of Fig. 6;
FIG. 12 is a flow diagram of the Power Out routfne incorporated in the control program of the microprocessor in the circuit of Fig. 6; and FIG. 13 is a flQw diagram of the PWRSUM routine incorporated in the control program of the microprocessor in the circuit of Fig. 6, 01~
PATENT - 9D-MA-16819- Payne DETAILED DESCRIPTION OF THE ILLUSTRATIVE EMBODIMENT
Overview Fig. 1 illustrates a glass-ceramic cooktop appliance designated generally 10. Cooktop appliance 10 has a generally planar glass-ceramic cooking surface 12. Circular patterns 13(a)-13(d) ident;fy the relative lateral positions of each of four heatfng un;ts ~not shown) located directty underneath surface 12. A control and display panel generally designated 15 includes a complete set of touch control keys 17 and a seven-segment digital LE~ display element 19 for ea`ch heating unit.
The term glass-ceramic with reference to the material comprising cooktop surface 12 refers to a boron silicate m~terial in the Ceran family of materials. In particular in the illustrative en~odiment the glass-ceramic material is an infrared transmissive 7~) glass-ceramic material designated Ceran-85'manufactured by Schott, Incorporated.
In the discussion to follow the designators 14(a) - 14(d) shall be understood to refer to the heating units disposed under patterns 13(a) - 13(d) respectively. Surface unit 14(a) is shown in greater detall in Figs. 2 and 3. For purposes of illustration only one of the heating units is shown. It will be understood that heating units 14(b) - 14(d) are similar in structure to that shown in Figs~ 2 and 3. Heating units 14~a) and 14~c) are 8 inches in diameter. Units 14~b) and 14~d) are 6 inches in diameter.
Referring again to Figs. 2 and 3, heating unit 14~a) comprises an open coii electrical resistance element 16 of spiral configurat;on, which is designed when fully energized to radiate primarily in the infrared ~1-3 micron) region of the electromagnetic energy spectrum.
Element 16 is arranged in a concentric coil pattern and staked or 1 ~X~
PATENT - 9D-MA-16819 - Payne otherwise secured to a support disk 18 formed of Micropore material such as is available from Ceramaspeed under the name Microtherm' Disk 18 is supported in a sheet metal support pan 20, by an insulating liner 22 formed of a conventional aluminum oxide, silicon oxide composition.
This insulating liner 22 includes an annular upwardly extending portion 22(a) which serves as an insulating spacer between disk 18 and the underside of glass-ceramic cooktop 12. ~hen fully assembled, pan 2~ is spring loaded upwardly forcing the annular portion 22(a) of insulating liner 22 into abutting engagement with the underside of cooktop 12 by support means not shown. Heating units 14(a) - 14(d) are manufactured and sold commercially by Ceramaspeed under the part name. Fast Start Radiant Heater with Concentric Coil Pattern.
Fig. 4 illustrates in simplified schematic form, an embodiment of-a heating system to be controlled in accordance with the present invention. Each of four heating units 14(a) - 14(d) is coupled to a standard 240 volt, 60 Hz AC power source via power lines Ll and L2 through one of four triacs 24(a) - 24(d) respectively, the heating circuits being connected in parallel arrangement with each other.
Triacs 24(a) - 24(d) are conventional thyristors capable of conducting current in either direction irrespective of the voltage polarity across their main terminals when triggered by either a positive or negative voltage applied to the gate terminals.
The power control system 26 controls the power applied to the heating units by controlling the rate at which gate pulses are applied to the triac gate terminals in accordance with power setting selections for each heating unit entered by user actuation of tartile touch membrane switch keyboard 28 comprising touch keys 17 (Fig. 1). The columns of keys designated SU0 through SU3 provide the control inputs for heating units 14(a) - 14(d) respectively.

0`1 ~

PATENT - D-MA-16819 - Payne In the illustrative embodiment gate signals are applied to triacs 24(a) - 24(d) to couple power pulses to the heating units. Each pulse is a full cycle of the 240 ~olt, 60 Hz AC power si~nal; howe~er, power signals of different frequencies and voltaae levels such as 120 volts, 60 Hz or 220 ~olts, 50 H~ could be similarly used.
A plurality o~ discrete power levels are pro~ided, each having uniquely associated with it a particular power pulse repetition rate.
In the illustrati~e embodiment fifteen non-Off power levels are implementable by the control system. ~ine power settings correspond;ng to power levels 1-9, plus Off and Cn are selectable for each heating unit by user actuation of the keys in keyboard 2~. The six hiahest power levels designated A-F are not user selectable. These levels are used to overdrive the heating units when operating in a transient heat up mcde to rapidly heat the units to radiant temperature as will be hereinafter described. Table I shows the pulse repetition rate associated with each power level.

TABLE I

Look Up Table Power Pulse Power Power Repetition 5ettings Level Rate Address Power Pulse Code Watts 0~l 0 - TBLADDR 0000 0000 0000 0000 0 1 1 1/64 TBLADDR +8 8000 0000 0000 0000 60/40 2 2 1/32 TBLADDR +10 8000 0000 8000 0000 120/75 3 3 ~f~ TBL~DDR +18 8000 8000 8000 8000 230/150 4 4 :kf4 l/~ TBLADDR +20 8080 8080 8080 8080 400/275 10/64 TBLADDR +28 8088 8QaO 8088 8080 65Q/425 6 6 15/64 TBLADDR t30 8888 8888 8888 8880 875/fiOO
7 7 21/64 TBLADDR +38 AA88 A888 A888 A888 1225/800 8 8 28/64 TBLADDR +40 AA8A M 8A M 8A AA8A 1650/1100 9 9 36/64 TBLADDR +48 E M A E M A EAAA E M A 2100/14QO
A 41/64 TBLADDR +50 EEEA EAEA EAEA EAEA 2400/1600 B 45/64 TBLADDR +58 EEEE AEEE EAEE EEAE 2650/1750 C 51/64 TBLADDR +60 FEEE EEEE FEEE FEEE 2900/1900 D 55/64 TBLADDR +68 FEFE FEFE FEFE FEEE 3150/2100 E 59/64 TBLADDR +70 FFEF FEFF EFFE FFEF 3400/2250 F 64/64 TBLADDR +78 FFFF FFFF FFFF FFFF 3700/2450 )145 PATE~T - 9D-MA-16819 - Payne The power pulse code in Table I represents 64-bit control words in hexadecimal format. These control words are used to implement the corresponding pulse repetition rates. The basic control period comprises 64 full cycles of the 60 Hz power signal. The distribution of ON power pulses over this 64 cycle control period for each power setting is defined by the bit pattern of the associated control word.
0~ pulses or cycles are represented by logical one bits and Off cycles by logical zero bits respectively. Thé repetition rates for the user selectable power settings have been empirically established to provide a range of power settings for good cooking performance in the appliance of the illustrative embodiment. The bit patterns have been selected to minimize the duration of idle or OFF cycles for each power level.
As shown in Table I, the pulse repetition rate for the first .
four power settings range from 1 ON pulse per 64 power cycles for power setting 1, the 1 ~lest non-Off power setting, to 1 0~1 power pulse for every 8 cycles for power level 4. In Fig. 5 waveforms A-D represent the voltage applied to heating element for each of power settings 1 through 4 respectively. Wave form E represents the power signal appearing across lines Ll and L2. P wer pulses or ON cycles are represented by full lines. Those cycles of the power signal during which the triac is non-conductive are shown in phantom lines.
One aspect of the present invention involves a novel application of the repetition rate power control concept disclosed in commonly assigned U.S. Patent 4,256,951. As mentioned briefly in the Background discussion, significant cost and reliability beneff ts can be enjoyed if the appliance can accommodate heating units designed for operation at an effective or RMS voltage level less than the 240 volt supply leYel. As used hereinafter the phrase "designed for operation at a particular voltage" with reference to a heating unit shall be 1~014~

PATFNr - CD-MA-16819 - Payne understood to mean that the unit is designed to provide the maximum output power and watts density desired for good cooking performance when that particular effective or RMS voltage is applied to the unit.
A reduction of the effective Yoltage for which the unit is designed permits an increase in heating element wire diameter to provide better structural integrity without compromising on the power and watts density specifications essential to good cooking performance.
Heating element wire manufacturers have determined that a less costly, structurally stronger, heating unit which provides the output power and watts density normally associated with the heating element designed to operate at line voltages can be designed for operation at about 75~ of line voltage. h r example, a unit can be designed for operation at 180 volts RMS which provides the output power and watts density normally associated with a unit designed to operate at 240 volts RMS. Similarly, a unit can be designed to operate at 90 volts RM5 and provide the output power and watts density ~ormally associated with a unit designed to operate at 120 volts PMS.
In accordance with the present invention the RMS voltage applied to the heating unit is effectively stepped down from the typical supply line voltage of 240 volts to the voltage level for which the unit is designed by determining the repetition rate which provides in RMS voltage equal to the design voltase and assigning this rate to the maximum user selectable power setting.
Repetition rate control can be used to step down the effective or RMS voltage applied to the heating unit, provided the time base is properly selected, because when power switching is conducted at a switching rate which provides On and Off times which do not exceed the same order of magnitude as the thermal time constant of the wire heating material, the voltage in terms of heating effect or output 30`145 PATENT - 9D-~A-16819 - Payne power is approximately equal to the RM5 value of the supply voltage reduced by a factor equal to the square root of the ratio of the number of On cycles to the total number of cycles in the control period. This relationship is expressed in the equation listed below.

YR~S Vpeak ~ 1/2 X (umber of on cycle Total Cycles in Control Perio The thermal time com tant of heating element wire is on the order of 800 milliseconds, varying slightly with wire radius. ThuS, a control period of 64 cycles is of the same order of nagnitude as the thermal time constant for the heating unit of the illustrative embodiment. U5ing the foregoing equation, a ratio of 36 Gn cycles to 64 total cycles provides an effecff ve PMS voltase of 180 volts for the peak supply voltage of 339 volts associated with the standard 240 volt PMS 60 Hz domestic supply. -AS sh~m in Table I the maximum user selectable power settingin the illustrative e~bodiment is power setting 9. The corresponding power level iS defined by a repetition rate of 36 On cycles per 64 total control period cycl es.
One undesirable consequence of heating units designed to operate at lower voltage levels iS that the increased wire diameter extends the time required to heat the wire to itS visually radiating temperature when operated at the voltage level corresponding to the maximum user selectable power setting. For example, in the illustrative embodiment the time required for the unit designed for operation at 180 volts to reach the visible radiating temperature at power level 9 iS on the order of 30 seconds. For purposes of prompt visual feedback to the user thiS iS undesirably slow. A heat Up time PATENT - 9D-MA-16819 - Payne not significantly greater than 4-6 seconds is preferred. To this end, in accordance with another aspect of the present invention, upon detecting a change in power setting from Off to a non-Off power setting, an overdrive power level higher than the power level associated with the maximum user selectable setting is applied to the unit for a relatively short transient heat up period of time, long enough to bring the heating unit to its radiating temperature quickly but not so long as to subject the unit to excessive thermal stress.
In the illustrative embodiment when the heating element wire is at or near room temperature, the unit can be operated at full line voltage for up to 5 seconds without undue stress on the wire. However, if the unit is turned from Off to On without sufficient time to allow the unit to cool adequately from a previous On period, operation of the unit at full power for the normal 4-5 seconds could, if repeated over a period of time, lead to a premature failure of the unit. To protect against such damage, in accordance with the present invention timing means is provided to measure the Off time, that is the elapsed time since the last occurring OFF setting was selected by the user. The power control system is operative in response to the timing means to vary the duration of the next occurring transient heat up period as a function of Off time so as to establish a shorter heat up period when the elapsed time indicates that the wire has not had adequate time to cool since a previous usage.
In the illustrative embodiment the timing means compares the elapsed time to three successively increasing reference times. The transient heat up period is selectively limited to one of four corresponding predetermined heat up time periods, the selected one of the time periods corresponding to the longest of the reference times to be exceeded. The predetermined reference times are 3 seconds, 14 PATENT - 9D-MA-16819 - Payne seconds, and 60 seconds. If the unit has been turned Off for less than approximately 3 seconds, the overdrive power level is applied for approximately 1 second; if the Off time is greater than 3 but less than 1~ seconds, the overdrive power level is applied for approximately 2 seconds; if the Off time is greater than 14 but not greater than 60 seconds, the overdrive power level is applied for approximately 3 seconds; and finally if the elapsed Off time is greater than 60 seconds, the overdrive power level is applied for approximately 4 seconds.
These specific reference times and heat up periods have been found to provide satisfactory results for the heating units of the illustrative embodiment. It will be appreciated, however, that these values are provided for purposes of illustration and are not to be considered as limitations on the invention.
Gverdriving the heating unit at an overdrive power level corresponding to full line voltage or 100~ power brings the heating unit to its radiating temperature quickly. However, in a multiple unit cooktop such as that of the illustrative embodiment, the maximum current which can be drawn by the appliance at a given time is limited, thereby limiting the total output power available from the heating units. This current limit may be exceeded by applying full line voltage in the heat up mode depending on what power levels are set by the user for the other heating units.
In view of the standard use of 50 amp circuit breakers for the domestic kitchen range power circuit, it is good design practice to limit the current to the cooktop to approximately 35 amps. Assuming supply voltage variations of +10~ and +5~ variation in the resistance of the heating units the extreme case current load is presented by a llO~ voltage variation and a -5~ resistance variation. A maximum l~O~S
PATENT - 9D-MA-16819 - Payne current limit of 35 amps at 264 volts ~240 votts ~lOX) defines a maximum output power limit of 9240 watts for the four un;t cooktop.
In accordance with the present invention means are provided for determining when the total current being drawn by the heating units is greater than a predetermined limit, and for reducing the voltage from full line voltage to a lower voltage level to bring the total current load within acceptable limits.
In a preferred form of the invention the means for detecting excess current computes a sum representing the maximum output power of the appliance for the power levels then being applied to each of the - heating units. When this sum exceeds a predetermined maximum value, power levels are adJusted until the sum is less than the reference. In the illustrative embodiment the implementable repetition rates are represented by the corresponding numerical power level designators.
The power level designators are summed and compared to a reference value representing the power level sum corresponding to the maximum power limit. Output power data for each of the six inch and eight inch units for the cooktop of the illustrative embodiment under both the nominal and extreme tolerance conditions are listed in Table II for the maximum user selectable power settings 8 and 9 and the top three power levels available during operation in the transient heat up mode.
' TABLE II
P~ler 6" Unit 8" Unit Level N~minal Extreme Nominal Extre~e PATENT - 9D-MA-16819 - Payne Using the data from Table II for extreme Yoltage and resistance conditions, with all four units operating at the power level corresponding to the maximum user selectable power level, power level 9, the total combined output power for the two 6" and two 8" units is 8900 watts. This is 340 watts less than the above defined maximum power limit of 924Q watts. As can be seen in Table II, a one power level change, particularly with respect to the top three power levels, corresponds to approximately three to four hundred watts difference in output power for a single heating unit. Thus this 340 watt difference corresponds to a power level change of approximately one power level.
In the illustrative embodiment with all four heating units operating at power level 9 the sum of the power levels is 36. This sum represents the maximum output power value of 8900 watts. An increase of one additional power level for one surface unit would place the total output power at approximately the maximum desirable limit of 9240 watts. Thus a maximum power level sum of 37 would meet the maximum power and corresponding current limit requirements under all possible operating conditions. However, a power level sum of 38 satisfactorily meets the maximum power conditions under all operating conditions reasonably likely to occur. Thus, 38 is employed in the illustrative embodiment as a reference value for the reference maximum sum of power levels for the appliance. No adiustments to the power level applied to any of the heating units is made to limit the current until the sum of the power levels exceeds the total 38.
For example assume one 8" heating unit is operating in the transient heat up mode with the maximum overdrive power level, power level F, being applied and the remaining three heating units are operating at the maximum user selectable power level, power level 9.

PATENT - 9D-MA-16819 - Payne The sum of the power levels in this case is 42 and the total output power is 10980 watts~ Reducing the power level of each heating unit by one level lowers the sum to 38 and lowers the total output power to 9195 watts which is slightly less than the allo~able maximum of 9240 watts.
In order to limit the effect on any one heating unit, the power level for each of the heating units may be lowered to bring the total current within limits. In the illustrative embodiment, in order to further limit the adverse affect on cooking performance for those units not operating in the transient heat up mode, the power level for such units is never reduced by more than one level to comply with the current limits. If reducing the power level for all units by one level is not sufficient, the power level applied to those units operating in the transient heat up mode will be successively reduced one level at a time until the total current as signified by the power level sum is within acceptable limits. The power control system is operative in response to this lowering of the power level being applied during trinsient heat up mode to correspondingly increase the duration of the transient heat up period to compensate for the lower power levels being applied.
Microprocessor Embodiment Fig. 6 schematically illustrates an embodiment of a power control circuit for the cooktop of Fig. 1 which performs power control functions in accordance with the present invention. In this control system power control is provided electronically by microprocessor 40.
Microprocessor 40 is a M68000 series microprocessor of the type commercially available from Motorola/. Microprocessor 40 has been customized by permanently configuring its read only memory to implement the control scheme of the present invention.

14~
PATENT - 9D-MA-16819 - Payne As previously described with reference to Fig. 4, keyboard 28 is a conventional tactile touch type entry system. The keyboard array comprises four columns of 11 keys each. Columns for controlling heating elements are designated SUO through SU8 respectively. The keys enable a user to select power levels 1 through 9 in addition to ~n and Off for each of the four heating units. Keyboard 2~ has one input line for each column commonly shared by all keys in that column and 11 output lines, one for each row of keys. Each particular column of keyboard 28 is scanned by periodically generating scan pulses sequentially at outputs P400 through P403 of microprocessor 40. These pulses are transmitted as they appear to the corresponding column input lines of keyboard 28. This voltage is transmitted essentially unchanged to the output lines of all the untouched keys. The output of an actuated key will differ, signifying actuation of the key in that row and column.
In this manner each column of keyboard 28 is scanned for a new input periodically at a rate determined by the control program stored in the ROM of microprocessor 40. As will become apparent from the description of the control routines which follow, each column is scanned once every four complete power cycles of the power signal appearing on lines Ll and N. The output from keyboard 28 is coupled to input ports PlIO-PlIA of microprocessor 40 via a 410 parallel port interface circuit.
A zero crossing signal marking zero crossings of the power signal appearing on lines Ll and N from the power supply is input to microprocessor 40 at input port P8IO from a conventional zero crossing detector circuit 44. The zero crossing signal from circuit 44 is illustrated as wave form F of Fig. 5. The pulses mark the position going zero crossings of the power signal across lines Ll and N of the ~Oli~

PATENT - 9D-MA-l68l9 - Payne AC power supply. The zero crossing signals are used to synchronize thetriggering of the triacs with zero crossings of the power signal and for timing purposes in the control program executed by microprocessor 40.
Microprocessor 40 transmits triac trigger signals from I/O
ports P500 through P~03 to the gate terminals of triacs 241a) ^ 2 (d) respectively via a conventional 615 triac driver circuit. Triac driver circuit 64 amplifies the outputs from ports P500-P503 of microprocessor 40 and isolates the chip from the power line. Display data is transmitted from I/C ports P200-P20F. Display 58 is a conventional four digit display, each digit comprising a 7-segment LED display.
Display information is coupled from I/O ports P200-P20F to the display segments via a conventional 410 parallet port interface circuit 60 and a conventional segment display decoder driver circuit 62 in a manner well known ln the art.
Control Program It will be recalled that microprocessor 40 is customized to perform the controt functions of this invention by permanently configuring the ROM to i~plement a predetermined set of instructions.
Figs. 7-13 are flow diagrams which illustrate the control routines implemented in microprocessor 40 to obtain, store and process the input data from the keyboard and generate control signals for triggering the triacs in a manner which provides the power pulse repetition rate required to apply appropriate power levels to each of the heating un;ts. From these diagrams one of ordinary skill in the programming art could prepare a set of instructions for permanent storage in the ROM of microprocessor 40 which would enable the microprocessor to perform the control functions in accordance with this invention.

PATENT - g~-MA-16819 - Payne The control program comprises a set of predetermined control instructions stored in the read only memory (RoM) of microprocessor 40. A separate file in the random access memory (RAM) of the microprocessor is associated with each of heating units l~a) - 14(d).
Each file stores the control inforration for its associated heating unit ~ich is acted upon by the instructions in the ROM. Execution of the control program is synchronized with the 60 Hz power signal such that the set of control instructions in the ROM is cycled through once during each cycle of the power signal. A file register common to all four files functioning as a four count ring counter is incremented once during each pass through the control program. The count of this file reaieter identifies the RAM file to be operated on by the contrDl instructions during the ensuing pass through the control program. By this arrangement the control program is executed for any one particular heating unit once every four cycles of the 60 Hz power signal.
The control program is logicall~ divided into a set of sub-routines which includes the Scan routine, the Keyboard Decode routine, the Off Timer routine, the Instant On routine, the PSET
routine, the Power Out routine, and the PwrSum routine. It will be appreciated that other sub-routines may also be included to perform control functions unrelated to the present invention.
The Scan routine lFig. 7), which contains the file register identifying the RAM file to be acted upon during the ensuing pass through the control program, sets the scan line for the keyboard column associated with the heating unit which is the subject of the current pass through the routine, reads the input from the keyboard for that heating unit, and stores the user selected power setting selection information in temporary memory. The Keyboard Cecode routine lFigs. 8A
and 8B) validates keyboard entries and updates the control variable 0~ ~5 PATENT - 9D-MA-16819 - Payne representing the po~er level selected by the user as appropriate to reflect the most recent valid user input for that heating unit. The Off Timer routine (Fig. 9) determines the time elapsed since that heating unit was last turned Off. This information is used in the Instant On routine (Figs. lOA and 10~) to vary the duratSon of the transient heat up period during which the unit is overdriven as a function of how long the unit has been Off in accordance with the present invention.
While the determination of what power level to be applied to a heating unit is determined only during execution of the control program for that particular heating unit, a power control decision must be made for the ensuing power cycle for each of the units during each pass through the program. The PSET routine (Fig. 11) obtains power level information from each file during each pass through the routine, - performs a table look-up for each heating unit to check the appropriate bit for the power level control word for each heating unit, and generates a four bit trigger control word which identifies which heating units are to be triggered on and which are to be off during the next power cycle. This four bit control word is then used by the Power Out routine (Fig. 12) which monitors the input from the zero crossing circuit and triggers those triacs associated with heating units to be energized during the next power cycle into conduction upon detection of the next occurring positive going zero crossing of the power signal.
The PWRSUM routine (Fig. 13) monitors the power level being applied to each of the four heat;ng units and reduces power ievels as necessary to limit the total current drawn by the appliance to within acceptable limits. Each of these control r w tines will now be described in greater detail with reference to its flow diagram in the discussion to follow.

S
PATENT - 9D-MA-16819 - Payne SCAN Routine - FiG. 7 The function of this routine is to address the appropriate RAM
file for the current pass through the program, set the appropriate scan line for the keyboard, and read in the input information from the keyboard for the heating unit associated with the designated R~M file.
RAM file register SU functions as a four count ring counter which counts from O to 3. Counts O through 3 of the SU counter identify R~l files for surface units 14(a)-14(d) respectively.
Upon entering the Scan routine the register SU is incremented (Block 102) and Inquiry 104 determines if SU is greater than 3. If so, the counter is reset to O (Block 106). Next the address of the R~l file to be acted upon during this pass through the control program is set equal to SU (Block 108). The scan iine set during the previous pass through the control program designated R(SU-l) is reset IBlock 110). The scan line associated with the surface unit for the current pass through the program designated R(S O is set (Block 112). The data of input lines PlIA through 9 are read in, conveying the current input information for this RAM file from keyboard 28 (Block 114) and this information is stored as variable KB (Btock 116). The program then branches (Block 118) to the Keyboard Decode routine oi Fig. 8A.
KEYBOARD DECQDE Routine - FIGS. 8A and 8B
The Keyboard Decode routine validates inputs from keyboard 28 and updates the user selected power setting variable PWD accordingly.
The routine ff rst determines if the new keyboard entry is a blank signifying no input, an Off entry, an On entry, or one of the power levels 1 through 9. To be valid when switching the heating unit from Off to another power setting, the Qn key must be actuated first followed by the desired power setting. The power setting must be entered within 8 seconds of actuation of the On key. If not, the On key must be re-actuated.

0`~
PA~ENT- 9D-MA-16819 - Payne The varia~le P~D represents the user selected power setting.
P~D is only changed in response to user inputs. However, in accordance with the present invention the power level actually applied to the heating unit may be less than the level corresponding to the user selected power setting. The variable PLYL is introduced in this routine to represent the power level to be actually applied to the heating unit. PLYL is assigned the value of PWD in this sub-routine.
However, PLVL is subiect to be changed in the temperature limiting routines hereinafter described.
In the Keyboard Decode routine the eight second period for entering a valid power setting after actuition of the Qn key is established using a flag designated the On flag and a timer or counter designated the ONTIMER. The Gn flag is set when the On key is actuated and is only reset in response to actuation of the Off key or timing out of ON~IMER.
Referring to the flow diagram of Figs. 8A and 8B, Inquiry 120 first determines if the K8 represents a blank signifying that no key is presently actuated. If KB is blank, the system branches to the Decode 2 sub-routine (Fig. gB). In the Decode 2 sub-routine Inquiry 122 determines if the On flag is set. If the On flag is not set, the power level stored in PWD is assigned to the variable PLVL (Block 124). If the Qn flag is set, Inquiry 126 determines if the previously selected power setting presently stored as PWD is the Qff settin~. If not, the system is presently operating at one of power settings 1 through 9 and the program proceeds to ass;gn the value of P~ID to PLYL (Block 124) and branches (Block 128) to the Off Time routine (Fig. 9). If Inquiry 126 determines that PWD equals O representing an Off power le~lel, this indicates that the user has switched from Off to Qn and the On timer is decremented (Block 130). When On timer equals O as determined at 1~80~

PATENT - 9D-MA-16819 - Payne Inquiry 132 signifying that the time to enter a valid power level has expired, the On flag is cleared (Block 134) and program proceeds to Block 124 as before.
Referring again to Fig. 8A, if KB is not a blank, Inquiry l35 determines if the new entry is the Off setting. If so, the On flag is cleared (Block 136) and the ~ariable PWD is assigned the Yalue O
representing the Off power setting (Block 138). The variable PLYL is assigned the value of PWD (Slock 140) and the program branches (Block 142) to the Off Timer routine of Fig. 9. If KB is not Off, Inquiry 144 determines if the new entry is the On setting. If it is, the On timer is re-initialized (Block 146). Inquiry 148 checks the state of the Cn flag. If set, the program proceeds to Block 140. If not set, the flag is set (Block 150) and the PWD is assicned the value O which corresponds also to the On setting (Block 152). The program then proceeds to Block 140 as before.
If the answer to Inquiry 144 is No, signifying that the new entry is one of power levels 1 through 9, Inquiry 154 checks the state of the On flag. If it is not set, signifying the user has attempted to go from Off to a power level without first actuating the On key, the new entry is ignored and the program proceeds to Block 140 wlth PWD
unchanged. If the On flag is set, the power setting input is valid, and variable PWD is assigned the new value corresponding to the new entry KB (Block 156).
Having assigned the value of PWD representing the most recent valid user selected power setting to the variable PLVL the system proceeds to the Off Timer routine (Fig. 9).
OFF TnMER Routine - FIG. 9 The function of this routine is to measure the time elapsed since the particular unit was last turned off to establish the ~01~

PATENT - 9~-MA-16819 - Payne appropriate duration of the next occurring transient heat up period for that heating unit. A timer designated OFFTMR is provided for each heating unit. The timer is incremented by one each pass through the rouff ne for that particular heating unit. The duration of the transient heat up period for the next occurring transient heat up period is defined by the value of the variable INSTIME. This variable is successively set equal to values of 1.07 seconds, 2.13 seconds, 3.07 seconds and 4.26 seconds as the count of the Off timer goes from less than 3 seconds to greater than 3 seconds, from greater than 3 to greater than 14 seconds, and from greater than 14 seconds to greater than 60 secondsj respectively.
Referring to the flow diagram of Fig. 9, on entering this routine the state of the On flag is checked at Inquiry 160. It will be recalled that the Qn flag is set in the Keyboard ~ecode routine hereinbefore described during the first pass through that routine following the user selection of the On key. It then remains set until the next occurring user actuation of the Off key. Thus, if the On flag is set, the system is already operating in the transient heat up mode or has completed the transient heat up mode and the value for INSTIME
has already been established. Thus, when the On flag is set no adjustment to INSTIME is needed and the program branches to the Instant On routine (Block 162) of Fig. lOA. If the On flag is not set, the count of the timer (OFFTMR) is compared to a maximum count of 61 seconds at Inquiry 164. If the count is greater than 61, the program branches (Block 162) to the Instant On routine of Fig. lOA. If the count represents a time that is not greater than 61 seconds, the counter is incremented by one (Block 166).
The timer is then compared to maximum reference time of 60 seconds at Inquiry 168. If the count represents a time greater than 60 PATENT - 9D-MA-16819 - P4yne seconds, the variable INSTDME is set equal to 4.26 seconds ~Block 17C) and the program branches to the Instant On routine. If OFFTMR is not greater than 60 seconds, the count i5 compared to a reference of 14 seconds at Inquiry 172. If greater than 14 seconds, the Instant Gn time variable INSTDME is set equal to 3.07 seconds (Block 174) and the program branches to the Instant On routine. If the count is not greater than 14 seconds, the count is compared to a reference of 3 seconds at Inquiry 176. If greater than 3 seconds, INSTIME is set equal to 2.13 seconds. If the count is not greater than 3 seconds, Instant On time variable INSTIME is set equal to t.O7 seconds (Block 180). Having established the correct reference value for the duration of the transient heat up period as a function of the Off time, the program branches to the Instant On routine of Figs. lOA and lOB.
INSTANT ON Routine - FIGS. lOA and lOB
The function of the Instant On routine is to establish the appropriate overdrive power level when operating in the transient heat up mode; to control the duration of this mode; and to make adjustments to the power level when not operiting in this mode as required to limit the total current drawn by the appliance.
It will be recalled that under certain conditions the sum of the power levels may exceed the predetermined limits signifying that the appliance is drawing too much current this determination is made in the PWRSUM routine hereinafter described with reference to Flg. 13.
latch designated PWRSUML, is set in that routine when the sum of the p~wer levels is greater than a reference value. When PWRSUML is set, power level adJustments are made in this routine durjng each ensuing pass through the control program for each heating unit until the sum of the power levels is no longer greater than the reference.

0`1~

PATENT^ 9D-MA-16819 - Payne Additionally, a variable designated OPR is used to make adJustments in power level to be applied to heating units in the transient heat Up mode and to vary the duration of this mode. More specifically when the transient heat up power level i5 reduced in order to meet the current limit requirements, the duration of the transient heat up period is correspondingly extended. The value of OPR is established in the PWRSI~ routine but it is used in this routine to make the appropriate power level and time adiustments for units operating in the Instant On routine.
Referring now to Figs. lOA and lOB, on entering this routine the state of the Instant Cn flag is checked at inquiry 182. If it is not set, signifying the unit for which the change is being executed is not operating in the transient heat up mode, the state of the power sum latch (PWRSlltL) is checked at inquiry 184. If PWRSU~L is set, signifying a need to adjust the power level to meet current limitation requirements the power level is reduced by one (Block 186) and the program branches to the next routine. If PWP5UML is not set no adjustments are made and the program continues on to the next routine.
Referring back to Inquiry 182, if Instant On flag is set signifying operation in the Instant On mode, the power level variable PLVL is set equal to the maximum power level F, reduced as required by the value of the adjustment variable OPR (Block 190). Inquiry 192 and Block 194 cooperate to prevent the applied power level during Instant On from being less than 9 and Inquiry 196 and Block 198 cooperate to keep PLYL not greater than F. The program then proceeds to inquiries 202-208 which operate in combination with 810cks 210-218 to vary the duration of the transient heat up mode as a function of the value of the OPR variable. A counter designated OVDRIMR is used to control the duration of the transient heat up mode. When OPR is not greater than 1~0~45 PATENT - 9D-MA-16819 - Payne 1, OYDRTMR is incremented by one, each pass through the routine (Block 210). If OPR is greater than one but not greater than three, Inquiries 204 and 206 and Blocks 212 and 214 cooperate to increment OVDRTMR on alternate passes through the routine for a particular heating unit, effectively reducing the increment rate by two thereby extending the duration of the Instant Cn period by a factor of two. If OPR i5 greater than three, Inquiry 208 and Blocks 216 and 218 cooperate to increment OVDRTMR by one on every fourth pass through this routine for this particular heating unit effectively extending the transient heat up mode by a factor of four.
Thus, the variable OPR serves as here before described to reduce the power level applied during operation of the transient heat up mode at block 190 and also is used to compensate for the lower power level by extending the duration by causing the duration of operation in the instant on mode to be extended to compensate for this lower power setting.
At Inquiry 220 the value of OVDRTMR is compared to the reference value INSTIME established in the hereinbefore described Off Timer routine of Fig. 9. When Inquiry 220 determines that OVDRTMR has timed out, the Instant Cn flag is cleared, OVDRTMR is reset to zero, and the reference variable INSTIME is set to zero.
PSET Routine - FIE. 11 Having established the appropriate power level to be applied to the heating unit, it remains to make the triac triggering decision for the next occurring power signal cycle. This decision is made for all four heating units during each pass through the control program.
Use is made in this routine of information from each of the four heating unit RAM files each time through the routine.

01~
PATENT - 9D-MA-168t9 - Payne It will be recalled that the power pulse repetition rate for each power level is defined by the bit pattern of a 64 bit word with the logical one bit representing an On cycle and logical zero representing an Off cycle. The bits of the control word for each heating unit representing the power level to be applied to it are tested sequentially with one bit being tested each pass through this routine. The state of that tested bit determines whether the triac for the corresponding heating unit will be triggered on or not in the next power signal cycle.
This routine performs a Table Look-Up function to find the appropriate control word for each of the four surface units and then checks the state of the appropriate bit in that word. The triac triggering information is then stored in a four-bit word designated TMPON, which is used in the Power Cut routine (Fig. 12) to generate the appropriate triac trigger signals.
The variable lBLADD represents the address in RA~ of the starting location for the look-up table containing the 64 bit control words. The address and associated bit pattern in Hex representation is shown in Table I. Each of the 16 diaits in the code as shown for each control word is the hexidecimal representation of four binary bits.
The variable designated BITADD represents the location within the 64 bit control word of the bit to be tested with O and 63 corresponding to the location of the most significant bit and least significant bit respectively.
An indexing variable n is used to iterate the table look-up loop four times during each pass through the routine, once for each heating unit. The variable PWDADD is the address of the control word representing the power level to be applied to the nth heating unit.
As can be seen in Table I, the address for any particular power word is 1 '~<8Q ~5 PATENT - 9D-MA-16819 - Payne obtained by multiplying the value of PL~L for its associated power level, which is a number O through 9, by a factor of 8 and adding this to TBLADD.
Referring to Fig. 11. on entering this routine the control word lMPON i5 cleared (810ck 226) and a ring counter which counts from O to 63 is incremented (Block 228). Inquiry 230 determines if the counter is greater than its maximum count of 63. If so, it is reset to O (Block 232). Next BITADD is set equal to the count of the ring counter thereby defining the location within the control word for the bit to be tested for each heating unit (Block 234). The same bit location is tested for each of the heating units.
The variable n is initialized to zero at Block 236. PWDPDD
for the power level to be applied to the nth heating unit is deter0ined at Block 240. The state of the bit location defined by the variable BITADD in the control word located at the address PWDADD is then tested (Inquiry 242). If the tested bit is a logical 1, the nth bit of the control word TMPON is set (Block 244). Othen~ise, the nth bit of ~MPON will remain 0. After the index n is incremented (Block 246) the value of n is checked (Inquiry 248). If greater than 3, signifying that the loop comprising Blocks 240, 244 and 246 and Inquiries 242 and 248 has been iterated four times, n is reset (Block 250) and the program branches (Block 252) to the Power Qut routine (Fig. 12). If n is not greater than 3, the program returns to Block 284 to test the bit for the power word for the next heating unit.
After the appropriate state for all four bits of the variable TMPON
have been established, the program branches (Block 252) to the Power Out routine (Fig. 12).
POWER OUT Routine - FIG. 12 The function of this routine is to trigger triacs 24(a) -24(d) to implement the triac triggering decision for the next power ~8~1~5 PATENT - 9D-MA-16819 - Payne cycle for each of the four heating units. The triggering of the triacs is synchronized with the positive going zero crossings of the power signal.
Referring now to the routine in Fig. 12, on entering this routine the output latches P500-P503, which control the triacs, are reset (Block 260). Next the program reads in the input from the input port P8IO representing the state of the zero cross detector (Block 262) and Inquiry 264 checks the state of this input until it switches to a logical 1 signifying the occurrence of a positive going zero cross;ng of the power signal. When P8IO equals 1, the program proceeds to Inquiry 266 to sequentially check the four bits of the power word TMPON
and set the appropriate one of output latches P500-P503. Index variable n is again used to sequentially check bits O through 3. It will be recalled that prior to branching from the PSET routine the n is reset to 0. Inquiry 266 tests the nth bit for a 1. If it is a 1, the output P50(n) is set (Block 268), n is incremented (Block 270) and Inquiry 272 checks for an n greater than 3. If n is less than 3, the program returns to Inquiry 266 to check the next bit and set the corresponding output port as appropriate. Those ones of output latches P500-P503 associated with bits in the variable TMPON which are in the logical one state are set. Those ones with output latches associated with zero bits in TMPON are not set. In the latter case these latches remain in the reset state since each of the latches is reset upon entering this routine.
In this fashion each bit of the control word lMPON is tested each pass through the Power Out routine. In this way a decision to trigger or not trigger each triac is carried out during each pass through the control program. Once the loop comprising Inquiries 206 and 272 and Blocks 268 and 270 is iterated four times, once for each 1 ~.80~4~

PATE~T - 9D-MA-16819 - Payne heating unit, the power control decision for the next power cycle has been implemented and the program branches (Block 274) to the PWRSUM
Routine of Fig 13.
PWRSUM Routine - FIG. 13 The function of this routine is to monitor the power levels being applied to each of the heating units and set or reset the latch designated the PWRSUML and update as appropriate the variable OPR It will be recalled that the PWRSUML and the OPR variable are utilized in the Instant Qn routine to modify the power level being applied to each heating unit as appropriate to bring the total current drawn by the appliance to within acceptible limits. The variable P~RSW~ is set equal to the numerical sum of the power level designator for each of the heating units. If this sum is greater than 38, the total current drawn by the appliance will exceed the maximum 35 amp design limit.
Thus, if the sum exceeds the reference value of 38, the PWRSUML is set and the variable OPR is ~ncreased by one. If the sum of the power levels is not greater than this reference, the PWRSUML is reset and the OPR variable is decremented by one.
Referring to the flow diagram of Fig. 13, on entering the program the variable PWRSUM is set equal to the sum of the power levels (Block 280). This variable is compared to the reference value which is expressed in hexadecimal representation (In hexadecimal the hexadecimal value 26 corresponds to a decimal value of 38.) at Inquiry 282. If PWRSUM exceeds the reference value, PWRSUML is set (Block 284) and the variable QPR is incremented by one (Block 286). If PWRS~l does not exceed the reference, PWRSUML is reset (Block 290). If OPR is less than or equal to O at Inquiry 292, the variable is set equal to O
(Block 296). If OPR is not less than 0, it is decremented by one (Block 294). Having established the apprcpriate state for PWRS~lL and 1~8~) ~45 PATENT - gD-MA-16819 - Payne the appropriate value for the variable OPR, the program then returns (Block 288) to the Scan rout;ne of Fig. 7 to repeat the control program for the next heat;ng unit.
~ hile in accordance with the Patent Statutes a specific e~bodiment of the present invent;on has been illustrated and described herein, it is realized that numerous modifications and changes will occur to those skilled in the art. For example, the illustrative embodiment employs infrared heating units. However, the invention could also be used in conventional conduction cooktops as well. It is therefore to be understood that the appended claims are intended to cover all such modifications and changes as fall within the true spirit and scope of the invention.

Claims (12)

1. An electric cooking appliance adapted for energization by a standard domestic household power supply characterized by an output power signal with a predetermined RMS voltage, said cooking appliance comprising:
at least one electric resistive heating unit designed for steady state energization at a maximum RMS
voltage level less than the RMS voltage level of the output power signal of the external power supply;
user actuable input selection means enabling the user to select one of a plurality of power settings including an OFF setting for said heating unit;
power control means responsive to said input selection means operative to couple power pulses of predetermined fixed duration from said external power supply to said heating unit at one of a plurality of power pulse repetition rates, each repetition rate establishing a corresponding RMS voltage level for application to said heating unit, each user selectable power setting having associated with it a corresponding one of said plurality of power pulses repetition rates;
the repetition rate associated with the maximum user selectable power setting effectively applying an RMS
voltage level to said heating unit corresponding to the RMS voltage level for which said heating unit is designed, whereby the RMS voltage applied by said heating unit when operating at the power level associated with the maximum user selected power setting is less than the RMS voltage level of the output power signal from the power supply; and timing means for measuring the elapsed time since the last occurring user selection of said OFF
setting for said heating unit; said power control means further comprising means for detecting the transition from an OFF power setting to one of said non-OFF power settings said power control means being operative to apply an RMS voltage level equal to the RMS voltage level of the power signal from the power supply to said heating unit for a transient heat up period, upon detection of a transition from said OFF setting to a non-OFF power setting, the duration of said transient heat up period being controlled as a function of said elapsed time.
2. The cooking appliance of claim 1 wherein said power control means is operative to limit the duration of said transient heat up period to a first predetermined period if said elapsed time is less than a predetermined minimum time sufficient to permit said heating unit to cool to near ambient temperature and to otherwise limit the duration of said heat up period to a period greater than said first predetermined period.
3. A heating apparatus comprising:
at least one electric resistive heating unit adapted for energization by an external standard domestic AC power supply having a predetermined RMS
output voltage;
user actuable input means for enabling the user to select from a plurality of predetermined power settings for said heating unit;
control means responsive to said user actuable input means, for controlling the output power of said heating unit;
switch means responsive to said control means for selectively coupling said heating unit to the external power supply;

Claim 3 continued:
said control means being operative to selectively switch said switch means at one of a plurality of switching rates to apply power pulses from said power supply to said heating unit, each pulse comprising one cycle of the AC power signal from the external power supply, each switching rate defining a power pulse repetition rate effective to apply a corresponding RMS voltage level to said heating unit;
each of said user selectable power settings having associated with it a corresponding one of said switching rates, the maximum user selectable power setting having a corresponding switching rate which defines an RMS
voltage level less than the RMS output voltage whereby the heating unit can be designed to operate at an RMS
voltage less than the RMS output voltage of the external power supply;
said control means further comprising means for detecting the transition from an OFF power setting to a non-OFF power setting and wherein said control means is operative to effectuate a power pulse repetition rate corresponding to an overdrive RMS
voltage level higher than that corresponding to the maximum user selectable power setting for a transient heat up period to rapidly heat the unit to its radiant temperature thereby providing visual indicator to the user that said heating unit has been turned on; means for measuring the elapsed time since the entry of the last occurring OFF setting by the user; and means for controlling the duration of the transient heat up period as a function of said elapsed time, to prevent over-heating a heating unit pre-heated from a previous use.
4. The heating apparatus of claim 3 wherein the overdrive RMS voltage level applied to said heating unit during the transient heat up period equals the RMS
output supply voltage.
5. The heating apparatus of claim 3 wherein said means for limiting the duration of the transient heat up period comprises means for comparing said elapsed time to a predetermined reference time and means for controlling the duration of the transient heat up period to a first predetermined time if the elapsed time is less than said reference time and to a second predetermined time greater than said first predetermined time otherwise.
6. The heating apparatus of claim 3 wherein said means for limiting the duration of the transient heat up period comprises means for comparing said elapsed time to a plurality of successively increasing reference times and means for selectively limiting the duration of the transient heat up period to a corresponding plurality of successively increasing predetermined time periods, the selected one of said time periods corresponding to the longest one of said references to be exceeded.
7. An electric cooking appliance adapted for energization by a standard AC domestic household power supply having an output power signal characterized by a predetermined RMS voltage level, said cooking appliance comprising:
a plurality of electric resistive heating units designed by steady state energization at a maximum RMS voltage level less than the RMS voltage level of the power signal from a standard domestic household power supply;
user actuable input selection means for enabling the user to select one of a plurality of Claim 7 continued:
available power settings including an OFF setting for each of said heat units;
power control means responsive to said user actuable input means for independently controlling the output power of each of said heating units;
switch means associated with each of said heating units and responsive to said control means; each of said switch means being operative to selectively couple its associated heating unit to the external power supply;
said control means being operative to selectively switch each of said switch means at one of a plurality of switching rates, each rate defining a corresponding predetermined RMS voltage level to be applied to the associated one of said heating units;
each of said user selectable power settings having associated with it a corresponding one of said switching rates, the maximum user selectable power setting having a corresponding switching rate which establishes an effective RMS voltage level less than the RMS level of the power signal from the power supply, whereby each of said heating units can be designed to operate at an effective steady state RMS voltage less than the RMS
level of the power signal from the power supply;
said control means further comprising means for detecting the transition from an OFF power setting to a non-OFF power setting and said control means being operative to effectuate a switching rate which establishes an overdrive RMS voltage level higher than that corresponding to the maximum user selectable power setting for a transient heat up period to rapidly heat the unit to its radiant temperature thereby providing visual indicator to the user that said heating unit has been turned ON;

said power control means further comprising means for determining when the total current drawn by said heat units is greater than a predetermined limit and means for reducing the effective voltage level applied to each of said heating units to reduce the total current to within acceptable limits.
8. A cooking appliance in accordance with claim 7 wherein each of said repetition rates is assigned a numerical designator; and wherein said means for determining when the total current exceeds a predetermined limit comprises means for computing the sum of the numerical designators corresponding to the pulse repetition rates being applied to each heating unit and comparing said sum to a predetermined reference representative of the maximum acceptable total current for said heating units, and wherein said control means is operative to lower the repetition rates applied to each of said heating units until said sum is less than the said reference value.
9. The cooking appliance of claim 8 wherein said power control means further comprises means for extending the duration of the transient heat up period for a heating unit operating in the transient heat up mode when said control means lowers the repetition rate applied to said heating unit operating in the transient heat up mode to compensate for the reduction in applied voltage level corresponding to the change in repetition rate.
10. An electric cooking appliance adapted for energization by a standard AC domestic household power supply having an output power signal characterized by a predetermined RMS voltage level, said cooking appliance comprising:
a plurality of electric resistive heating units designed for steady state energization at a maximum RMS voltage level less than the RMS voltage level of the output power signal from the external power supply;
user actuable input selection means enabling the user to select one of a plurality of power settings including an OFF setting for each of said heating units;
power control means responsive to said user actuable input means for independently controlling the output power of each of said heating units;
switch means associated with each of said heating units and responsive to said control means; each of said switch means being operative to selectively couple its associated heating unit to the external power supply;
said control means being operative to selectively switch each of said switch means at one of a plurality of switching rates, each rate defining a corresponding RMS voltage level to be applied to the associated one of said heating units; each of said user selectable power settings having associated with it a corresponding one of said switching rates, the maximum user selectable power setting having a corresponding switching rate which defines an RMS voltage level less than the RMS level of the power signal from the power supply;
said power control means further comprising means for determining when the total current drawn by said heating units is greater than a predetermined limit and means for reducing the effective voltage level applied to each of said heating units to reduce the total current to within acceptable limits.
11. A cooking appliance in accordance with claim 10 wherein each of said switch rates is assigned a numerical designator; and wherein said means for determining when the total current exceeds a predetermined limit comprises means for computing the sum of the numerical designators corresponding to the switching rates being applied to each heating unit and comparing said sum to a predetermined reference representative of the maximum acceptable total current for said heating units, and wherein said control means is operative to lower the switching rates applied to each of said heating units until said sum is less than the said reference value.
12. The cooking appliance of claim 10 wherein said power control means further comprises means for detecting the transition from an OFF power setting to a non-OFF power setting and wherein said control means is operative to effectuate a switching rate corresponding to an overdrive RMS voltage level higher than that corresponding to the maximum user selectable power setting for a transient heat up period to rapidly heat the unit to its radiant temperature thereby providing visual indicator to the user that said heating unit has been turned ON, and means for extending the duration of the transient heat up period for a heating unit operating in the transient heat up mode when said control means lowers the switching rate applied to said heating unit operating in the transient heat up mode to compensate for the reduction in applied voltage level corresponding to the reduction in switching rate.
CA000559188A 1988-02-18 1988-02-18 Cooktop appliance with improved power control Expired - Fee Related CA1280145C (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CA000559188A CA1280145C (en) 1988-02-18 1988-02-18 Cooktop appliance with improved power control

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CA000559188A CA1280145C (en) 1988-02-18 1988-02-18 Cooktop appliance with improved power control

Publications (1)

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CA1280145C true CA1280145C (en) 1991-02-12

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CA000559188A Expired - Fee Related CA1280145C (en) 1988-02-18 1988-02-18 Cooktop appliance with improved power control

Country Status (1)

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CA (1) CA1280145C (en)

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