ES2279950T3 - INDUCTION KITCHEN PLATE. - Google Patents

Abstract

An induction cooking system including a power inverter (10), a microprocessor (18), a protection circuit (15) and a pan detection circuit (17) is provided. The power control, timing and a monitoring of the power inverter circuitry (10) is managed primarily by a microprocessor (18). Also an additional analog protection circuit (15) is provided to protect the system against hazardous conditions, such as over current and inappropriate gating signals that may be resulted by the malfunction of the microprocessor (18). So that main disadvantage of a system controlled primarily by a microprocessor is eliminated. Another circuit (17) for detection the presence of the suitable cookware is provided.

Description

Induction cooktop

Technical field

This invention relates to a system of induction heating, more particularly to a kitchen induction for use as an appliance.

Background of the invention

The kitchen devices or hobs of Induction are more reliable and effective, have no flame and therefore They are safer appliances compared to other types of kitchens. High current is generated in the induction cooktops frequency in the heating coil that is usually coupled with a resonant capacitor. The coil current of heating generates a high frequency magnetic flux that gives place to an electromagnetic induction action that generates stray currents in a kitchen utensil, removable or not removable (saucepan, pan, etc.), made of a magnetic material such as steel, iron, etc. As a result of these currents parasites, the kitchen utensil and the food contained therein, are They heat up.

Since the invention is related to a appliance, it should not emit noise to the line of AC power, must work with a factor of unit power and must be provided with protections against dangerous conditions such as non-existence of cargo, overcurrents, overvoltages or overheating. Other important aspect of such devices is the reduction of the cost of The whole system.

The circuitry of the kitchen plates of induction has, fundamentally, two parts: a first consisting of a power stage that generates energy to cooking, and a second, consisting of a control circuit of power, timing and monitoring, which operates at system and that provides convenient control for the Username.

Induction cooktops are used Two types of main power stages: an inverter with a only transistor and a half bridge inverter. The investor with a single transistor is a low cost power stage with a single transistor that facilitates the control. On the other hand, the plates of kitchen with half bridge inverter have two transistors and their cost is greater than those of investors with only one transistor. In return, they can work with more power margins wide and with higher frequencies, which may allow the hot appliance even low strength magnetic materials, such as aluminum.

Several solutions have been developed for incorporate into practice the control circuitry of a system Induction cooker Some of them are based solely on the analog circuitry for control operations of the power, monitoring and timing, for example, such as described in U.S. Patent No. 4429205. The main disadvantages of analog systems are that they cannot be easily modified to change its characteristics operation, that the resolution of the problems they present such systems can be difficult and they are less stable and robust compared to digital systems. Other solutions are based on analog and digital circuits, such as the one described in US 5648008. This system uses circuitry analog only to monitor and activate the power inverter, but this does not turn out to be more advantageous than systems totally digital, since the control of the power or the adaptation of the activation system for systems with multiple coils, result be very difficult In addition, this system interrupts operation of the cooktop in selected cycles of the line of current, which causes the problem known as "flicker".

They are also known in the prior art. induction systems based only on circuits digital US 4,511,781 describes a system that employs a microprocessor for all control actions, but that try to manage all the critical and fast operations of Microprocessor timing. Therefore, a Extremely fast and expensive microprocessor. Consequently, the cost of the system increases and it turns out to be less feasible.

Furthermore, in the prior art it is claimed that The microprocessors are sensitive to line fluctuations of current, which can cause outputs and program errors random. Thus, it is not advisable to rely solely on the microprocessor to activate discriminated pass signals from the power stage But, in this invention, with the help of circuitry additional could prevent the power stage from resulting damaged. No prior invention is known in the prior art. carry out all control actions through a microprocessor, which is stable and robust and has a cost Competitively low compared to other systems.

Many attempts have been made to detect the presence of a suitable kitchen utensil on the plate kitchen. Some of those inventions have made use of observers additional or special equipment to detect the presence of kitchen utensil or its dimensions. Some of them only they use techniques to monitor various signals from investors of power for load compensation.

Summary of the invention

The main objects of the present invention are provide a working induction heating stove with a unit power factor, which does not generate audible noise during operation, which can continuously detect the load variations and that can work in a wide range of powers, can control the temperature of the kitchen utensil and automatically protect against dangerous conditions, such as situations of over-intensity and false discriminated pass signals.

The induction cooker of this invention comprises a power stage constituted by a circuit almost resonant inverter with a single transistor (bipolar transistor with isolated control electrode, IGBT). According to the series of the impulses of discriminated passage, the transistor is put in driving and driving off continuously. As a result of these impulses, a high frequency current is generated in the heating coil and resonant condenser. The current in The heating coil generates a high magnetic flux frequency that gives rise to an electromagnetic induction action which generates parasitic currents in a kitchen utensil, removable or non-removable, located on the hob and Made of a magnetic material such as steel, iron, etc. How result of these parasitic currents, the utensil is heated of cooking and the food contained therein.

The induction cooktop system is feeds from an AC voltage source. A rectifier is connected between the current voltage source alternate and the power stage of the induction hob to generate series of rectified alternating current half cycles. The heating coil is connected between the output of the rectifier and semiconductor switch (IGBT). Condenser resonant is connected in parallel to the heating coil and an anti-parallel diode is connected in parallel to the IGBT.

As mentioned in the previous section, in prior art there is no system that employs a microprocessor to activate the transistor and to execute the timing, fast and critical operations, such as the measurement of feedback signals from the stage of power. The objective of this system is to take advantage of all advantages of a microprocessor for these critical operations and, with the help of additional analog circuitry, minimize disadvantages of a digital system (for example, outputs and random program errors due to fluctuations in power).

Brief description of the drawings

Figure 1 shows the block diagram Functional set of induction cooker system which Incorporates the invention.

Figure 2 illustrates the block diagram in that the control blocks of figure 1 have been replaced by The microprocessor

Figure 3 represents the power stage and the input stage of the induction cooker system.

Figures 4a and 4c show the waveform of the current of the IGBT as a function of time, the voltage IGBT collector-emitter, V_ {CE}, depending on the time, and the discriminated passage signal of the IGBT based on the time, respectively, when the input power is relatively low

Figures 5a and 5c show the waveform of the current of the IGBT as a function of time, the voltage IGBT collector-emitter, V_ {CE}, depending on the time, and the discriminated passage signal of the IGBT based on the time, respectively, when the input power is relatively high

Figures 6a and 6b illustrate the diagram of Microprocessor software flow.

Figures 7a and 7b represent "Routine 1: Get user entries "and" Routine 2: Determine duration of the out-of-driving period of the software of the microprocessor illustrated in Figures 6a and 6b.

Figure 8 shows the circuit diagram for The current transformer block.

Figure 9 illustrates the circuit diagram for The protection circuit block.

Figures 10a and 10b show the waveform V_ {CE} as a function of time, after the electrode of IGBT command receives a driving boost and the timing of the next driving start pulse.

Figures 11a-11d illustrate the inductor current, I_ {L}, as a function of time, V_ {CE} in function of time, the discriminated step signal, V_ {GE}, in function of time and zero crossing output depending on the weather.

Figure 12 represents the circuit diagram of the kitchen utensil detection circuit.

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Figures 13a and 13b show the tension, V_ {C1}, of DC link as a function of time, and the output of the 50 Hz zero-pass detector depending on the time, when a utensil is placed on the kitchen plate suitable.

Figures 14a and 14b show the tension, V_ {DC}, of DC link as a function of time, and the output of the 50 Hz zero-pass detector depending on the time, when there is no placed on the cooktop suitable utensil.

Figure 15 represents the circuit diagram of the voltage to voltage converter block.

Figure 16 represents the circuit diagram of the activation block of the system control electrode induction cook.

Detailed description of the preferred embodiments

Figure 1, in which the blocks have been Designated according to their functions, shows the representation, in the form of a block diagram of the induction cooker system. The "Power stage" block (10) is where the transmission of energy from the system to the kitchen utensil (20) and where the current and the high magnetic field are generated frequency. The bipolar transistor with isolated control electrode (IGBT) used in this block is activated by the passing pulses discriminated sent by the "electrode activator block of command "(11).

"Command electrode activator" (11) receives signals from the "duration controller of the driving period "(12) and" duration controller driving period "(13)." Duration controller of the driving period "(12) determines the duration of the period of conduction of the impulses of discriminated passage according to the power level required by the block "controller power "(14). The durations of the driving periods of the discriminated step signals of each power level are defined and different from each other. The value that the current reaches of the inductor (19) in that period is also defined, so the value (620) of the inductor current is also monitored. He block "period duration controller out of driving "(13) determines the durations of the periods of out of conduction of the impulses (540) of discriminated passage. The periods of non-driving do not vary with the value of the current, but are sensitive to load variations. And the durations of periods outside driving are defined by the zero crossings of the inductor or coil current of heating (19). Thus, the circuit "Detector passing through zero "(22) used in the" Protection circuits "block (15) detects the moments of zero crossing of the current of the inductor (19) and, in those moments, sends a signal to the controller (13) off-driving period.

The inductor current (19) is measured and transformed into a low value voltage signal by the block "current transformer" (16). The "Controller of power "(14) obtains user inputs, such as the desired power level or the desired temperature of the utensil cooks, and defines accordingly the durations of the periods of commissioning of the discriminated step pulse (540). Also, monitor the peak value (610) of the inductor current and the temperature of the kitchen utensil (20) to control the power level and temperature of the kitchen utensil (20). In addition, it monitors the outputs (570A, 570B, 590) of warning signals e interrupts operation if necessary.

The "Protection circuits" block (15) It is designed to protect the system against conditions of over-intensity and discriminated pass signals (520) wrong. This block continuously monitors the voltage collector-emitter, V_ {CE}, of the IGBT and the value (620) of the inductor current and makes the control block (14) power interrupt system operation when It presents a dangerous condition. The detection circuit (17) of cookware observes the current link voltage (500) continues from the power stage (10) and makes the block (14) power controller interrupt operation if detected An inappropriate kitchen utensil.

Figure 2 shows the same block diagram functional than figure 1 when using a microprocessor (18) in the system as an interconnection with the user, to control the utensil temperature (20) and power level, and for the observation of dangerous conditions.

The circuit "Power stage" (10) generates a high frequency electromagnetic field (about 20-25 KHz) to heat a kitchen utensil (20) of magnetic material. Figure 3 shows the diagram of detailed circuit of the power stage (10). The circuit of power is connected to the network through a "rectifier of full wave "(24) D1, D2, D3 and D4. The output (500) of the full wave rectifier (24) is fed to the stage of power (10) through a high bypass capacitor frequency, C1. The voltage across C1, V_ {C1} or V_ {DC}, It is also called DC link voltage (500). C1 is not large enough to make V_ {DC} a signal of direct current smooth; thus, V_ {DC} is formed by the plurality of rectified current line half cycles. As the Interrupt frequency (about 20 KHz) of the IGBT is much higher that the frequency of the network (50 Hz), it could be assumed that the voltage  DC link (500), V_ {DC}, is constant during a period of interruption (approximately 50 \ mus).

The transistor (IGBT) is put into driving and out of conduction in response to impulse signals (520) from the activation circuit to carry a coil of heating (19), L, and a condenser in parallel with it, C_ {RES}, to a resonant state. Consequently, the coil of heating (19) generates a magnetic flux that causes an action of electromagnetic induction to generate a parasitic current in a kitchen utensil (20) of magnetic material. When he transistor is put into conduction, a short current of circuit, I_ {Cres}, circulates through the resonant capacitor and the IGBT for a very short period (a few microseconds). During the rest of the driving period, by the heating coil (19) and the IGBT circulates the current I_ {L}. The sum of these two currents is the current of the IGBT and is represented in the figure 4a. The value of I_ {Cres} depends on the value of the voltage (510) IGBT collector-emitter, V_ {CE}, in the instant of driving. The V_ {CE} waveform (510) is illustrated in Figure 4b. As can be seen, the transistor it is put into driving at the moment when the voltage of Collector is not zero. Thus, the voltage across the capacitor resonant forced to a change equal to the value of V_ {CE} (510) in the moment of the start-up. This way, you can write the following equation:

C_ {RES} \ text {*} \ Delta V_ {Cres} / \ Delta t_ {fi} \ = \ C_ {RES} \ text {*} V_ {CE} / \ Delta t_ {fi} \ = \ I_ {Cres}

Where \ Deltat_ {fi}, illustrated in the figure 4b, is defined as the period of time that V_ {CE} (510) falls to zero, namely the time of change to driving. Likewise, \ DeltaV_ {Cres} is the change in voltage across C_ {RES}.

When the durations of the driving time periods also increases power consumed from the power line. The current of the IGBT for case of a high power output, is represented in the figure 5th. As V_ {CE} (510) at the time of commissioning is of zero volts, \ DeltaV_ {Cres} is also equal to zero. So, using the previous equation, I_ {Cres} is found to be zero. Therefore, it is evident, from Figure 5a, that only The inductor current (19) circulates through the IGBT. The way of collector voltage wave (510) is represented in the figure 5b Given the nature of the resonant circuit, V_ {CE} tends to adopt negative values but the diode in anti-parallel, D_ {P}, prevents these cycles negative Therefore, V_ {CE} (510) is limited to zero volts when D_ {P} is driving, as indicated in the figure 5b

If for 20 milliseconds, which is the period of the 50 Hz input alternating current signal (V ac), is assumes that the periods of driving and out of conduction of the discriminated step pulses (520) have constant duration and current I_ {CRES} is neglected, then it could be accepted that the average of the current of the IGBT, that is, the input current is proportional to the voltage (500) of DC link and, therefore, to V_ {ac}. Consequently, the system takes power from the network with a unit power factor, that is, the input current and V_ {ac} have the same phase.

The digital device (18) responds to start and interrupt the operation of the power stage (10) The microprocessor (18) starts the power stage (18) when the system is activated and an input is received from Username. The microprocessor (18) stops operation when the cookware temperature (20) reaches a value Default by the user. It also disables the operation of the inverter when the presence of a improper kitchen utensil and restart the system after a while. When an alarm signal is received (570A, 570B, 590) from peripheral circuits analog (15, 17), the microprocessor (18) treats this signal and disables discriminated pass signals (540) during a fixed duration period; then it restarts when it has The period of silence has passed.

The digital device (18) adjusts the level of power regulating the commissioning periods of the discriminated passage pulses (540); no one is required intermittent operation to adjust the power level. To the start, the cooktop begins to heat to power minimum, which means that the discriminated passage signals of driving are the shortest and then the power is increased until the user's desired power level is reached. The power is monitored by monitoring the peak current value (610) of the inductor; this value is directly related to the output power.

The program algorithm of the microprocessor (18) using the process diagram illustrated in Figures 6a and 6b. When the system is activated (100), the microprocessor (18) reads user inputs as shown through Routine 1: GET USER TICKETS (110), which shown in figure 7a.

In Routine 1 (110), the microprocessor (18) read the variables MODE and LEVEL (111) defined by the user to through the user panel, not necessarily shown in the figure. MODE could be TEMP (TEMPERATURE) or POWER (POWER) (112). If it is TEMP, it means that the cooktop of induction will work as a temperature controlled system (114). Thus, it will work at maximum power, defined as Max_Power (maximum_power) until the temperature reaches the desired value by the user, defined as Final_Temp (final_temperature), which It is equal to the variable LEVEL. If the MODE is POWER (113) it means that the hob will work at the desired power by the user, which is equal to the variable LEVEL. Also, the operation will be interrupted, as a safety precaution, if the temperature reaches the maximum permissible value, defined as Max_Temp (maximum_temperature). Max_Temp and Max_Power are the constant system parameters and cannot be modified by the user.

After acquiring user tickets, the level of current power, power_level, with which the cooktop, set to the minimum power level of the system, Minimum_power (120). The durations of the driving periods they are default values that change accordingly with the current power level. Each power level has its own predefined durations (120) of the periods of driving. Minimum_Power is a constant system parameter and It cannot be modified by the user.

The duration of periods outside of conduction depends on the resonant frequency of the stage of power (10), namely, of load variations; thus, They must be updated dynamically. During startup for determine the durations of periods of non-driving, in First, a single discriminated step pulse is generated (130) (540). "Discriminated step" is a built-in function of the PWM output (pulse width modulation) of the microprocessor. The first argument of the function "step discriminated "is the conduction duration of the step signal discriminated against (520), and the second argument is the duration outside driving. To generate a single pulse, the duration is sent predefined in driving as the first argument and, as duration (130) of the off-driving period a time is entered long enough, 1 second (this value is not mandatory but simply preferable), so that at the exit (520) of the microprocessor control electrode (18) will only be produced an impulse.

After generating the single step pulse discriminated against, Routine 2 is called: DETERMINING DURATION (140) FROM THE PERIOD OUT OF DRIVING, illustrated in Figure 7b. In this routine, at the instant (141) of driving out of the discriminated step signal (520), a timer is started (142) and the time elapsed until it is counted (143) is counted presents the falling edge of the signal of the perceiver passing through zero. This time is saved as duration (144) of the period outside of driving.

After determining the durations of the driving and off-driving periods of the passing signals discriminated, these could be started using the "Step discriminated against "(150).

Every second the entries of the user, to see if this has made any update and, each 100 milliseconds (this value is not mandatory but simply preferable) the peak value (610) of the current of the inductor; power_level is updated so that you can reach final_power_level and, finally, the cooking utensil temperature (20). Two are used timers: timer 1 and timer 2, to count the duration of these periods. These timers are set in motion. just after starting (160, 170) the impulses (540) of discriminated step. When the current link voltage continuous reaches its peak value, the duration of the off-driving period using Routine 2 (140), as has been described above. This action is repeated in a loop every 10 milliseconds (this value is not mandatory but simply preferable).

Thus, 3 nested loops are executed (each of them with their own timers: timer 1, timer 2, timer 3) that are repeated continuously unless interrupt system operation. The value envelope (610) of the inductor current is checked every 100 milliseconds; if the peak value (610) of the current is not in a band of ± 20% (this value is not mandatory but, simply, preferable) around the expected value, then it stops (200) operation for 3 seconds and starts from new the whole procedure; otherwise, the software continues its execution (190).

The level of the power of the current, Power_Level, is compared to the final_Power_Level, which is the desired power level (190) by the user. Yes Power_Level is greater than final_power_Level, then it reduce (210) Power_Level. If they are the same, it is not carried out any update (220); otherwise, it increases (230) Power_Level The temperature of the kitchen utensil (20) is received from the analog peripheral circuit (21) and stored in the TEMP variable. TEMP is compared with the value Final_Temperature what the user wants (240). If the temperature of the utensil of cooker (20) reaches the desired value, operation stops of the system for 10 seconds (this value is not mandatory but, simply preferable) and the whole procedure is restarted from the beginning (250). Otherwise, the software continues its execution (260).

The shortest loop ends instantly in that the peak value of the link signal (500) of DC; this instant appears 5 milliseconds later that the output (580) of the 50 Hz zero-pass detector (23) reaches the HIGH value (if the frequency of the line is assumed is 50 Hz). If this output (580) does not adopt the HIGH value, it check (280) the outputs (570A, 570B) of the circuits protection (15) and output (590) of the detection circuit (17) of cooking utensil. If any of them (570A, 570B, 590) has the HIGH value, this means that a utensil of improper cooking on the hob or that there has been a dangerous condition, so the passing signals (540) Discriminated are interrupted for 3 seconds (200). One time Once the 3-second period is completed, it starts again (100) all The procedure. If none of them (570A, 570B, 590) has the HIGH value, then the output (580) of the 50 Hz zero-pass detector (23), loop-shaped (260).

When the output (580) of the passage detector (23) by 50 Hz it takes the HIGH value, the microprocessor replenishes the "timer 3" and begins a count of 5 milliseconds (270). While said calculation is being carried out, the microprocessor (18) it also checks the outputs (570A, 570B) of the circuits of protection (15) and output (590) of the detection circuit (17) of cooking utensil. If any of them (570A, 570B, 590) adopts the HIGH value (320), the discriminated step signals (540) are interrupted for 3 seconds (200). Otherwise, it is checked Timer 3 if the period of 5 milliseconds expires (330). Yes has not expired, the signals are checked in loop form (320) (570A, 570B, 590) warning of danger. Otherwise, it updates the duration of the off-driving period of the discriminated passage pulses (540) using Routine 2 (140) and the durations of the periods are updated accordingly (290) out of conduction of the discriminated passage signals.

Then, the timers are checked to see if the durations of the loops have been exceeded (300, 310). Whether has exceeded (310) the duration of 100 milliseconds, then the Timer 2 is spare (170) and the procedure is repeated described above. If you have exceeded (300) the duration of 1 second, user entries are checked using the Routine 1 (110), regarding updates and then replenished (160) timer 1 and the loop is repeated.

The current transformation block (16) transforms the inductor current (19) into a voltage value which is defined as value (620) of the inductor current. The Figure 8 shows the internal diagram of the transformer block (16) of current. The primary side of the transformer is the coil of heating (19) and the side of the secondary is where the voltage transformed, in resistance R10. The relationship of windings, 1: N, defines the output voltage of the transformer of current, V_ {OUTPUT}, as

V_ {OUTPUT} = R10 \ text {*} I_ {L} / N

Where I_ {L} is the current flowing through the heating coil (19).

Also, using D10 and C10, it is saved and sends the peak value of V_ {OUTPUT} to the microprocessor (18) and, therefore, the peak value (610) of the inductor current.

The protection circuits (15) and the circuit (17) kitchen utensil detection are designed to protect the power circuit (10) against dangerous conditions unexpected, such as a microprocessor failure (18).

The analog protection circuit (15) monitors the value (620) of the inductor current and the voltage of manifold (510) of the semiconductor switch. When the value (620) of the inductor current exceeds the maximum permissible value (V_ {ref, current}), the output of COMP1 takes the value HIGH. This output drives the T3 bipolar transistor (530); in consequently, it hooks the output of the step signal (520) discriminated in the low state so that the power inverter (10). Therefore, the power circuit (10) and the IGBT are protected against overcurrents. Too, sends an alarm signal (570A) to the microprocessor (18) to make that this one disables the outputs (540) of discriminated passage of the digital circuitry (18). Similarly, when the tension (510) of transistor collector is above a value default (V_ {ref, voltage}) the signal output (520) of discriminated step is hooked in a low state through T3 (530), so that discriminated passage signals are eliminated false that may be caused by a microprocessor failure. If a pulse (540) of discriminated passage arrives at the instant in that the output of COMP2 has a HIGH value, this step signal discriminated against cannot drive the IGBT, because the T3 collector voltage (530) has already set the signals (520) discriminated in the LOW state, so that the stage of power (10) and the IGBT may be protected, but the output (570B) of logic gate Y1 will adopt a HIGH state, indicating a dangerous condition. Thus, the microprocessor (18) stops generating impulses (540) of discriminated passage.

As the losses out of driving and in IGBT driving is inevitable, it could only be reduced to Minimum driving losses. To achieve this goal, V_ {CE} (510) should be investigated, as it is the most important that affects the value of losses outside driving. As can be seen in figure 10a, after the moment it is put the transistor off, V_ {CE} (510) oscillates at the resonant frequency of the heating coil (19) and the resonant capacitor, C_ {RES}. Thus, the minimum of V_ {CE} (510) it always occurs at the same moment after putting off conduction for the same load, heating coil (19), and C_ {RES}.

The duration of the off-driving period is constant during an alternating current half cycle and is directly related to the resonance frequency of the power inverter (10). But, due to load variations, Resonance frequency may vary. To compensate for these variations, the inductor current (19) is monitored by the current transformer (16), which is also used as overcurrent protection. Theoretically, the minimum tension V_ {CE} (510) occurs in the zero crossing of the current of the inductor (19). Figures 11a and 11b show the waveforms typical of the inductor current (19) and V_ {CE} (510), respectively, thus, observing the value (620) of the current of the inductor, the durations of the periods outside could be achieved driving with minimal power losses. The value (620) of the monitored inductor current is inverted by a inverter amplifier (22) and is fed to the microprocessor as output (560) of the zero crossing detector. The microprocessor (18) updates the duration of the off-road signals every 10 milliseconds (290) watching this signal. The microprocessor (18) calculates the time elapsed between the instant of setting off conduction of the discriminated passage signals (140) and the edge downstream of the output (560) of the zero crossing detector (22). Figure 11d shows the output (560) of the detector (22) passing through zero.

The system also includes a circuit, called kitchen utensil detection circuit (17), for detect if a kitchen utensil has been placed on the hob kitchen (20) suitable. This circuit (17) monitors the signal (500) of DC link voltage. According to the signal monitored, the cookware detection circuit (17) decide whether or not there is a kitchen utensil on the plate (20) adequate. If a suitable kitchen utensil is not present, This circuit (17) sends an alarm signal (590) to the microprocessor (18) to make it disable the operation of the power inverter (10) for a while predetermined.

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If a cooktop is not present proper kitchen utensil, there will be no transmission of any energy from the power stage (10) to the utensil of kitchen (20). Detection of the presence of a kitchen utensil (20) is based on the change of the voltage waveform (500) of DC link Figure 13a shows graphically this tension (500) in case there is a utensil Kitchen (20) suitable. When there is no suitable kitchen utensil, the waveform (500) becomes the signal of figure 14a. How no power transmission occurs when a Proper kitchen utensil, energy will be stored in the C1 high frequency bypass capacitor. Therefore, the presence of the kitchen utensil (20) can be detected by evaluating this waveform (500). The 50Hz zero-pass detector (23) produces a HIGH value signal (580) during the zero crossing of the DC link signal (500) over a period of, approximately 400 microseconds. This output (580) is powered also to the microprocessor (18) G to detect the moment in which the peak of the direct current link voltage occurs. The DC link voltage (500) is monitored with a resistance divider by the inverting input of the comparator COMP3 of Figure 12. The value of the non-inverting input, to know, the reference value, is a small fraction of the value of peak voltage (500) of direct current link. Of this mode, when the DC link voltage (500) falls below a certain value, the comparator output (580) will pass to a HIGH state, as seen in figure 13b.

As seen in Figure 14b, no step occurs by zero when there is no suitable kitchen utensil. Thus, the circuit (23) 50 Hz zero-pass detector will not produce a HIGH value signal output when there is no cookware suitable. The cookware detection circuit (17) observe these outputs and, if the detector (23) of zero crossing of 50 Hz does not generate a signal output (580) of HIGH value during a 400 millisecond period, sends a signal (590) to disable the microprocessor (18) to stop the operation of the stage of power (10). 3 seconds after the operation, the circuit (17) starts the system to detect if the user has placed a utensil of cooker (20) suitable on the hob. Then, look at the output (580) of the 50 Hz zero-pass detector (23) during 400 milliseconds and disables the system or stays on hold, according to the value of this signal, that is, the presence of a kitchen utensil (20).

In Figure 13, the output (580) of the detector (23) 50 Hz zero-pass feeds the entrance of the door NO-Y A. The exit of the NO-Y gate A capacitor C23 charges and, if its input has a LOW value, it It means that there are no zero steps. Time elapsed to load C23 up to a value that causes the output of the door NO-Y B adopt a LOW state is, approximately 400 milliseconds. If there is no zero crossing, then C23 is loaded up to the threshold value, the output of the NO-Y B gate takes the LOW value and the output (590) of the NO-Y C gate takes the HIGH value, which is connected to the microprocessor (18).

Figure 15 illustrates the circuit diagram of the block (21) voltage to voltage converter. A thermistor of negative temperature coefficient (NTC) is located below of the top plate of the cooktop and perceives the temperature of the kitchen utensil (20). The NTC and R11 thermistors form a resistance divider and the voltage at node (600) changes to As the temperature changes. Thus, observing the tension in the node (600), the microprocessor could acquire the temperature of the kitchen utensil (20).

The invention contains an activator (11) of control electrode with a single output in termination counter unique designed for direct activation of IGBT. This block it is necessary because the impulses (540) of discriminated passage of the microprocessor (18) is between 0 and 5 V, but the IGBT requires between 0 and 15 V to have a better behavior. When arrive a discriminated passage signal (540) for driving from the microprocessor (18), the lower transistor T1 will be set out of driving and the upper transistor T2 will be put in driving. Therefore, a 15 volt signal will reach the electrode IGBT control via node (520) and the upper transistor, T2 When a discriminated step signal (540) arrives for setting out of conduction from the microprocessor (18), the transistor lower T1 will be put into driving and the upper transistor T2 It will be put out of driving. Therefore, the control electrode of the IGBT will be grounded through node (520) and the lower transistor T1. Through node (530), the exit of the command electrode activator could be grounded by the protection circuits (15), regardless of the signal of discriminated step received from the microprocessor (18). This prevents false signals (540) from discriminated passage caused for microprocessor failures, destroy the transistor of power.

Claims (7)

1. An induction cooker, which understands: a power inverter circuit (10) that takes of the network essentially a power factor current unit, which has an induction heating coil (19) which generates a high frequency magnetic field that is induced on a magnetic cookware (20) removable or not removable, a resonant capacitor in parallel with said coil (19) heating, an IGBT as an interruption element and a power diode (D_ {P}) arranged in anti-parallel with said IGBT; a microprocessor (18) that takes the temperature desired of the kitchen utensil or the desired power level of the kitchen appliance from a control panel, which controls the power transmitted to said kitchen utensil (20) by adjusting the duration of pulse driving (520, 540) discriminated, which controls the temperature of the aforementioned utensil cooker (20) interrupting the operation of the system when the said kitchen utensil temperature (20) reaches the value desired or restarting the system, after wait for a preset period, after being interrupted such operation, which adjusts the duration of periods outside of conduction of the impulses of discriminated passage observing the moments of zero crossing of the current flowing through the coil heating by means (22) detectors of the passage through zero, and interrupting the operation of the power stage (10) for a predetermined period of time when receiving a warning signal (570A, 570B, 590) from a circuit (17) of detection of kitchen utensil or a block (15) of circuitry protection; a utensil detection circuit (17) of kitchen that detects if there is a suitable kitchen utensil (20) placed on the hob observing the tension (500) of DC link and comprising detector means (23) 50 Hz zero crossing to detect zero signal crossings AC voltage input (V_ {ac}); a protection circuit block (15) analogs that protect the power stage (10) against overcurrents observing the current flowing through the coil heating (19) and against inappropriate signs of passage discriminated by observing the collector voltage of the IGBT (510) and, at same time, the discriminated passage signals (540). 2. An induction cooker according to the claim 1, wherein said microprocessor (18): in a power mode, acquires the input of power from the user panel, assign the temperature desired kitchen utensil (20) to the default value of maximum permissible temperature of the kitchen utensil (20), and makes operate the power inverter (10) at the power input selected; in a temperature mode, acquire the input of temperature from the user panel, operates the power inverter (10) at the maximum power level, stops the system operation when the utensil temperature of cooker (20) reaches the desired value, and restart the system after waiting a preset time. 3. An induction cooker according to the claim 1, wherein said microprocessor (18): start activating the power stage (10) with the minimum power level of the kitchen device, compare the present power level with the power level that the user has entered through the control panel, increases or decreases the present power level to match both levels; generates pulses (540) of discriminated passage that have driving durations corresponding to the level of power at that moment; compare the peak value (610) of the current of the inductor with the expected value and interrupts the operation of the system for 3 seconds if it is not within a ± 20% band around expected value. 4. An induction cooker according to the claim 1, wherein said microprocessor (18): first observe the output (580) of the detector (23) pass through zero of 50 Hz and wait 5 milliseconds, when the output (580) has a HIGH value; Calculate the time between instant of driving off the impulse (540) of the discriminated passage  current and the instant the output (560) of the detector (22) of zero crossing changes its state, from HIGH to LOW; use the time calculated as the duration of the period of putting out the conduction signals (540) discriminated, until the next calculation. 5. An induction cooker according to the claim 1, wherein said microprocessor (18): look at the output (590) of the circuit (17) of kitchen utensil detection and output (570A, 570B) of block (15) of protection circuits; interrupts step signals (540) discriminated for 3 seconds and restart the system, after this period has elapsed, if any of these outputs (570A, 570B, 590) has a HIGH value. 6. An induction cooker according to the claim 1, wherein said detection circuit (17) of cooking utensil: comprises means (23) detectors passing through 50 Hz zero comparing the current link voltage (500) continues with a reference value using COMP3 and they produce an output (580) with HIGH value if the link voltage (500) of direct current is lower than this reference, producing otherwise an output (580) with LOW value; observe the inverse of this output (580) through of a door NO-Y A; if the output (580) of the detector (23) passing through 50 Hz zero has LOW value, charge the capacitor (C23) with the NO-Y A gate exit via R56 (with a time constant of R56 * C23) and otherwise download it to through (R55 // R56) (with a time constant of (R55 // R56) * C23); send a signal with HIGH value to microprocessor (18) if C23 is charged to a value greater than Door entry threshold NO-Y B, or with value LOW if not; charge the capacitor (C22) with the output of the NO-Y C gate via R59 and R52 (with a time constant of (R52 + R59) * C22) if the output (590) of the cookware detection circuit (17) has HIGH value and, if not, download it through R59 (with a constant of R59 * C22 time); download C23 through R58 causing the COMP4 output take the LOW value, if C22 has been loaded above of a preset reference value over a period of duration determined by the time constant of ((R52 + R59) * C22), and not download if not; reset the output of NO-Y C to LOW state when C23 is discharged to a value lower than that of NO-Y B input threshold. 7. An induction cooker according to the claim 1, wherein said circuit block (15) of protection: comprises means (22) detectors passing through zero that reverse the value (620) of the inductor current received from the block (16) current transformer and that send it to the microprocessor (18) as output (560); comprises a comparator (COMP1) that compares said value (620) of the inductor current with a value of reference (V_ {ref, current}) that corresponds to the maximum value permissible current, sends a signal (570A) with HIGH value to the microprocessor (18) if said value (620) of the current of the inductor is greater than V_ {ref, current}, or a signal (570A) with LOW value otherwise; BJT drives (T3) and sets signals (520) of discriminated passage to the LOW value through node 530, if The output of COMP1 has a HIGH value, not intervening on the impulses of passage discriminated in opposite case; it comprises a comparator (COMP2) that compares the IGBT collector voltage (510) with a reference value that corresponds to the maximum permissible value (510) of the voltage of collector before commissioning of the IGBT; producing a output with HIGH value if the collector voltage (510) is greater than reference value, or with LOW value otherwise; sends a signal (570B) with HIGH value to the microprocessor (18) if the output of COMP2 has a HIGH value and the discriminated passage output (540) has, at the same time, value HIGH, or LOW value if not; BJT drives (T3) and sets signals of discriminated passage (520) with LOW value through node 530 if The output of COMP2 has a HIGH value, not intervening on the impulses of discriminated passage if not.