FR2466932A1 - INDUCTION HEATING APPARATUS, WITH DETECTOR OF THE HEATING OBJECT - Google Patents

Abstract

Induction heater. Apparatus characterized by a switch 3 controlled from a detector 15 detecting the presence of an object 11 on the plate 10 above the winding 6 and a load detector 19 detecting the weight of the object 11 to control the power supply of the winding 6 when the detectors 15, 19 detect the presence of an object to be heated. The invention relates to household appliances. (CF DRAWING IN BOPI)

Description

-2466932

  The present invention relates to an induction heating apparatus and in particular a cooking appliance and

  in particular a device that is easy to use.

  Induction heaters have recently been proposed for cooking. In such an induction heater, an object such as a stove or the like of a magnetic material to be heated is placed in the magnetic flux

  generated by a coil which is fed by an alternating current

  native, so as to generate eddy currents in the object, to heat it in this way. In this cooking appliance, the object such as the pogle or the like that one wants to heat, is placed on a top plate, made of a material

  non-magnetic, to be heated according to the indications

  above. In this cooking appliance, the upper plate itself

  even is not heated that is to say that its temperature does not rise, which reduces the risk and is advantageous for

Security.

  In the induction heater, above used for cooking, when a pan for example of a non-magnetic material is placed on the top plate, there is no eddy current inside the unit. the stove so that the pan does not heat, even if the coil is powered by alternating current. This entails a consumption

  unnecessary current. In addition, there is the risk in this

  cooking wire, that if a fork or other element of a magnetic material, which must not be heated, is accidentally put on the top plate, it heats and may be damaged. To remedy this danger, there is provided a magnetic material detection circuit and a charge detection circuit, in the known cooking apparatus. This magnetic material detection circuit is for example constituted by a magnet placed under the upper plate, and which detects the nature of the material which is on the upper plate, to check whether this material is magnetic or not, then controls the circuit so that it does not supply any current to the winding, if the detected material is a material not

  magnetic; by cortre, it gives a search signal depending on

  In the case of detection, the current is supplied at the end of a short period of time when the substance is present. The load sensor detects the size of the load or object placed on the top plate during the above period, for example by detecting amplitude, work cycle, or the like. current flowing through a switching element of an inverter giving the alternating current supplying the winding. If the load or object on the upper plate is detected or is considered by detection as a light load, i.e. a small load such as a spoon, a small utensil or the like, the inverter is inhibited , not to provide

current to the coil.

  The magnetic material detector and the load sensor fitted to the cooking appliance make it possible to remedy the drawbacks mentioned above. However, if the pan is made of a magnetic material and placed in a corner of the top plate, and not in the normal position, that is to say in the center, the magnetic material detector finds that the pan is in a magnetic material and it creates a search signal. Then the load detector detects the size of the load. At this time, however, the charge detector thinks that the charge is small or light and does not control its heating. However, the user can not know if the stove is heating or not. Even if it later finds that the pan is not heated because it is not placed in the normal position on the top plate, or that the pan is moving from its normal position on the top plate, the sensor of magnetic matter no longer creates the search signal and no longer carries out the detection of the load. It is

  why, even if we correct the position of the pan on the

  that, higher, this pogle does not heat up.

  In addition, as the detection of the load is carried out for a short time, it is possible that even if the pan is normal or magnetic material, and has normal dimensions, being placed on the top plate in the

  normal position, the detector does not detect this as a condition

  the pan does not heat up.

  The present invention aims to create an induction heater, usable for cooking, overcoming the drawbacks of known solutions, for effectively heating a product, normal, intended to be heated, and having a means for emitting a signal d alarm when the object that one wants to heat is placed on the plate

top of the device.

  For this purpose, the invention relates to a device

  inductive heating element for cooking, this apparatus

  characterized in that it consists of a flat support plate on which the object to be heated is placed, an induction heating coil, under the support plate to generate a magnetic flux for heating the object,

  a signal generator comprising a switch for

  ter a continuous signal, rectified from an AC signal and create a signal supplied to the induction heating coil, a drive signal generator to create a drive drive signal, a gate connected between the generator drive signal and the switch, for controlling the passage of the driving signal, a detector for detecting whether the object placed on the support plate is of a magnetic material or not and for creating an output signal, a generator of search pulses controlled by the detector output and to create a search pulse controlling the gate, a charge detector for detecting the charge for the signal generator and creating an output signal controlling the gate with the search pulse , as well as a generator

  of a periodic signal controlled by the output signal of the

  charge generator and to generate a periodic signal supplied to the search pulse generator, so that it generates the search pulse at a speed corresponding to the

frequency of the periodic signal.

  The present invention will be described in more detail with the aid of the accompanying drawings, in which: - Figure 1 is a block diagram of an example of an induction heater used for cooking,

according to the invention.

  FIGS. 2A-2D and 3A-3E are chronograms

  explain how the example of reali-

according to Figure 1.

  DESCRIPTION OF PREFERENTIAL EMBEDDING OF THE INVENTION

  The description below relates to a device for

  heating and induction according to the invention.

  Zieyure 1 is an example of a device for use in ls; This appliance has a plug 1 intended to be connected to a socket of

  network. Plug 1 is connected by a fuse 2 and switches

  3a, 3b at the input of the rectifier 4 whose output terminal

  positive voltage 4a is connected to the voltage output terminal.

  4b negative by the series connection formed by an arresting coil 5 for stopping the passage of high signals

  frequency, an induction heating coil 6 and a condenser

  7 to avoid resonance. The junction point of the arresting coil 5 and the network 6 is connected to the cathode of a damping diode 8, the anode of which is itself connected to the negative voltage terminal 4b as well as to the anode of a controlled door switch, 9 constituting the switching element providing a high frequency alternating current applied to the induction heating coil 6. The cathode of the element 9 is

  it itself connected to the voltage output terminal. negative 4b.

  Above the winding 6 is a top plate 10, flat support, made of a material not

  magnetic. An object 11 such as a pogle in a magnetic material

  tick, which one wants to heat up is placed on the plate superior

  10. When element 9 provides an alternating current to the

  bearing 6, this current generates a magnetic flux. If the pan 11 of magnetic material is placed on the top plate 10 in a correct or normal position, eddy currents appear in the pan 11 which is heated as in the prior art. In the assembly of FIG. oscillator 12 generates a rectangular signal of frequency for example equal to KHz and whose working ratio is equal to 50%. The oscillating signal supplied by the generator is applied to one of the input terminals of an AND gate 13 whose output signal passes through the deenergising circuit 14 to drive the door of the element 9, and to control the on state or off state,

at high frequency.

  There is provided a magnetic switch 15 which detects whether the material or object placed on the top plate

  is or is not in a magnetic material. This magnetic switch

  15 is made to give a high level signal "1" when the material placed on the top plate 10 is made of a magnetic material, while it gives a low level signal "0" when it comes of a non-magnetic material, the output signal of the magnetic switch 15 is applied to one of the

input terminals of an AND gate 16.

  An alarm oscillator 17 gives a signal

  a period equal for example to 1.45 seconds and a working ratio of 50%. The output signal provided by this oscillator is applied to the other input of the AND gate, 16 by a frequency divider 18 dividing by 21 The alarm oscillator 17 is designed so that it always oscillates except when the power supply is connected and a load detector 19 described later gives a high level signal "1" at its output, that is to say when a normal object such as a pogle 11 or other, The output signal of the alarm oscillator 17 is also applied to the light alarm generator 20 which has a light emitting diode or a light emitting diode.

  analogue, illuminating in synchronism with the oscillation signal

  The oscillation signal of the alarm oscillator 17 is further applied to one of the input terminals of the AND gate, which also receives on its own.

  another input the output signal of the AND gate, 16 by the invert-

  22. The output signal of the AND gate 21 is applied to a sound alarm generator 23 which is for example a sound-emitting buzzer only if the output signal of the AND gate 21 is a high level signal. In these circumstances, the

  the sound volume of the alarm can be adjusted using the

  variable speed 24 connected to the device 23.

  The output signal of AND gate 16 is also

  applied to the trigger terminal of a monostable multivibrator 25 which then gives a search signal. The output signal is applied to one of the input terminals of the OR gate, the output of which is connected to the terminal D of a type D flip-flop 27; the terminal Q of this flip-flop is connected to the other

  input terminal of the AND gate 13. The time constant of the

  monostable tibibrator 25 is for example chosen equal to 120 milliseconds and the output signal of this multivibrator constitutes the research signal

  It is. a pulse generator of syn-

  CINOnis-atiOfi *. 1-- liale.on 28 which is connected to card 1 by

  i 'inter-e> Z. 50-: a-t-. have: 3a to give an impulse signal

  The method is applied to the clock input terminal C of the D-type flip-flop 27. The junction point between the choke coil 5 and the winding 6 is also connected to the input of the charge detector 19 which detects the period of time during which the damping diode 8 is conductive, and then detects whether the material of the object placed on the top plate 10 is a light charge. that is, a small item such as a spoon, fork, or the like that should not be heated or if it is a normal load such as a pogle 11. The charge detector 19 provides a high level signal "1" when the normal charge such as the stove 11 is put on the upper plate 10, against, the detector 19 provides a low level signal "0" when other objects to be heated, are placed on the upper plate 100 The output signal of the charge detector 19 is applied to the other terminal the input of the OR gate 26 and the oscillation control terminal of the alarm oscillator 17 via an inverter 29. The alarm oscillator 17 is made of

  way that it does not oscillate when the output signal of the

  load driver 19 is a high level signal "1".

  The invention being carried out as indicated above,

  when a habitual pogle He in a magnetic material, des-

  heated, is placed on the top plate 10, the magnetic switch 15 gives a high level output signal "1"; the output signal of the charge detector 19 is then a low level signal "0", at the moment when closing

  the power switches 3a, 3b. At this moment, the oscilla-

  alarm 17 oscillates and generates at the output an oscillating signal shown in FIG. 2A. As this oscillating signal is applied to the divider 18 which divides the frequency by two, at its output a signal 18a is obtained whose period is for example equal to 1.9 seconds (FIG. 2B). This signal 18a drives the other input terminal of the AND gate, 16, so that this gate 16 outputs the signal shown in FIG. 2B. The signal of the AND gate, 16 is applied to the monostable multivibrator 25 to trigger it and output a pulse signal 25a whose period is for example equal to 120 milliseconds (Figure 3A). The pulse signal 25a is applied by the OR gate 26 to the terminal D of the D-type flip-flop 27 to provide on its Q terminal a high level signal "1" which is applied to the other input terminal of the AND gate 13. The output signal of the oscillator 12 is thus applied by the AND gate 13 and the bias circuit 14 to the gate of the element 9 so that the winding 6 generates the magnetic flux necessary for induction heating. . At this time, as the normal stove 11 that is to be heated, is on the upper plate 10, the load detector 19 gives its output a high level signal "1" (Figure 3C) which is applied by the inverter 29 to

  the alarm oscillator 17 to stop the oscillation.

  At the same time the high level signal "1" of the charge detector 19 is applied by the OR gate 26 to the D terminal of the S-type flip-flop 27, so that a signal which is added to those of the figures 3A, 3C, as shown in FIG. 3D, is applied to terminal D of flip-flop 27 of type D; the flip-flop 27 gives on its output terminal Q a signal applied to the other input terminal of the AND gate 13. The oscillating output signal of the oscillator 12 is thus applied by the AND gate 13 and the circuit 14 at the door of the element 9, permanently, so that the winding 6 continues heating by induction or loss of eddy current

  in the stove 11 under the effect of the magnetic flux of the coil

  6, so as to heat the shell 11. As the pulse synchronized on the network for example at 50 Hz (Figure 3B) is applied to the terminal C or clock terminal of the flip-flop 27 by the generator 28, its output on terminal Q goes low

  "0" in synchronism with the network current.

  If a small element, such as a spoon, fork or the like in a magnetic material, but small in size compared to that of a usual stove 11 and must not be heated, is put on the plate 10 above, the magnetic switch 15 provides a high level signal "11", similar to what occurs for a normal stove 11. at this time: as the alarm oscillator 17 oscillates, it is obtained at the output of the monostable multivibrator the search signal o5a (FIG. 3A) which is applied by the door OMi 26 to the terminal D of the flipslop 27 of the D type.

  b Q, it, pat to; high level "l" which is applied

  .! 1 C. d! ? Is it, so is T 13 and so is the air barrier or the door?

  AND 13 and the drive circuit 14 to the door of the element 9.

  At this moment, the charge detector 19 outputs a low level signal 'O', since a small element, which

  should not be heated, is on the top plate 10.

  The alarm oscillator 17 thus continues to oscillate and its output signal is applied to the other input terminal of the AND gate 16. As the output signal of the AND gate 16 goes high '"", after that, for example after 2.9 seconds, the monostable multivibrator 25 begins to provide the search signal 25a again (FIG. 3E) and performs an operation

  load sensing as indicated above. Then, the opera-

mentioned mention is repeated.

  At this time, the output signal of the alarm oscillator 13 is applied to the light alarm generator 20 which emits light in synchronism with the output signal

of the alarm oscillator 17.

  At the same time, at the output of the AND gate, 16, the signal represented in FIG. 2B is derived, so that the signal applied to the other input terminal of the AND gate, 21 is the signal which is the inverse to that applied to the output of the AND gate, 16 (FIG. 2C) because of the inverter 22. As the output signal of the alarm oscillator 17 (FIG. 2A) is applied to a terminal of FIG. input of the AND gate 21, this AND gate 21 passes half of the impulsiohnel output signal of the alarm oscillator 17 (Figure 2D). The pulse signal of the AND gate 21 is applied to the sound alarm generator 23 which repeatedly emits a given sound signal whose period is twice that of the alarm oscillator 17. In other words, when a small, small charge, such as a spoon or fork or the like, which must not be heated, is on the top plate 10, the light emits intermittently and at the same time the device emits a signal whose period is double that of

the emission -luminous.

  In addition, if the first detection made by the charge detector 19 is false, the operation is performed by the second, the third ... search signal as in the case of a normal stove set up. One can also correct a wrong maneuver. In addition, when the charge detector 19 makes a false detection or assessment that the normal pogle is not in a correct position on the top plate, even if the pogle is in the correct position on the top plate, the signal from

  search 25a is transmitted in sequence according to a given period.

  we can correct the wrong maneuver. Under these conditions, the period of the search signal is determined by the oscillation frequency of the alarm oscillator 17. However, the period and duration of the search signal are chosen so that a small piece such as a spoon, fork or the like is not

  heated during this period and this time interval.

  When a pogle or other, non-magnetic material is placed on the top plate 10 or there is no filler material on the top plate 10, the magnet magnet 15 gives a low level signal. O ". This is why the output signal of the AND gate 16 is a low level signal "O" and at this point the circuit provides no search signal. As a result, the output signal of the detector

  19 is always a low signal "O" and the oscillator

  alarm 17 continues its oscillation. The other input terminal of the AND gate 21 continues to receive a high level signal "1" and an input terminal of the AND gate 21 receives the output signal of the alarm oscillator 17. As the light alarm generator 20 emits a flashing light, the sound alarm generator 23 emits the audible signal, repeated in synchronism with the flashing light. This situation is thus detected in which no load or non-magnetic material is on the top plate 10 or a part made of a magnetic material but of small size by

  comparison with a normal product (and do not heat

  iron) is on the top plate 10.

  In the above example, according to the invention, the flip-flop 27 of the D type is clocked in synchronism with the AC power supply so that if the AC supply voltage is zero, it can be stopped. signal provided by the element 9. There is in these conditions no risk that an exceptional voltage, increases at the stop of the signal dl estitation0 Co'iÉté d ", crit fç: i & asuse se tone In the invention, even if there is a search signal for debiting the load and this charging detection is false for any reason, the search signal is again provided after a predetermined period of time. so no difficulty

in practice.

  Furthermore, according to the above example of the invention, it is detected or discerned whether the charge is of small size or if it is in a non-magnetic material, so that

  the use of the installation is interesting in practice.

  In the above example of the invention, the volume of the alarm sound signal can be adjusted appropriately by controlling the variable resistor 24 as described above, so that it is not inconvenient for a person when the device is used in a quiet atmosphere, since the volume of the sound

choice of the user.

l1

Claims (4)

  1) An induction heating apparatus, in particular for cooking, an apparatus comprising a flat support plate, on which the object to be heated is placed, an induction heating coil being placed below the support plate to generate a heating element. magnetic flux for heating the object, characterized in that it comprises a signal generator comprising a switch (9) for controlling a rectified DC signal obtained from an AC signal, and for creating a signal applied to the inductive heating coil (6), a drive signal generator (12) creating a drive signal for the switch (9), a connected gate (13) between the drive signal generator (12) and the switch (9), for controlling the passage of the drive signal in the gate (13), a detector (15) for detecting whether the object placed on the support plate (10) is of a material   magnetic or not and to give an output signal, a gen-   search pulse controller (25) controlled by the detector output to create a search pulse controlling the gate (13), a charge detector (19) for detecting the charge for the signal generator and providing an output signal controlling the door at the same time as the search pulse, as well as a periodic signal generator (17) controlled by the output of the charge detector (19) to create a periodic signal applied to the search pulse generator (25) of way that the search pulse generator gives the search pulse at a speed corresponding to the frequency of the periodic signal.   2) Apparatus according to claim 1, characterized in that the search pulse at the output of the charge detector is applied to the OR gate (26) whose output control the door (13).   3) Apparatus according to claim 2, characterized in that the output of the OR gate is applied to a flip-flop (D 27) which is controlled by a synchronized signal on the AC signal and the output signal of the flipsflop (D). order the door (13).   4) Apparatus according to claim 1, characterized in that the output of the detector e-t periodic signal are 4'O al, .ql s. an AND gate at the output con-controls the generator iGi-; e p-orte 2 2466932   -12-) Apparatus according to claim 1, characterized   in that the periodic signal is applied to an indi-   the object placed on the support plate must not be To be heated.