EP0537796B1 - Cooking oven - Google Patents

Abstract

The oven has a heating resistance in the bottom and in the roof and is cleaned by pyrolysis. It has a temperature detector (31) inside the oven which delivers and electrical signal as input to a microprocessor (17). The microprocessor controls the electrical plower supply to the top and bottom resistances during pyrolytic cleaning. The microprocessor is also programmed so a heating or cooking instruction is automatically preceded by a pre-heating interval.

Description

The invention relates to a cooking oven, in particular of the pyrolysis cleaning type. It relates, more particularly, to a method of controlling the heating of such an oven during cleaning by pyrolysis.

Cooking ovens heated by electrical resistances often have a pyrolysis cleaning position. This cleaning consists in heating the interior of the oven enclosure, using the electric cooking resistors, to a temperature of the order of 500 ° C. in order to burn the organic residues on the walls without, however, degrading the enamel which usually covers such walls.

To carry out the pyrolysis, a catalyst is often used. Furnaces of this type are described, for example, in French patents Nos. 2,365,927 and 2,588,641 in the name of the Applicant.

• le premier seuil est la température de 250°C au-dessus de laquelle le catalyseur devient actif et à partir de laquelle on alimente les résistances à leur puissance maximum, alors qu'au-dessous de cette température la puissance de chauffage doit être limitée afin de minimiser l'émission des fumées résultant d'une combuston incomplète en l'absence de catalyse.

Up to now, pyrolytic cleaning ovens have been quite expensive, in particular because controlling the heating of the oven requires relatively complex electromechanical probes or thermostats. Most often, these electromechanical thermostats have three positions which correspond to three temperature rise thresholds:

• the first threshold is the temperature of 250 ° C above which the catalyst becomes active and from which the resistors are supplied at their maximum power, while below this temperature the heating power must be limited in order to to minimize the emission of smoke resulting from incomplete combustion in the absence of catalysis.

The second threshold is the temperature of 340 ° C, above which standards require that the oven door should no longer be opened;
The third and last threshold is the temperature of 480 ° C close to the maximum admissible temperature and from which the heating power must be limited in order not to risk exceeding the admissible temperature of 500 ° C.

To simplify the production of such a pyrolysis cleaning oven, it has already been proposed to provide the oven with a probe delivering an electrical signal representing the temperature inside this oven and with a microcontroller or the like for controlling the electrical power supplied to the heating resistors, and preferably the locking of the oven door.

The present invention provides a new method for controlling an oven as described above.

Consequently, the subject of the present invention is a method for controlling a pyrolysis cleaning oven as defined in claims 1 to 3.

The probe is, for example, a platinum resistance probe whose accuracy is more or less 3 ° C for temperatures between 60 and 500 ° C.

In the preferred embodiment, the probe and microprocessor, which are used to control the various functions associated with cleaning by pyrolysis, are also used to control the usual operation of the oven, i.e., its operation for cooking. or heating.

It should be noted that the use of an electronic type temperature measurement probe associated with a microprocessor is not incompatible with the use of a type thermostat. electromechanical to control the interruption of electrical power supply to the resistors in the event of failure of the electronic circuit, in particular if an electronic switch, such as a triac, in series with a resistance is short-circuited.

• la figure 1 est un schéma simplifié d'un four de cuisson ;
• la figure 2 est un schéma électrique d'un four selon l'invention, et
• la figure 3 est un diagramme représentant la puissance de chauffage lors d'un nettoyage par pyrolyse.

Other characteristics and advantages of the invention will appear with the description of some of its embodiments, this being carried out with reference to the attached drawings in which:

• Figure 1 is a simplified diagram of a cooking oven;
• FIG. 2 is an electrical diagram of an oven according to the invention, and
• FIG. 3 is a diagram representing the heating power during cleaning by pyrolysis.

In the example, the baking oven 10 (FIG. 1) conventionally includes a vault (or grill) resistance 11 and a hearth resistance 12 making it possible to cook food placed on an intermediate shelf 13.

In this example, only one vault resistor 11 and one sole resistor 12 are provided (FIG. 2).

Resistors 11 and 12 are supplied in parallel by the AC power sector. Resistor 11 is in series with a triac 15. Likewise, resistor 12 is in series with a triac 16.

The conduction of the triacs 15 and 16 is controlled by a microprocessor 17. For this purpose, an output 17₁ of the microprocessor 17 is connected to the trigger of the triac 15 via an interface circuit 18. Similarly, an output 17₂ is connected to the trigger of the triac 16 via another interface circuit 19.

Furthermore, the microprocessor 17 has inputs 17₃, 17₄, 17₅, ... to which are applied binary signals representing addresses of programs in memory of the microprocessor 17.

The output 17₁ controls the conduction of the triac 15 in such a way that at each alternation of the AC sector (at frequency 50Hz) the triac is conductive for a time chosen as a function of the power which it is desired to have delivered by the resistor 11. This fraction of the duration of each alternation during which the resistor 11 is supplied is determined by the program in the microprocessor 17.

Similarly, the programs of the microprocessor 17 control, by the output 17₂, the duration of conduction of the triac 16 at each alternation of the alternating current of the sector.

The inputs 17₃, 17₄ and 17₅, associated with keys, respectively 20, 21, and 22, allow preprogrammed operations, as will be seen below.

Furthermore, the microprocessor has an input 17₇ to which is applied, via an interface circuit 30, an electrical signal supplied by a thermocouple probe 31 which represents the temperature inside the enclosure of the oven 10 The probe 31 is arranged inside this enclosure.

Another input 17₈ of the microprocessor 17 receives, via an interface circuit 32₁, a signal supplied by a variable resistor 32, or coding wheel, which represents the temperature desired by the user. The display of this setpoint temperature is carried out by an actuating member located on the control panel of the cooking appliance.

An output 17₉ of the microprocessor controls, via an interface circuit 33₁, a latch 34 for automatically locking or unlocking the door (not shown) for access to the oven. The circumstances under which such locking occurs will be described later.

The microprocessor has two other inputs 17₁₀ and 17₁₁. The input 17₁₀ is connected to a variable resistor 25, or a coding wheel, via an interface circuit 25₁. The microprocessor converts the value of the adjustable resistor 25 into a conduction time of the triac 15 at each alternation of the sector. The value of the resistor 25 is determined by the user, for example with the aid of a rotary button or of a cursor with linear displacement, as a function of the power supply that he desires for the resistor 11.

Similarly, the input 17₁₁ of the microprocessor 17 is connected to a variable resistor 26 (or coding wheel) via another interface circuit 26₁. Resistance 26 plays, with respect to triac 16, the same role as that played by resistance 25 with respect to triac 15.

In one example, the commands on the inputs 17₃, 17₄ and 17₅, which represent preprogrammed commands, have priority over the commands on the inputs 17₁₀ and 17₁₁.

FIG. 3 shows a diagram corresponding to the program associated with the input 17₃ which is intended to control cleaning by pyrolysis. The time t is plotted on the abscissa and the temperature T is plotted on the ordinate.

Diagram 50 therefore represents the variation of temperature T in degrees C as a function of time t.

As long as the temperature inside the enclosure, detected by the probe 31, is less than 180 ° C, the power supplied to the resistors 11 and 12 is maximum, that is to say that the triacs 15 and 16 are, during each alternation in the sector, permanently conductive. From this temperature of 180 ° C. fumes and carbon monoxide CO may be released due to incomplete combustion, and this all the more so at this temperature the catalyst (not shown) generally provided in the cooking chamber ceiling, is not yet active. Under these conditions, once the temperature in the enclosure has exceeded 180 ° C (at time t₁), the microprocessor controls a reduction in the power supplied to the resistors, in particular to the sole resistor 12, as described in the French patent. No. 2,588,641 in the name of the Claimant. In this way, as long as the catalyst is not primed, the organic waste which is usually found in the lower part of the oven, is not burnt.

Then (at time t₂) when the temperature of 250 ° C, detected by the probe 31, is reached, the program again controls the power supply at full power of the resistors 11 and 12 in order to quickly reach the temperature of 500 ° C. From this temperature of 250 ° C, the catalyst is active and there are therefore practically no more CO and smoke emissions.

However, before the temperature of 500 ° C is reached, the microprocessor delivers when the temperature of 350 ° C has been reached (at time t₃), a signal on its output 17₉ which actuates the latch 34 to prevent the opening of the oven access door. This lock 34 remains closed as long as the temperature is above 350 ° C.

When the temperature of 500 ° C or a slightly lower temperature (for example 480 ° C) is reached (at time t₄), the power supplied to the resistors decreases significantly in order to limit the risk of exceeding this temperature of 500 ° C . The microprocessor then controls, for a time determined by its program, the maintenance of the supply of the resistors 11 and 12 so that the temperature remains at the value of 500 ° C. The operation is stopped automatically, this stop also being controlled by the microprocessor 17.

The probe 31 also intervenes during the normal operation of the oven, that is to say when recourse is made to specific cooking programs in the memory of the microprocessor and which are triggered by actuation of the keys 21, 22, etc., or when the potentiometers 25 and 26 are directly controlled, the power supplied to the heating resistors 11 and 12.

Claims (3)

1. Method for controlling an oven having pyrolysis cleaning, of the type comprising at least one bottom resistive element (12), a grill resistive element (11), a microprocessor (17) controlling the power supplied to the resistive elements, a probe (31) for measuring the temperature within the oven, which delivers a signal to the input (17₇) of the microprocessor and a catalyst which is active above a defined temperature which is lower than the maximum pyrolysis operation temperature, characterized in that, during the pyrolysis cleaning:

   - the resistive elements are first supplied to a maximum power until a temperature T1 is obtained within the oven which is less than the defined temperature above which smoke and carbon oxide risk being released;

   - the supply power of the resistive elements is then decreased until the defined catalyst activation temperature is obtained, and

   - the resistive elements are again supplied to the maximum power until the pyrolysis temperature is obtained.
2. Method according to Claim 1, characterized in that the microprocessor sends to an output (17₉) a control pulse for locking (34) the door for access to the oven when the temperature in the chamber exceeds a defined value.
3. Method according to one of the preceding claims, characterized in that the probe is a platinum resistor probe with +3°C precision for temperatures lying between 60 and 500°C.

Images