TR201507682A3 - MULTI-ZONE QUASI-RESONANCE INVERTER INDUCTION HEATER SYSTEM AND METHOD IMPROVING NOISE PERFORMANCE - Google Patents

Abstract

The present invention relates to an induction heater cooking system and method in which the audible noise caused by different operating frequencies is prevented when the individual cooking zone is controlling the power. In particular, the present invention provides a plurality of resonance inductors (6) associated with induction resonance inverters (2) supplied by means of a medium DC bus to obtain a multi-zone induction coil system, power switching devices (5) associated with said induction resonance inverters (2). a power switch driving circuit; and a pan sensing circuit for detecting the presence of a ceiling.

Description

DESCRIPTION MULTI-ZONE QUASI-RESONANCE INVERTER WITH INDUCTION HEATER THE SYSTEM TO IMPROVE THE NOISE PERFORMANCE OF THE OVEN AND METHOD This invention allows for power control of individual cooking zones, while different operating A multi-zone where audible noise caused by frequencies of It is about the operating system and method of the hob with induction heater. Induction heater cooktops are electromagnetically induced eddy currents. Heating a ferromagnetic material with the induction process and talking about resistance. The subject ferromagnetic material, in other words, in the form of pans or pots It is operated by dissipating the heat in a cooking cabinet.

In the induction heating method, high frequency alternating current is used on the same A magnetic field of high frequency is passed through an induced coil. interior of the ceiling resistance causes heat dissipation with the Joule effect and the pan is removed from the stove. When it is removed, the energy transfer is interrupted. Between the hotplate and the cooking pot Energy efficiency of furnaces with induction heaters as there is no heat energy transfer is significantly higher and the loss of heat energy by air is also minimal. level.

A resonant converter in an induction heater circuit is a capacitor, a It consists of an inductor and a resistor. For this purpose, power to the resonance tank When powered, electrical energy is stored in the inductor and transmitted to the capacitor.

Thus, resonance occurs when the inductor and capacitor exchange energy.

Resonance converter, a half-bridge series resonant converter or quasi-resonance converter It can be a translator.

With half-bridge series resonant converters with a more complex operating structure by comparison, simple circuit with only one power switching device quasi-resonant converters half-bridge series resonance It has some advantages over converters. Circuit in a quasi-resonant converter design parameters provide an important cost advantage in this respect.

Driving a magnetic field generating resonance inductor and using a cooking cabinet A high-frequency power source such as IGBT is used to induce eddy currents at the surface of the key is used.

In the patent document numbered EP 1629698B1, which is in the state of the art, a power inverter, a microprocessor, a protection circuit and a pan detection circuit A system with an induction heater is described.

According to a specific load, in other words, a cooking pan that reacts magnetically Variable operating frequency with multiple burners at the same time when applied to an induction heater stove with burners, the frequency between the burners a pan of interference noise arises due to their differences.

Thanks to this invention, while controlling the power of the individual cooking zone, different operation audible noise caused by frequencies are blocked and multiple where the induction resonance inverter is effectively powered from the same DC bus An induction heater cooktop operating system and method is being implemented.

By virtue of this invention, all the properties defined in claim 1 and single cooking zone power at one main driving frequency for resonant inductors Cooker operating system with an induction heater that allows the control of and method is implemented.

The aim of this invention is to control the individual power of the different cooking zones into one main drive. A stove operating system with an induction heater that allows method is implemented.

The subject of the invention is the induction heater hob, a ferromagnetic cooking cabinet. detects the presence and correct position on the hob with induction heater.

The hob with an induction heater consists of a bridge rectifier, a DC line inductance and a DC The line contains the capacitor. The hob with induction heater is also A medium connected to a bridge rectifier is connected to a DC source and a high voltage such as IGBT. connected in parallel to be energized by the frequency switching device multiple quasi- Includes resonant converter. High frequency switching device, reverse parallel It is connected in parallel to a diode in the form of a diode.

The induction hotplate allows the presence of at least one cooking pan to be detected and a a main resonance inductor to be determined in the main cooking zone. contains the control circuit. Main cooking zone with maximum conduction time resonance in the main cooking zone, which includes power switching devices with inductors are determined to be determined. Next, the main cooking The nominal operating time of the main cooking zone in question is set. It is calculated proportionally to the power setting. A common switching frequency determined and all other resonances in the induction heater hob. applied to the inductors.

In addition, the nominal values of resonance inductors located in different cooking zones Transmission times vary according to different power settings set by the user. is calculated. The rated runtimes obtained are per cooking only. It is used to determine a certain working rate for the region. Calculation, The nominal conduction times obtained are a predetermined value of the denominator. determines the operating rate of a particular power switching device, where It is done in a way that will constitute the share of the rate.

The appended figures only outline above the advantages over the prior art. an induction heater stove described and described in detail below given for illustration purposes.

The figures do not limit the scope of protection defined in the claims and this without reference to the technical explanation in the explanation part of the invention, alone for the purpose of interpreting the scope defined in the claims should not be used.

Figure 1 shows the circuit diagram of the power circuit in one embodiment of the invention. shows.

Figure 2 - hob operation with induction heater in one embodiment of the invention It shows the general flow diagram of the method.

The parts in the figures are numbered one by one and the corresponding numbers are given below: 1) Cooker with induction heater 3) Filter inductance 4) Filter capacitor ) power switching device 6) Resonance inductor 7) Resonant capacitor 8) Full wave rectifier 9) Free pass diode ) input node 11) Collector node 12) Control circuit The subject of the invention is the induction heater cooker (l), multi-zone induction coil It contains multiple induction coils in the form of Each induction A power subcircuit associated with the coil is located in the hob (1) with the induction heater. A magnetically responsive cookware placed on top of induction coils or heat energy is induced in the pan.

The hob with induction heater (l) is a multiplex powered by AC voltage source. includes an induction resonance inverter (2). A full-wave bridge rectifier (8), Between the AC power supply and the power stage of a resonance inductor (6) is connecting. The resonance inductor (6) is connected with the output of the said rectifier (8). it is connected between a power switching device (5). resonance capacitor (7) is connected in parallel with the resonance inductor (6) and an antiparallel diode is connected to another i.e. a free pass diode (9), connected to said power switching Device (5) is connected in parallel.

The hob (l) with an induction heater is usually an AC signal filtering circuit contains. Power passing through a filter capacitor (4), high frequency current performs the filtering function. Voltage of filter capacitor (4), promise to square wave by the high frequency power switching device (5). is being converted. According to Ampere's Law, a square wave, resonant inductor (6), that is, it creates a magnetic field around the induction coil. creates resonance. Thus, the one connected in parallel to the resonance inductor (6) The resonance capacitor (7) determines the inductive property of the resonance inductor (6). it compensates.

The power switching device (5) housed in the quasi-resonant converter, with an insulated door It is a bipolar transistor (insulated gate bipolar transistor-IGBT). Quasi-resonance The operating principle of the inverter is usually when the power switching device (5) is open. storage of energy in the resonant inductor (6) and the power switching device (5) when off, energy is transferred from the resonance inductor (6) to the cooking cabinet. is based on. In other words, when the power switching device (5) is closed, Since the resonance capacitor (7) is discharged, the collector node (11) the resonance voltage increases. The resonant voltage is the input at the input node (10) voltage, the energy stored in the resonance inductor (6) is equal to the resonance It is transferred to the capacitor (7). Resonant voltage maximum When it reaches its value, the resonant current slowly drops to zero, in other words, energy transfer from the resonance inductor (6) to the resonance capacitor (7) is terminated. As a result of this, the resonance capacitor (7) absorbs the energy it has stored. begins to discharge to the resonance inductor (6). Current parallel to IGBT It completes its cycle by passing through the connected free-pass diode (9).

Thanks to this invention, the house in which multiple flexible cooking compartments will be created will be different. sized cookware to be heated by induction. Multiple separate induction coils driven by resonance inverters (2) (resonance inductors (6)) are implemented.

In one embodiment of the invention, a single-switch quasi-resonance converter is used. multiple induction resonance inverters (2) are fed from the same DC bus and This is due to the different operating frequencies of different power switching devices (5). It causes audible noise when driven. prevent this For this reason, with this invention, audible noise problems will be explained below. A working method is carried out that allows it to be overcome.

A cooking cabinet on a vitroceramic glass surface of the hob with induction heater To detect whether the control circuit (12), a pan detection circuit that senses the cookware position It monitors and controls the operation of the induction hotplate (l) via is doing. Pan detection methods on stoves with induction heater (l) are described in the art. it is used extensively and is known to the person skilled in the art. This Such a pan detection circuit monitors the resonant current or IGBT voltage.

The microcontroller collector nodes (ll) in the control circuit (12) voltages and voltages at the input nodes (10) and a power switch The driving circuit is switched to the corresponding power switch according to the power setting defined by the user. drives their devices (5).

In one embodiment of the invention, each resonant inductor (6) is connected to the same DC bus. by a corresponding quasi-resonance inverter (2) energized by is energized. In this circuit structure, audible noise generation separate resonance inductors (6) to avoid must be energized at intervals of time or all at the same switching frequency. should be run.

In the inventive system and method, all quasi-resonance inverters have a common or at the main switching frequency. In this application, a After each resonant coil (6) forming part of the cooking zone has been identified, then said resonance inductors (6) are energized according to my references, and all associated resonance coils (6) a predetermined maximum current of a power switching device (IGBT (5)) The maximum transmission time is determined according to the reference.

In this application, a power with maximum transmission time at the highest power level is used. the resonant coil (6) associated with the switching device (5) is designated as the main coil. and the cooking zone where the main coil is located is the main cooking zone. Mother Once the coil has been determined, the user-defined zone of the main cooking zone power level setting, to calculate the rated transmission time of the main coil is used. For example, the maximum transmission power switching device (5) of the main coil When the time is set to 18 us, the power level setting of the relevant cooking zone 9 out of 10, which is the highest setting, the main cooking zone is real or the nominal transmission time is 18*(9/10), that is, approximately 16 us. In this way, All power related to the resonant coils (6) in all other cooking zones The switching devices (5) have a rated transmission time of 16 µs. driven at the switching frequency. In summary, for different cooking zones, different actual or nominal operating Although their times are calculated according to different power settings, the main coil and main The switching frequency of the cooking zone can be used as common or main frequency. is used. On the other hand, the power switching of the different resonant coils (6) The calculated nominal or actual operating times of the devices (5) To determine a certain working rate for the cooking zone in the figure below is used.

When the maximum operating time of a power switching device (5) is 15 us (i.e. when the relevant resonant coil (6) is not the main coil) and the power of the respective cooking zone When the level of the coil is set from 10” to 7”, which is the highest value, the power of the relevant coil rated conduction time of the switching device (5) as 15*(7/10):11 us is calculated. This value is associated with the corresponding resonant coil (6) for power switching. It is used as the numerator of the ratio that determines the operating rate of the device (5) and the denominator If the induction heater cooktop (l) works safely, a minimum In particular, when the minimum predetermined secure transmission time is 13 us, with a maximum transmission time of 15 ps and a nominal transmission time of 1 1 us the operating ratio of the power switching device (5) is 11/13, ie approximately at a time T Likewise, the power setting selected as 5 out of the highest value 10 and resonance The maximum conduction time of the inductors (6) of the power switching devices (5) is 17 us and for a cooking zone with a nominal conduction time of 17*(5/10)=9, the operating ratio 9/13, the driving frequency is the same as the main cooking zone where the main coil is located. will be the same frequency. As a number greater than 1 when calculated, the corresponding power switching device (5) for the entire time T is being worked.

Thanks to this invention, each piece of cooking surface in a flexible structure The resonant coil (6) is connected to the maximum conduction time of the main coil in the main cooking zone. a common drive determined by the power switching device (5) having energized by frequency. In summary, thanks to this invention, a multi-zone induction coil system will be obtained. Induction resonance powered through an ambient DC bus as multiple resonance inductors (6) associated with their inverters (2), induction resonance driving a power switch that drives the power switching devices (5) associated with its inverters (2) circuit and a pan detection circuit that detects the presence of a ceiling. A hob (1) with an induction heater is realized.

In one embodiment of the invention, a control circuit (12) consists of a) at least two cooking pans. detection of its presence, b) each power associated with the associated resonant coils (6) corresponds to a predetermined maximum current reference of the switching device (5). predetermined current to determine the maximum incoming transmission time a main cooker by energizing all resonant coils (6) according to their reference determination of a main resonance inductor (6) forming part of the region, c) according to a power level setting set for the main cooking zone in question. determining the nominal conduction time of the cooking zone and d) induction to be applied to all resonance inductors (6) located in the heated furnace (1). a medium switching related to the rated conduction time of the cooking zone. performs the task of determining the frequency.

In another embodiment of the invention, the nominal operating time of the main cooking zone proportional to a set power level setting for the main cooking zone is calculated.

In another embodiment of the invention, the control circuit 12 also has different set place in other cooking zones other than the main cooking zone, depending on the power settings. nominal for power switching devices (5) associated with field resonant inductors (6) performs the calculation of working times.

In another embodiment of the invention, the resonance in the main cooking zone power switching of different resonant coils (6) other than coils (6) Calculated nominal operating times of the appliances (5) for each cooking zone It is used to determine a certain working rate for

In another embodiment of the invention, the resonance in the main cooking zone a power switching of the different resonant coils (6) other than the coils (6) The calculated nominal operating time of the device (5), the different resonance the operating ratio of a respective power switching device (5) with respect to its coils (6) It is used as the numerator of a ratio that enables the determination of

In another embodiment of the invention, with said different resonant coils (6) which enables the determination of the operating ratio of the respective power switching device (5) the denominator of the ratio is a predetermined common value. Alternatively, work The denominator of the ratio by which the ratio is determined is the denominator of a resonance inductor (6) is set as the predetermined minimum maximum transmission time.

In another embodiment of the invention, the working rate is expressed as a number greater than 1. when calculated, the corresponding power switching device (5) for the entire time T is being run.

In another embodiment of the invention, a multi-zone induction coil system is obtained. induction resonance fed via an ambient DC bus such that multiple resonance inductors (6) associated with their inverters (2), induction resonance driving a power switch that drives the power switching devices (5) associated with its inverters (2) circuit and a pan detection circuit that detects the presence of a ceiling. used in the operation of an induction heater (l) containing an induction heater, and a) at least. two detection of the presence of the cooking pan, b) associated with the respective resonance coils (6) a predetermined maximum current of each power switching device (5) in advance to determine the maximum transmission time corresponding to the reference by energizing all resonant coils (6) according to the determined current references. of a main resonance inductor (6) forming part of a main cooking zone c) a power level set for the main cooking zone in question determination of the nominal delivery time of the main cooking zone according to the setting and d) to all resonance inductors (6) located in the hob (1) with the induction heater shall be applied to the nominal conduction time of the main cooking zone. a method comprising the steps of determining the ambient switching frequency is carried out.

Thanks to the effective and advantageous method, the subject of the invention can be obtained from the same DC bus. an induction heater with powered induction resonance inverters (2) It is ensured that the cooker is operated by applying a single cooking zone power(` control, each cooking zone is energized at a main driving frequency and Audible noise caused by operating frequencies is suppressed.

Plslrrne Pan Detection of Presence Azamilleiim and AnaPisirrne RegionInDescription Main Cooking Area Nominal Conduct Determining the Time Media Switching Determination of Frequency Nominal Conduct Determining the Timings Working Rates to be determined

Claims (9)

REQUESTS 1) A power switch driving multiple resonant inductors (6) associated with induction resonance inverters (2), power switching devices (5) associated with induction resonance inverters (2) fed via an ambient DC bus so as to obtain a multi-zone induction coil system - detection of the presence of multiple cooking pans, - the maximum conduction time corresponding to a predetermined maximum current reference of each power switching device (5) associated with the respective resonance coils (6) to be determined determining a main resonance inductor (6) that forms part of a main cooking zone by energizing all resonance coils (6) according to current references predetermined in the figure, - determining the nominal conduction time of the main cooking zone according to a power level setting set for the main cooking zone in question, and - to be applied to all resonance inductors (6) characterized by a control circuit (12) which performs the determination of an ambient switching frequency related to the rated conduction time of the main cooking zone. 2) An induction heater hob (l) as in claim 1, characterized by the main cooking zone whose nominal operating time is calculated proportionally to a power level setting set for the main cooking zone. 3) Also, according to the different power settings set, the control circuit (12) is characterized by the control circuit (12), which performs the calculation of the rated operating times for the power switching devices (5) related to the resonance inductors (6) located in the other cooking zones other than the main cooking zone, as claimed in Claim 1 or 4) Claim 3, characterized in that the nominal operating times calculated for the power switching devices (5) of the different resonant coils (6) other than the resonance coils (6) located in the main cooking zone are used to determine a certain operating ratio for each cooking zone. one like a 5) The rated operating time calculated for a power switching device (5) of the different resonant coils (6), other than the resonant coils (6) located in the main cooking zone, is to be calculated from the corresponding power switching device (5) with the respective different resonance coils (6). A hob (l) with an induction heater as in claim 4, characterized by the use of a ratio as the numerator allowing the determination of the working ratio. 6) An induction heater hob (1) as in claim S, characterized by a predetermined common value, the denominator of the ratio that allows the determination of the operating ratio of the power switching device (5) associated with said different resonant coils (6). 7) A hob with an induction heater as in claim 5°, characterized by the use of the lowest predetermined maximum conduction time of a resonance inductor (6) as the denominator of the ratio by which the operating ratio is determined. 8) A cooktop with an induction heater (l) as in claim 6 or 7, characterized by the corresponding power switching device (5) operated during the entire time T, where the operating ratio is calculated as a number greater than 1'. 9) A power switch driving multiple resonant inductors (6) associated with induction resonance inverters (2), power switching devices (5) associated with induction resonance inverters (2) fed via an ambient DC bus so as to obtain a multi-zone induction coil system drive circuit and a pan detection circuit that allows the presence of a pan to be detected. designation of a main resonance inductor (6) forming part of a main cooking zone by energizing all resonance coils (6) according to predetermined current references such that the maximum conduction time corresponding to a predetermined maximum current reference is determined, - a tuned for the main cooking zone in question n of the main cooking zone depending on the power level setting. a method characterized by the steps of determining the nominal conduction time and - determining an ambient switching frequency related to the nominal conduction time of the main cooking zone, which will be applied to all resonant inductors (6).