DE102012004204A1 - Cooking appliance and method for controlling a cooking appliance - Google Patents

Abstract

The invention provides a cooking appliance (10) having a cooking chamber (12), a controller (40), a high - frequency radiation source (28) which is controlled by the controller (40), and at least one movable element (24, 42), which in Cooking chamber (12) is arranged, which is characterized in that a signal generator (38) is provided, which the controller (40) provides a synchronization signal indicating a position of the movable element (24, 42). The invention also provides a method for operating such a cooking appliance, which is characterized in that the high-frequency radiation source (28) is controlled in dependence on the synchronization signal.

Description

The invention relates to a cooking appliance with a cooking chamber, a controller, a high-frequency radiation source, which is controlled by the controller, and at least one movable element which is arranged in the cooking chamber. The invention also relates to a method for operating such a cooking appliance.

It has been known for decades that food can be heated by high frequency radiation; which is generated by a high-frequency radiation source, for example a magnetron, and conducted into the cooking chamber. The heat is thereby generated in the food that the high-frequency radiation (in common usage "microwave radiation") vibrates water molecules contained in the food, vibrating. In order to heat the foodstuffs evenly, it is desirable that the high frequency radiation act evenly on the foodstuffs. However, due to reflections on the walls of the cooking chamber, interference occurs that leads to so-called hot spots and cold spots, ie local areas where more heat energy is released in the food or less energy than in other areas.

For the field of high-frequency radiation household appliances (usually referred to as "microwave ovens"), it is known to arrange the food to be heated on turntables so that their position changes relative to the field inside the cooking chamber. This should cause the food to be heated evenly. For cooking appliances in the field of large catering, however, it is hardly practicable to move the food introduced into the oven. Either the foods are on food supports, which are inserted in slide rails of a Einhängegestells, or they are arranged on a tray rack, which is fully loaded inserted into the oven. For such cooking appliances beats the EP 2 230 882 A1 to use a movable element in the interior of the cooking chamber, for example a fan wheel, which consists of a material which has an interaction with the high-frequency radiation. As the fan rotates, it causes the field generated by the high-frequency radiation to change regularly inside the cooking chamber, so that the food is heated evenly and no hot spots or cold spots can form.

The object of the invention is to further optimize the energy transfer to the foodstuffs with respect to the uniformity and efficient utilization of the power provided by the high frequency radiation source.

To solve this problem, a signal generator is provided in a cooking appliance of the type mentioned, which provides the controller with a synchronization signal indicating a position of the movable element. In a method for operating a cooking appliance, it is provided according to the invention that the high-frequency radiation source is controlled as a function of the synchronization signal. The invention is based on the recognition that the energy transfer to the foodstuffs can be optimized in that a correlation of the position of the moving element with properties of the high-frequency radiation, in particular frequency, amplitude and / or phase, can be used to transfer the energy to the foodstuffs to optimize.

According to one embodiment of the invention, the movable element is a fan. In this case, the synchronization signal indicates the phase position or rotational position of the fan wheel, so that the high-frequency radiation source can be operated synchronized periodically with the rotation of the fan wheel.

It is also possible that more than one movable element is provided, for example two or three fan wheels. These can be arranged at suitable locations inside the cooking appliance in order to influence the high-frequency field in the interior of the cooking chamber in the desired manner.

Preferably, it is provided that the movement of the elements is controlled relative to each other. This embodiment takes into account that the radio-frequency field in the interior of the cooking chamber can also be optimized in the desired manner by a suitable phase angle of the movement of the elements relative to each other.

According to one embodiment of the invention, more than one high-frequency radiation source is provided in the cooking appliance. In this way, there is a higher flexibility with regard to the feeding of the high-frequency radiation into the cooking chamber and the combination of different powers, frequencies, etc.

Preferably, it is provided that at least one characteristic parameter of the high-frequency radiation emitted by a high-frequency radiation source is controlled relative to at least one characteristic parameter of the high-frequency radiation emitted by the second high-frequency radiation source. The characteristic parameter may be the frequency, the polarization or the amplitude of the emitted high-frequency radiation, which can be controlled relative to each other so that the energy transfer to the food is optimized.

According to one embodiment of the invention, it is provided that the high-frequency radiation source is controlled as a function of at least one cooking chamber parameter. This is based on the knowledge that by taking into account certain parameters, in particular the absorption of the high-frequency radiation in the cooking chamber, the temperature of the food, the browning of the food and / or the litter parameter, the energy transfer to the food can be further improved.

The invention will be explained below with reference to an embodiment shown in the accompanying drawings. In these show:

1 an inventive cooking appliance in a schematic view;

2 two examples of the synchronization of the frequency of high-frequency radiation with the rotation of a fan wheel; and

3 two curves of the energy absorption in the oven as a function of the frequency characteristics of 2 ,

In 1 is a cooking appliance 10 which is a professional cooking appliance used in restaurant kitchens, canteen kitchens and large catering. It contains a cooking space 12 , in which food or food can be introduced. The cooking space 12 has a floor 14 , several side walls 16 , A blanket 18 and a divider 22 on. The baffle is used to optimize the flow of air by means of a fan 24 can be generated in the cooking chamber 12 is arranged and used to circulate the atmosphere in the oven. Food or food items can be arranged on food supports, which in different insertion levels of a suspension frame schematically shown here 26 can be inserted.

Temperature and humidity of the cooking chamber atmosphere can be influenced in a conventional manner by means of a heater and a steam generator, both of which, however, are not shown here, since they are of no significance for the understanding of the invention. In addition, here are two high frequency radiation sources 28 hereinafter referred to simply as magnetrons, which can generate high frequency electromagnetic waves (hereinafter simply referred to as microwave radiation). The ones from the magnetrons 28 generated microwave radiation is intended to act on food to be cooked in the oven 12 located. For this purpose, the microwave radiation is here via waveguides 30 in the oven 12 initiated, in which it spreads. For this purpose are passage openings 32 between the separating plate 22 and the ceiling 18 or the ground 14 provided the cooking chamber, which are also used to the cooking chamber atmosphere between the room in which the fan 24 is arranged, and the cooking chamber 12 to enable.

The fan wheel 24 is with a drive shaft 33 connected, in turn, with a motor 34 connected is. The motor 34 is in a technical room 36 arranged, in which also the two magnetrons 28 are located. The drive shaft 33 is a signal generator 38 assigned to a controller 40 can provide a synchronization signal. The synchronization signal consists here in particular of an angle signal, which is the angular position or rotational position of the drive shaft 33 and thus also the fan wheel 24 indicating at a specific time.

On the ceiling 18 of the cooking chamber 12 is another moving element 42 arranged, which by a (not shown here) drive motor can be set in rotation. This may be a mode mixer with which the reflection of the microwave radiation in the oven 12 can be influenced. Also the second moving element 42 is a signal generator 38 assigned to the controller 40 a synchronization signal also for the second movable element 42 can be made available. Furthermore, the controller receives a signal from a sensor 44 , which is shown here only schematically. The sensor 44 can provide a cooking chamber parameters, for example, the temperature of the food, the tanning of the food, temperatures or temperature profiles in the cooking chamber, parameters of the cooking chamber atmosphere such as temperature and humidity, the absorption of high-frequency radiation in the oven or the magnetrons 28 evaluate returning waves (S-parameter).

It can be in the oven 12 also more than a fan 24 can be used, which is then usually arranged on the same wall as the first fan. It is also possible to arrange the fan wheels on opposite walls of the cooking chamber.

When operating the cooking appliance 10 in a microwave mode, the controller controls 40 the magnetrons 28 such that the desired microwave radiation is provided. In particular, characteristic parameters of the microwave radiation are varied by the control. For example the polarization, the amplitude and / or the frequency can be varied. The characteristic parameter is varied so that the energy transfer to the in the cooking chamber 12 food is optimized. This will be explained below with reference to 2 and 3 explained using a simplified example, which emanates from only a movable element in the cooking appliance, such as the fan 24 ,

On the abscissa is the angle of rotation of the fan wheel 24 applied. The information about the current position of the fan wheel 24 is the controller 40 as a synchronization signal from the signal generator 38 to disposal. On the ordinate are plotted with Fmin and Fmax the lower limit and the upper limit of the frequency range within which the frequency of the magnetrons 28 provided microwave radiation is varied. As a curve 1 is a linear change of the frequency from the lower limit to the upper limit over a complete rotation of the fan wheel applied, wherein the phase position 0 ° or 360 °, a frequency at the lower limit of the frequency band or at the upper limit exists. As a curve 2 is a variation of frequency plotted versus curve 1 is 180 ° out of phase. In the phase position 0 ° or 360 ° so there is an average frequency, while in the phase position of 180 °, the sudden transition from the maximum frequency to the minimum frequency.

In 3 is plotted the absorbed power, which is dependent on the two frequency curves according to curve 1 and curve 2 results. It can be seen that the absorbed power in the variation of the frequency according to curve 1 fluctuates much less than that of the frequency variation according to the curve 2 the case is. Therefore, the controller 40 Synchronize the rotational movement of the fan with the variation of the frequency of the magnetrons so that a cycle of change of the frequency with the angular position θ = 0 ° is started and is completed after a full revolution of the fan.

There are further variations are conceivable, with which the change of the frequency could be synchronized with the rotation of the fan wheel. For example, a change in frequency could be made from the minimum to the maximum frequency within half a revolution of the fan wheel. It is also possible to adjust the values for the minimum frequency and the maximum frequency or to choose depending on the food to be cooked. It is also possible to change the way the frequency changes. Instead of the linear course shown here, an exponential curve or a discretely changing curve can also be used, for example in steps of 10 hertz.

In principle, the manner in which the magnetron or the magnetron is synchronized with the movable element or elements can be investigated experimentally beforehand and then determined individually for different cooking processes and / or different food items. It is also possible in the controller 40 several different variation schemes to deposit, for example, different histories with respect to the change in the frequency of the microwave radiation or different synchronizations between the angular position of the movable element and the course of the frequency change, and the controller at the beginning of a microwave cooking program to successively test different combinations of different parameters , By evaluating the microwave parameters (reflected power and / or power absorbed by other feeds), an individual profile of the power absorbed in the cooking chamber is obtained. The controller can then choose for the further cooking process the combination of changing the frequency of the microwave radiation with synchronization relative to the movable element, in which a larger and / or more uniform energy input is realized.

If, as in the embodiment shown, two magnetrons and two movable elements are used, further variation possibilities result. In particular, the phase position of the movable elements can be synchronized relative to each other so that they run offset with a certain angular position to each other, or they can be operated at defined different speeds or frequencies, so that the angular position changes continuously relative to each other. It is also possible to synchronize the microwave radiation emitted by the magnetrons relative to each other, for example by the amplitude of the two magnetrons 28 emitted microwave radiation whose polarization and / or their frequency is kept constant in a certain way to each other or is also varied continuously.

Furthermore, it is possible that the controller 40 in the control of the magnetron 28 the signals of the sensor 44 takes into account which different food parameters specify. For example, depending on the heating of the food or a phase transition or the degree of browning of the food can be switched from one operating mode of the magnetron to another.

It is basically within the scope of the invention also conceivable that a turntable is used as a movable element in the cooking chamber, whose position with the properties of the fed Microwave radiation or the position or movement of other moving elements (for example, fashion storm or fan) can be correlated.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• EP 2230882 A1 [0003]

Claims (12)

Cooking appliance ( 10 ) with a cooking space ( 12 ), a controller ( 40 ), a high frequency radiation source ( 28 ), which are controlled by the controller ( 40 ) and at least one movable element ( 24 . 42 ) in the cooking chamber ( 12 ), characterized in that a signal generator ( 38 ) is provided, which of the controller ( 40 ) provides a synchronization signal representing a position of the movable element ( 24 . 42 ) indicates. Cooking appliance according to claim 1, characterized in that the movable element is a fan ( 24 . 42 ). Cooking appliance according to claim 1 or claim 2, characterized in that more than one movable element ( 24 . 42 ) is provided. Cooking appliance according to one of the preceding claims, characterized in that more than one high-frequency radiation source ( 28 ) is provided. Method for operating a cooking appliance according to one of the preceding claims, characterized in that the high-frequency radiation source ( 28 ) is controlled in response to the synchronization signal. A method according to claim 5, characterized in that the controller controls the frequency of the high-frequency radiation source ( 28 ) emitted radiation varies. Method according to claim 5 or claim 6, characterized in that the controller controls the polarization of the signals emitted by the radio-frequency radiation source ( 28 ) emitted radiation varies. Method according to one of claims 5 to 7, characterized in that the control of the amplitude of the high-frequency radiation source ( 28 ) emitted radiation varies. Method according to one of claims 5 to 8, characterized in that more than one high frequency radiation source ( 28 ) and that at least one characteristic parameter of the signal from a high-frequency radiation source ( 28 ) is controlled relative to at least one characteristic parameter of the high-frequency radiation emitted by the second high-frequency radiation source ( 28 ) is delivered. Method according to one of claims 5 to 9, characterized in that a plurality of movable elements ( 24 . 42 ) are provided and that the movement of the elements is controlled relative to each other. Method according to one of claims 5 to 10, characterized in that the high frequency radiation source ( 28 ) is controlled in dependence on at least one cooking chamber parameter. A method according to claim 11, characterized in that the cooking space parameter comprises the absorption of the high-frequency radiation in the cooking chamber, the temperature of the food, the browning of the food and / or the scattering parameters.

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