EP2445311A2 - Combination cooking device - Google Patents

Abstract

The cooking appliance contains a cooking chamber (1,3) for receiving the to-be-cooked item, a steam generator (2,4) for supplying steam into the cooking chamber and a microwave generator (31) for heating oven containing to-be-cooked item. The steam is escaped from the cooking chamber by forming openings (11,14) in cooking chamber. The temperature of opening is measured by temperature sensor (18) from the cooking chamber vapor. The microwave generator is controlled by controller (24) depending on the measured value. An independent claim is included for method for operating cooking appliance.

Description

Field of the invention

The invention relates to a cooking appliance for cooking food and a method for operating a cooking appliance.

background

Steam cooking appliances are becoming more and more popular if they are cooked in the same way. In this case, a cooking chamber steam is supplied to heat the cooking chamber and the food therein.

Presentation of the invention

The object of the invention is to provide a cooking process and a cooking appliance, which further develop the steam cooking operation presented, so that the cooking time is reduced and / or the cooking result is improved.

The object is achieved by cooking appliances having the features of patent claims 1 and 4 and by methods for operating cooking appliances according to the features of patent claims 11 and 12.

According to a first aspect, the cooking appliance has a cooking chamber for receiving a food item. Cooking in the context of this invention is intended to include all types of heating of the food, ie heating, heating, as well as the thawing of food, food, liquids, etc .. The cooking chamber is typically a one-sided open hollow body, in the context of ovens also muffle called, whose open side can be closed with a door is. Furthermore, a steam generator is provided, which allows a supply of steam, in particular steam, into the cooking chamber. In this case, external steam generators are included, which generate steam outside the cooking chamber, which steam is then introduced via a supply line into the cooking chamber. The claimed steam generator should also include internal steam generators, in which the steam within the cooking chamber, for example by heating water, is generated.

Furthermore, the cooking appliance has an opening in the cooking chamber, which allows the escape of steam from the cooking chamber. This opening is therefore to be understood in particular as an opening provided in addition to the door opening, which allows an escape of steam even when the door is closed. Such an opening may for example have an approximately coin-sized cross-section.

In addition to the steam generator, a microwave generator is provided for heating cooking food received in the cooking chamber. By providing two different types of heating for the food to be cooked, the present cooking device is a so-called combination device. Furthermore, a controller is provided, preferably an electronic controller for the operation of the cooking appliance. Among other things, this controller receives the signal from a sensor that measures a parameter of steam exiting the orifice. This parameter may be the temperature of the exiting vapor in the event that the sensor is designed as a temperature sensor. This parameter may be the flow of the exiting vapor in the event that the sensor is designed as a flow sensor. This parameter may be the pressure of the exiting vapor in the event that the sensor is designed as a pressure sensor. This parameter may be the moisture of the exiting vapor in the event that the sensor is designed as a humidity sensor. The sensor may be a combined sensor of two or more of the preceding individual sensors and thus support its measurement result on two or more different physical parameters.

Preferably, the sensor is arranged at the opening itself or in an extension of the opening, also called mouth, which extension connects the cooking chamber with an outside space outside the cooking chamber. The sensor can be arranged on an inner wall or on an outer wall of the extension for measuring the parameter. However, the sensor can also be arranged, for example, in the cooking chamber itself near the opening. There, too, he can measure a parameter of steam exiting through the aperture. In this case, the sensor may be arranged, for example, within a radius of at most 5 cm around the opening.

According to a further aspect of the invention, a cooking device for cooking food to a cooking chamber for receiving the food and a steam generator for supplying steam into the cooking chamber. A sensor is now provided for measuring a parameter of steam in the cooking chamber. In turn, a microwave generator is provided for heating the cooking product received in the cooking chamber. A controller controls the microwave generator depending on the parameter measured by the sensor.

In this case, instead of an indirect measurement of the vapor saturation in the cooking chamber, a direct measure of the vapor saturation in the cooking chamber is recorded by measuring a parameter of steam exiting from the cooking chamber. This can be done, in particular, by a moisture sensor arranged in the cooking chamber, which receives, for example, a relative humidity in the cooking chamber. An opening in the cooking chamber for steam outlet may preferably still be present.

• Ein Einschalten des Mikrowellengenerators;
• Ein Ausschalten des Mikrowellengenerators;
• Ein Erhöhen der Leistung des Mikrowellengenerators;
• Ein Erniedrigen der Leistung des Mikrowellengenerators;
• Ein Bestimmen einer Zeitdauer des Betriebs des Mikrowellengenerators;
• Ein Verlängern einer Zeitdauer des Betriebs des Mikrowellengenerators;
• Ein Verkürzen einer Zeitdauer des Betriebs des Mikrowellengenerators;
• Eine Auswahl eines Mikrowellenprogramms; o.ä.

The controller in turn controls the microwave generator in both aspects depending on the parameter measured by the sensor. For example, the control may cause one or more of the following actions:

• Turning on the microwave generator;
• Turning off the microwave generator;
• Increasing the power of the microwave generator;
• Lowering the power of the microwave generator;
• Determining a duration of operation of the microwave generator;
• Prolonging a period of operation of the microwave generator;
• Shortening a period of time of operation of the microwave generator;
• A selection of a microwave program; etc.

• Ein Überschreiten eines Schwellwerts durch den gemessenen Parameter - welcher Parameter typischerweise als Sensorsignal vorverarbeitet und an die Steuerung übertragen wird;
• Ein Unterschreiten eines Schwellwerts durch den gemessenen Parameter;
• Ein Über- oder Unterschreiten eines Schwellwerts durch einen Gardienten des gemessenen Parameters;
• Einem Muster im gemessenen Parameter, o.ä.

The controller may be formed in advantageous developments for controlling the microwave generator depending on one or more of the following events, also called trigger events or trigger events:

• Exceeding a threshold by the measured parameter - which parameter is typically preprocessed as a sensor signal and transmitted to the controller;
• Below a threshold value by the measured parameter;
• Exceeding or falling below a threshold by a guardian of the measured parameter;
• A pattern in the measured parameter, or similar.

The addition of the microwave function in response to the steam escape signal shortens the cooking time; switching off the microwave function as a function of the steam outlet signal prevents cooking of the food. Typically, the sensor will indirectly indicate the degree of steam in the cooking chamber, as the more steam is in the cooking chamber, the more steam will escape through the orifice. On the other hand, hardly Steam out through the opening, when only a little steam in the cooking chamber or only a little steam was supplied to the cooking chamber. The quantitative detection of the exiting vapor may depend on the pressure conditions that prevail at the outlet of the opening and other factors that determine the internal pressure in the cooking chamber.

In this respect, the cooking process and the cooking result can be improved: For example, in a first mode of operation with a microwave addition can be waited until at least a certain vapor level is reached in the cooking chamber, assuming that the steam primarily acts as a transfer medium for the microwave to the sensor so that the microwave generator can be operated with better measurability with the prior addition of steam. A better energy intake by the food may be the result. In addition, the power distribution can be improved and local drying of the food can be prevented. In this respect, for example, in this first operation, cooking can be started with a pure steam cooking operation. If, for example, the sensor, which is designed here as a temperature sensor, indicates a certain temperature of the exiting vapor, which temperature exceeds a first threshold value, the microwave current generator is switched on when this first threshold value is exceeded.

In a second exemplary mode of cooking of the food is achieved primarily by steaming. The addition of microwave is only intended to accelerate steam cooking by adding the microwave function, either from the start of steam cooking, or when a certain cooking level has already been achieved and, accordingly, the temperature at the sensor exceeds a second threshold. Here is the microwave addition serve for a time reduction of cooking. On the other hand, a microwave feed for the cooking result is advantageous because the food to be cooked by the Mirkowellenbeigabe is heated in particular in its interior, whereas the steam cooking acts on the food from the outside. Also, the microwave in the second mode of operation, for example, remain switched on only for a short period of time, possibly with maximum power.

The invention thus combines the steam cooking and the microwave cooking advantageously by the control of the microwave generator via a size representing the steam outlet from the cooking chamber. It has been found that this way the food can be heated faster and / or warmer, and that the food does not dry out too quickly. The residual water surplus can also be reduced by the proposed methods.

Preferably, the steam cooking can be done in combination with the addition of hot air. All the above operating modes can also be used for regeneration.

The proposed operation of the cooking appliance can preferably be triggered by the selection of a specific cooking program via a selector switch. Such an election program may explicitly refer to combined steam and microwave cooking. Alternatively, the proposed operation may always be performed when one of the cooking programs "steam cooking" or "microwave cooking" is selected by the user. Such operation may also be activated by the user during a conventional cooking program, for example, by the operation of an option key. The proposed operation can also be activated automatically if, independently of the cooking program, either the steam generator or the microwave generator is activated. Preferably, the proposed operation can be activated even if the microwave generator and the steam generator are activated simultaneously.

According to a further aspect of the invention, a method for operating a cooking appliance for Cooking food, feeding steam generated by a steam generator into a cooking space, measuring a parameter of steam exiting through an opening from the cooking space, and controlling a microwave generator depending on the measured parameter.

According to another aspect of the invention, a method of operating a cooking appliance for cooking food comprises supplying steam into a cooking chamber, measuring a parameter of steam in the cooking chamber, and controlling a microwave generator depending on the measured parameter. Here, again, preferably the moisture in the oven is measured.

Advantageous developments of the invention are characterized by the subclaims.

Further developments, which are expressly disclosed in connection with the cooking appliance, are also to be regarded as disclosed belonging to the method, and vice versa.

Brief description of the drawings

• Fig. 1 einen Querschnitt durch ein Gargerät nach einem Ausführungsbeispiel der Erfindung, und
• Fig. 2 eine schematische Illustration eines Gargeräts nach einem weiteren Ausführungsbeispiel der Erfindung.

Further embodiments, advantages and applications of the invention will become apparent from the dependent claims and from the following description with reference to FIGS. Showing:

• Fig. 1 a cross section through a cooking appliance according to an embodiment of the invention, and
• Fig. 2 a schematic illustration of a cooking appliance according to another embodiment of the invention.

Way (s) for carrying out the invention

The cooking appliance according to Fig. 1 comprises a cooking chamber 1, which is bounded by walls 2 and a door 3. The cooking space may for example comprise 50 liters and more, for example, 56 liters. The cooking appliance shown can be operated at least both as a steam cooker, as a microwave oven and as a combined Dampfgar- / microwave oven. The cooking appliance includes a schematically drawn and separated from the cooking chamber 1 steam generator 4, the steam is supplied to the cooking chamber 1 via a supply line. A microwave generator with the reference numeral 31 is arranged schematically in the ceiling of the cooking chamber 1 and may for example provide a maximum power of 700 watts. The cooking appliance can optionally also be operated as an oven, for which, in an advantageous development, it contains a conventional resistive heater with top heat 5a and bottom heat 5b. Alternatively or in addition to the heater 5a, 5b, the cooking appliance may also be equipped with hot air or with a grill radiator.

Outside the cooking chamber 1, a fan 6 is arranged as a fan, for example a cross-flow fan. The fan 6 conveys air from a suction area 7 in a pressure chamber 8. From the pressure chamber 8, the conveyed air passes through a front outlet opening 9 of the device in the environment. The pressure chamber 8 is bounded above by an inclined cover plate 10 and down through an inclined bottom plate 11, such that the pressure chamber 8 preferably tapers towards the outlet opening 9. Laterally, the pressure chamber is closed by side walls (not shown). The cover plate 10 and the bottom plate 11 may, for example, but also be guided approximately parallel to each other. Other design variants are conceivable.

In the ceiling of the cooking chamber 1, an opening 14 and a further opening 20 are arranged. The further opening 20 has a diameter of about 2.5 cm, the opening 14 is preferably smaller. The cooking appliance has a device for measuring a steam outlet from the Cooking chamber 1. This device comprises the opening 14, which serves as a measuring opening and leads from the cooking chamber 1 into the interior 15 of a protective housing 16. The protective housing 16 is arranged in the pressure chamber 8 and communicates with this via a connection opening 17. The connection opening 17 is located on the side facing away from the fan 6 of the protective housing 16. In the protective housing 16 is further at the mouth of the opening 14, a temperature sensor 18, for example in Formed an NTC resistor, which measures a temperature Tx. The opening 14 is preferably always open.

During operation of the cooking appliance, the fan 6 is preferably permanently in operation. It sucks in air through openings in the rear wall and in the side walls of the cooking appliance from the environment. This air passes through the suction area 7, is blown into the pressure chamber 8 and leaves it through the outlet opening 9. Since the pressure chamber 8 tapers towards the outlet opening 9, a slight overpressure arises in the pressure space 8, ie. a pressure higher than the ambient pressure while the pressure in the suction area 7 is lower. This must prevail in the cooking chamber 1 a certain overpressure, so that a temperature increase can be detected at the temperature sensor 18, which can close to a gas / steam outlet through the opening 14. Another task of the fan 6 is to remove the air, which has warmed on the outside of the cooking chamber 1, to the outside for cooling the cooking appliance.

For controlling the steam generator 4, the microwave generator 31 and other components of the cooking appliance, a controller 24 is provided, which among other things monitors the temperature signal output by the temperature sensor 18. The steam generator 4 is basically controlled as follows: If a cooking operation is set by the user on an operating unit, for example in the form of a selector switch, which at least includes steaming, the steam generator 4 is switched on and the generated steam supplied to the cooking chamber 1. Due to the above, the escape of the steam from the cooking chamber 1 is difficult due to the pressure conditions generated by the fan 6 at the opening 14. Insofar, above a vapor pressure in the cooking chamber 1 higher than the ambient pressure steam escape through the opening 14, which then steam through a temperature increase detected at the temperature sensor 18 and can be recorded quantitatively. If the measured temperature Tx exceeds a first threshold value T1, then the microwave generator 31 is switched on. It is assumed that from the prevalence of certain steam conditions in the cooking chamber 1 represented by the first threshold T1, a microwave addition leads faster to the desired cooking result and supports the Dampfgarprozess.

The temperature signal of the temperature sensor 18, or in general form the gas outlet signal of the gas outlet sensor, but is preferably used for other purposes: For example, the steam generator 4 energy can be supplied when the temperature Tx at the temperature sensor 18 falls below a lower threshold Tu.

Also, the further opening 20 can be optionally opened when the temperature Tx at the temperature sensor 18 rises above an upper threshold value To, so that the cooking chamber 1 further steam is withdrawn. The further, closable opening 20 connects the cooking chamber 1 with the suction area 7 in front of the blower 6. For closing the second opening 20, a closure 21 is provided, which consists of a flap 22 which is more or less far from a stepping or servomotor 23 can be pushed over the mouth of the opening 20, so that the shutter 21 can be transferred substantially continuously from a closed to an open position. Also conceivable is an embodiment in which the flap 22 can only assume a closed or an open position. Intermediate positions for a reduced Flow through the further opening 20 can in this case, if necessary, be achieved by repeated, brief opening and closing of the flap 22, in the sense of pulse width modulation.

The temperature signal Tx of the temperature sensor can also be used to detect a gas outlet from the food itself, which event takes place approximately at a heated food to about 90 ° Celsius. This gas outlet from the food in turn causes a steam outlet from the oven, which can be detected by the temperature sensor. The recognition of this event, in turn, allows a more precise control of the further cooking process, since conclusions about the volume, nature, etc of the food can be made on the basis of the timing of this event. Escaping gases and vapors can also be removed by opening the other opening, be vented to high pressure, and to keep the oxygen level in the oven low

In the cooking chamber 1, a cooking chamber temperature sensor 25 may further be provided, with which the temperature of the cooking chamber 1 can be measured. Further, a core temperature sensor may be present (not shown), for example in the form of a needle that can be pricked into the food.

The microwave function can alternatively be controlled by a humidity sensor 26 in the cooking chamber 1, which receives the relative humidity in the cooking chamber 1.

The cooking appliance after FIG. 1 may be operated in various modes of operation, for which purpose the controller 24 is to be provided with suitable input elements via which the user can select a desired program. In particular, the device can be used in a conventional manner as a cooking appliance, for example by entering a desired oven temperature.

FIG. 2 shows a schematic illustration of a cooking appliance according to another embodiment the invention. This cooking appliance contains in a housing, not shown, a water tank 1, a boiler used as a steam generator 2, a cooking chamber 3, a not shown microwave generator, and a controller 4. The water tank 1 is preferably a drawer-like insert that holds a supply of water, preferably more as 500 ml, in an advantageous development more than 800 ml, and another version 1 liter. Via an intake pipe 5 and a suction pump 6, water can be taken from the water tank 1 and led to the steam generator 2. After operation, remaining water in the steam generator 2 can be pumped back to the water tank 1 via a drain line 7 and a drain pump 8. In the steam generator 2, a heating coil 9 is arranged, which is supplied by the controller 4 when needed with power. If the water is brought to boil in the steam generator 2, then steam flows via a line 10 into the cooking chamber 3 and heats the food. Excess steam escapes through an opening 11. If the water level in the steam generator 2 drops below a certain limit, the controller 4 switches on the pump 6 during normal operation, so that water can flow from the water tank 1. For this purpose, a not shown level sensor is arranged in the steam generator 2.

To regulate a temperature Tg in the cooking chamber, a cooking chamber temperature sensor 12 is provided. Furthermore, a temperature sensor 18 is provided, which measures the temperature Tx of outflowing steam at the opening 11. It turns out that the temperature Tx increases as soon as steam begins to exit through the opening 11. A steam outlet can therefore be detected, for example, by comparing the temperature Tx with a first temperature threshold T1, wherein the first threshold value has, for example, a value between 30 ° and 50 ° Celsius. If Tx> T1, steam exits through the opening 11, ie a certain level of steam is reached around the cooking space 1, at which either sufficient steam would have to be present, to perform a microwave operation more energy efficient, ie with less power and / or better Garresultat than without steam.

In a second mode of operation, an exit of steam is also detected with the aid of the temperature sensor 18, wherein the measured temperature Tx is compared with a second threshold T2 having an exemplary value between 50 ° and 70 ° Celsius. If Tx> T2, vapor is increasingly exiting through the opening 11, i. the steam cooking in the cooking chamber 1 is in full swing and could even be accelerated by the addition of microwaves. In this respect, if the second threshold value T2, i. at Tx> T2, the microwave generator is turned on.

Furthermore, the cooking appliance has an input unit 13, at which the user can set the desired setpoint temperature Tg of the cooking chamber 3. Furthermore, a ceiling heating 20 and a floor heating 21 can be arranged on the cooking chamber 3, with which the ceiling or the bottom of the cooking chamber 3 can be heated. Alternatively or in addition thereto, laterally arranged heaters may be provided for heating the side walls. The heater 19 and optionally the ceiling heater 20 and the floor heating 21 can be used, among other things, to pre-heat the cooking chamber before steaming. In this case, the cooking chamber 3 is preheated to a preheating temperature Tgv before steam is supplied. This preheating temperature is preferably 1 to 10 ° C, in particular about 5 ° C below the target temperature Tgs. Steam is only conducted into the oven when the preheat Tgv is reached. This can avoid that too much condensate precipitates or that a deflagration of the steam takes place.

While preferred embodiments of the invention are described in the present application, it should be clearly understood that the invention is not limited thereto and in any other way within the scope of the following claims.

Claims (15)

Cooking appliance for cooking food, comprising a cooking chamber (1, 3) for receiving the food,
a steam generator (2, 4) for supplying steam into the cooking chamber (1, 3),
an opening (11, 14) in the cooking chamber to allow escape of steam from the cooking chamber (1, 3),
a sensor for measuring a parameter of steam exiting through the opening (11, 14) from the cooking chamber (1, 3),
a microwave generator (31) for heating the cooking product accommodated in the cooking chamber (1, 3),
a controller (24) for controlling the microwave generator (31) depending on the parameter measured by the sensor. Cooking appliance according to claim 1,
wherein the sensor is a temperature sensor (18) for measuring the temperature (Tx) of steam exiting through the aperture (11, 14). Cooking appliance according to claim 1 or claim 2, wherein the sensor is arranged in an outwardly facing extension of the opening (11, 14). Cooking appliance for cooking food, comprising a cooking chamber (1, 3) for receiving the food,
a steam generator (2, 4) for supplying steam into the cooking chamber (1, 3),
a sensor for measuring a parameter of steam in the cooking chamber (1, 3),
a microwave generator (31) for heating the cooking product accommodated in the cooking chamber (1, 3),
a controller (24) for controlling the microwave generator (31) depending on the parameter measured by the sensor. Cooking appliance according to claim 4,
in which the sensor is designed as a humidity sensor for measuring the humidity in the cooking chamber (1, 3). Cooking appliance according to one of the preceding claims,
in which the controller (24) is designed to control the microwave generator (31) as a function of overshoot and / or undershoot of a threshold value (T1, T2) by the measured parameter. Cooking appliance according to one of the preceding claims,
in which the controller (24) is designed for connecting and / or disconnecting the microwave generator (31) as a function of the measured parameter, and / or
wherein the controller (24) is adapted to increase and / or decrease the power of the microwave generator (31) depending on the measured parameter. Cooking appliance according to one of the preceding claims,
wherein the controller (24) is adapted to control the microwave generator (31) in response to the measured parameter in the event that the steam generator (2, 4) is activated. Cooking appliance according to one of the preceding claims,
with a water tank (1) for receiving water for conversion into steam by the steam generator (2, 4), which water tank (1) has a capacity of greater 500 ml, and wherein the water tank (1) preferably has a capacity of greater than 800 ml. Cooking appliance according to one of the preceding claims,
with a selector switch for selecting one of several cooking programs,
wherein the controller (24) is adapted to control the microwave generator (31) solely by the measured parameter in the event that selection of an associated cooking program by the selector switch is detected. Method for operating a cooking appliance for cooking food,
in which steam generated by a steam generator (2, 4) is fed to a cooking chamber (1, 3),
in which a parameter of steam exiting through a port (11, 14) from a cooking chamber (1, 3) is measured, and
wherein a microwave generator (31) is controlled depending on the measured parameter. Method for operating a cooking appliance for cooking food,
in which steam generated by a steam generator (2, 4) is fed to a cooking chamber (1, 3),
in which a parameter of steam in the cooking chamber (1, 3) is measured, and
wherein a microwave generator (31) is controlled depending on the measured parameter. Method according to claim 11 or claim 12
in which the microwave generator (31) is controlled exclusively as a function of the measured parameter in the event that the steam generator (2, 4) is activated. Method according to one of the preceding claims 11 to 13,
in which the microwave generator (31) is switched on when a first threshold value (T1, T2) is exceeded by the measured parameter. Method according to one of the preceding claims 11 to 14,
in which the microwave generator (31) is switched off when a second threshold value (T2) is exceeded by the measured parameter.

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