EP0321768A2 - Control device for the heating, the thawing and/or the cooking of food by microwaves - Google Patents

Abstract

The control arrangement according to the invention for heating, thawing and / or cooking foods to be treated thermally by applying microwave energy within a closed cooking chamber, in particular in domestic cookers, has a microwave energy potential in the space between the microwave generator and the food to be charged with microwave energy which is filled with microwave energy Sensor, via which the control power for the microwave generator can be controlled.

Description

The present invention relates to a control arrangement for heating, thawing and / or cooking foods to be thermally treated by exposure to microwave energy within a closed cooking space, in particular in domestic stoves.

In the household, microwave ovens or microwave ovens with or without additional thermal heating sources are used, into which the microwave energy is fed into a cooking space sealed in a microwave-tight manner by means of a microwave generator, namely a magnetron, via waveguides. An approved microwave frequency of 2.45 GHz is used. The coupled microwave energy is usually 600 to 700 watts. The microwaves coupled into the cooking space penetrate more or less deeply and intensively into the food to be cooked, depending on the type and nature of the food to be cooked, and the microwave energy is converted there into thermal energy and is used to carry out cooking processes or to defrost food. Depending on the desired type of treatment and the type of food to be cooked, different power levels can be set in known cookers up to this maximum output. There are various options for this. It is possible, for example, to change the microwave power by switching capacitances on and off in the magnetron circuit. Another widely used measure for reducing the maximum power is given by generating the maximum power of the microwave generator in a clocked manner, ie at relatively short intervals the microwave transmission is interrupted for predetermined pause times. The setting of the suitable microwave power for the respective cooking process is the responsibility of the operator in known household appliances. Thus, the operator must take great care to avoid inappropriate, unfavorable or even harmful settings of the microwave energy. Similar to roasting processes with purely thermal exposure of the food to be cooked, it is also possible to provide fixed programs or programs which can be entered individually, from which different microwave loads on the food to be cooked are controlled in phases. These measures are problematic in that the practical cooking phases differ more or less from the values entered due to the nature of the individual items to be cooked. There are particularly large deviations in the required treatment time during thawing processes.

In order to counter this problem, it has become known to provide sensors for detecting the current state of the food to be cooked, which in the form of a so-called roasting spit detect the respective internal temperature of the food to be cooked, or in the form of gas sensors or moisture sensors to determine the state of the food in the cooking space or removed from the cooking space Wrasens record from which an attempt is being made to indirectly identify the current state of the food. Both methods are problematic and, for these reasons, have so far been virtually unsuccessful with generally satisfactory results.

Based on these findings, it is the object of the present invention to provide an arrangement for the thermal treatment of foodstuffs in which the respective cooking state of the foodstuff can advantageously be detected without intervention in the foodstuff, but nevertheless close to the body, when these foods are exposed to microwave energy.

An arrangement which meets these requirements is characterized according to the invention in that a sensor detecting the microwave energy potential is arranged in the space filled with microwave energy between the microwave generator and the food to be charged with microwave energy, via which sensor the control power for the microwave generator can be controlled.

This control arrangement according to the invention makes use of the knowledge that a cooked food undergoes heat change in terms of its microwave absorption capacity. These changes are particularly striking when a food changes from frozen to thawed. With the help of the control arrangement according to the invention, these changes are detected in the food to be cooked, namely in that a sensor is arranged in the space filled with microwave energy between the microwave generator and the foodstuff exposed to microwave energy, which sensor detects the prevailing microwave energy potential. The microwave energy potential in this room depends on the one hand on the microwave energy that is radiated into this room by a microwave generator and on the other hand on the microwave energy that is absorbed by the food. Now it is possible to either evaluate the relation between the radiated and absorbed microwave energy as an absolute value of the microwave energy space potential or its temporal changes.

The control arrangement according to the invention will preferably be used in stoves in which the food to be cooked is treated thermally by microwave exposure. In principle, however, the measure according to the invention is also suitable when the food to be treated thermally is subjected to purely thermal action. In this case, however, the microwave must be coupled into the cooking space for the measurement measures. This microwave coupling can then be very weak, i.e. low energy and impulsive.

According to a preferred embodiment, the control arrangement according to the invention is characterized in that the process sequence control device for the operating mode "thawing a food" upon detection of the thawing temperature range by measuring field strength changes in the microwave range as a result of the changed microwave absorption capacity of the surface-thawed foodstuff, a decrease in the microwave energy triggers. In this connection, it is advantageous that during the "defrosting of a food" mode, when there is a representative change in the field strength of the microwave energy detected by the sensor as a result of the thawing of the surface area of the food, controlled by the process sequence control, it is withdrawn for a limited time and then at least again for a period of time determined by the sensor is switched on. With the help of these measures, the thawing of a food as quickly as possible is achieved without the risk that the food is already being cooked on its surface. As long as the surface area of the food is still frozen, relatively high microwave energy or other thawing energy can be supplied to the food. However, if the surface area of the food has already been thawed, the thawing energy supplied is reduced to such an extent that a heat balance is formed between the thawed outside area of the food and the still frozen food core. The thawing process can thus be evened out and optimized in terms of time.

According to another preferred embodiment, the control arrangement according to the invention is characterized in that the process sequence control device for cooking processes to be carried out contains representative values of the field strength in the microwave space in relation to the supplied microwave energy and stores these with the respective actual microwave field strength comparison detected by the sensor and as a function of the comparison result can be controlled by the process flow control device, the supply of microwave energy via the microwave generator.

In connection with the control arrangement equipped according to the invention, it is expedient that the process sequence control device can be supplied with values for the initial conditions given by the food to be treated and / or for the intended end conditions.

According to another preferred configuration, the control arrangement according to the invention is characterized in that an evaluation circuit connected downstream of the sensor for the detection of the microwave energy potential in the microwave room contains representative values for the "idle mode" closed in the microwave room and that upon detection of a corresponding microwave energy potential by the sensor via the evaluation circuit, the control of the microwave generator and thus the microwave generation is switched off. In this connection, the evaluation circuit is preferably equipped with a timing element, so that it uses this to trigger the switch-off of the microwave generator when a value specified for "idle mode" is received. The microwave is mistaken If the energy supply to the cooking chamber is switched on by an operator, even though there is no food to be cooked in the cooking chamber, the microwave energy supply is switched off in good time when these circuitry measures are taken, so that no dangerous moments arise. By using the timing element, however, so much microwave energy is coupled in that the smallest quantities of food are still influenced in a relevant thermal manner. In this context, it is also possible to carry out two measured value acquisitions at short intervals and to make the switching off of the microwave supply dependent on the fact that values for "idle operation" are determined in both acquisitions.

Provisions can preferably be made in such a way that the evaluation circuit switches off the microwave generator only when the maximum microwave power has been set and / or, if appropriate, an additional high thermal heating power supply. This means that only relatively high microwave powers, which can lead to problem situations, either alone or in conjunction with additional thermal heating powers, are switched off, while lower microwave power radiation is not switched off. Because of the microwave losses in the waveguide and cooking space elements, it can be problematic to detect food of low mass within the cooking space with sufficient microwave technology. Such quantities of food can be subjected to lower, but also sufficient, microwave energy without the risk of automatic shutdown.

In terms of construction, the microwave sensor can be designed as an inductive probe or as a capacitive probe for the control arrangement according to the invention. It can be expedient to arrange the microwave sensor as a directional coupler arrangement in the region of the waveguide arranged between the microwave generator and the food treatment region. In this area, the microwave sensor is usually not exposed to any relevant vapors and therefore cannot become dirty. In particular, the microwave field conditions can be recorded relatively precisely in this area.

An embodiment equipped according to the features of the invention is described in more detail below with reference to the drawing.

The figure shows a schematic representation of the basic structural units of a microwave oven.

Microwave energy is coupled into a cooking chamber GR of the microwave oven, within which cooked food GG to be treated thermally is introduced, via a rotating antenna MA. This rotating antenna MA takes over the microwave energy from a waveguide HL, which in turn takes over the microwave energy from a microwave generator MG, a magnetron. To control this magnetron, a power control unit LS is arranged, which contains a high-voltage transformer and rectifier and capacitor units in a known manner. These switching elements, which are required for safe microwave operation, need not be considered in the present case.

The setting values relating to the microwave power to be radiated into the cooking space GR and the duration of this irradiation are entered into a control logic AL via a display / operating panel AE, which converts these input values for the control of the power control unit. The set values can be displayed on the AE display / control panel.

A microwave directional coupler RK is coupled to the waveguide HL, an output line A1 of which detects measured values which correspond to the microwave energy traveling from the microwave generator MG in the direction of the cooking chamber GR through the waveguide HL and whose second output A2 detects measured values for opposing microwave energy. The relation of these microwave energy migrations and thus the relation of the measured quantities detected by the outputs A1 and A2 of the directional coupler RK gives a good indication of which microwave energy potential prevails in the cooking chamber, since not only the microwave generator MG is able to absorb microwave energy feed the waveguide HL, but also feeds the cooking chamber back into the waveguide HL in accordance with the microwave energy potential prevailing in it, which can be detected by the microwave directional coupler RK at the output A2. The microwave potential that arises in the cooking chamber when microwave radiation is present is dependent on the microwave absorption capacity of the cooking product GG located in the cooking chamber GR. The microwave absorption The ability and convertibility into heat of the food depends on its type, its mass (weight) and its condition. If, for example, no food to be cooked is arranged in the cooking space GR, no substantial energy is absorbed in the cooking space GR and the declining microwave energy detected by the microwave directional coupler RK will increase to a very high degree in relation to the coupled-in microwave energy. When carrying out cooking processes, however, the change in the state of the food to be cooked, for example from the frozen state to the thawed state, becomes important for the control measures.

The outputs A1 and A2 of the directional coupler RK are fed to a comparison circuit VS, which carries out the relation between the two measured values that are detected and supplied, and from this passes on a criterion to the control logic AL. Depending on this, the power control LS for the microwave generator MG is influenced and readjusted in accordance with the energy requirement within the cooking chamber GR and the entered values. The control logic AL can be entered via the display / input panel AE, the values for the individual cooking processes or the control logic AL contains such values that are permanently entered for the implementation of standard cooking processes. By superimposing the values detected by the microwave directional coupler RK, which currently represent the cooking state of the food, the process of the individual process steps is controlled and modifications of these steps can be carried out.

Instead of the directional coupler RK in the area of the waveguide HL, a corresponding sensor for detecting the microwave energy potential can also be arranged in the cooking chamber itself. However, it should be taken into account that different microwave energy intensities build up in the cooking space GR. For uniform thermal treatment of the food to be cooked, these microwave energy intensities are additionally spatially changed via the rotating antenna MA in the present exemplary embodiment. These circumstances are to be taken into account in terms of circuitry when measuring the microwave energy potential prevailing in the cooking space GG both by appropriate arrangement of the sensor and by equalization of the measurement results over time.

In the present exemplary embodiment, the microwave energy emitted by the microwave generator MG is used both for the thermal treatment of the food GG and for measuring purposes. This link is possible, but it is by no means a prerequisite for the measurements. Rather, it is also possible to provide only microwave energy for the measuring purposes in the cooking space. This microwave energy can then be relatively small and can only be emitted in time slots used for the measurement purposes. In addition, there is the possibility that the microwave frequency for measurement purposes deviates from the microwave frequency for carrying out the cooking process, which has measurement-related advantages in that different wavelengths of the microwaves have different penetration depths in the food. In this context, it is also possible to use solid-state microwave energy generators, since, as has already been stated, the required powers can be relatively small.

However, it is also possible to use the microwave technology only for measuring purposes in relation to the quality of the food to be cooked and to operate the thermal treatment in conjunction or exclusively by means of thermal heating elements.

Claims (16)

1. Control arrangement for heating, thawing and / or cooking food to be treated thermally by applying microwave energy, within a closed cooking space, in particular in domestic stoves, using a sensor that detects the condition of the food, from which the energy radiated into the cooking space can be controlled , characterized in that in the space filled with microwave energy (GG) between the microwave generator (MG) and the food exposed to microwave energy, a sensor detecting the microwave energy potential is arranged, by means of which the control power for the microwave generator (MG) can be controlled. 2. Control arrangement according to claim 1, characterized in that a process sequence control device (LA) for controlling the microwave generator (MG) is arranged, which influences the control state of the food (GG) as a function of the detected treatment state of the food (GG) ) controls for the microwave generator. 3. Control arrangement according to claim 1, characterized in that the process sequence control device (AL) for the operating mode "thawing a food" upon detection of the thawing temperature range by field strength change measurement in the microwave range as a result of changed microwave absorption of the surface-thawed food a withdrawal of the microwave energy triggers. 4. Control arrangement according to claim 3, characterized in that during the operating mode "thawing a food" in a detected by thawing the surface area of the food by the sensor, representative change in the field strength, the microwave energy controlled by the process control for a limited period of time and withdrawn is then switched on again at least for a period of time determined by the sensor. 5. Control arrangement according to claim 1, characterized in that the process sequence control device for cooking processes to be carried out contains representative values of the field strength in the microwave space in relation to the supplied microwave energy and compares them with the respective actual microwave field strengths detected by the sensor and that as a function of that Comparison result by the process sequence control device, the supply of microwave energy can be controlled via the microwave generator. 6. Control arrangement according to one of claims 1 to 5, characterized in that the process sequence control device can be supplied with values for the initial conditions given by the food to be treated. 7. Control arrangement according to one of claims 1 to 6, characterized in that the process sequence control device can be supplied with values for the end conditions provided by the food to be treated. 8. Control arrangement according to one of claims 1 to 7, characterized in that the sensor for detecting the microwave energy potential in the microwave space downstream evaluation circuit contains representative values for the "idle mode" in the microwave room, and that when detecting a corresponding microwave energy potential by the sensor the evaluation circuit, the control of the microwave generator and thus the microwave generation is switched off. 9. Control arrangement according to claim 8, characterized in that the evaluation circuit is equipped with a timing element and with the aid of this controls the shutdown of the microwave generator upon receipt of a value predetermined for "idle mode". 10. Control arrangement according to claim 8, characterized in that the control circuit is equipped with a timing element and influenced by this within a predetermined period of time when the value detected by the sensor "idle mode" causes a further measurement value acquisition via the sensor and with the same result as a result of second measurement value detection switches off the control circuit for the microwave generator. 11. Control arrangement according to one of claims 8 to 10, characterized in that the evaluation circuit can be acted upon in addition to the value detectable by the microwave space sensor by values of the powers fed into the microwave space and as a function of predetermined power values acting on the microwave space and one from the sensor for the operating state "idle mode", the control for the microwave generator switches off. 12. Control arrangement according to claim 11, characterized in that the evaluation circuit switches off the microwave generator only when the maximum microwave power and / or optionally additional high thermal heating power supply is set. 13. Control arrangement according to one of claims 1 to 12, characterized in that for the detection of the type, the mass and the condition of the food to be thermally treated operating conditions within the space filled with microwave, a microwave generator with only required for the metrological detection Power and for the metrological detection optimal frequency is arranged, to which the sensor arranged in the microwave room is tuned. 14. Control arrangement according to claim 1 to 13, characterized in that it is designed as a microwave sensor as an inductive probe. 15. Control arrangement according to one of claims 1 to 13, characterized in that the microwave sensor is designed as a capacitive probe. 16. Control arrangement according to one of claims 1 to 13, characterized in that the microwave sensor is designed as a directional coupler arrangement in the region of the waveguide arranged between the microwave generator and the food treatment region.

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