DE102013109300B4 - Method for controlling a cooking appliance - Google Patents

Abstract

Method for controlling a cooking appliance which comprises at least two magnetrons (10, 12, 14) which together generate a total power that can be subdivided into several power ranges (L1, L2), the magnetrons (10, 12, 14) being switched and clocked are partially in operation at the same time, at least in a certain power range (L1).

Description

The invention relates to a method for controlling a cooking appliance which comprises at least two magnetrons.

Cooking devices are known from the prior art which have a magnetron that generates microwave radiation. A product to be cooked in the cooking appliance is cooked with the microwave radiation generated. Furthermore, cooking devices are known from the prior art which have a plurality of magnetrons, whereby a higher total nominal power can be achieved, since the respective individual powers of the magnetrons are added to a total power. The power provided by the magnetrons can also only partially be called up by the user or the cooking program, this requiring fine control of the magnetrons. In the prior art, at least one magnetron is typically used continuously in order to achieve high, desired target output of the cooking appliance, which is a partial output of the total nominal output, with a second magnetron being switched on in such a way that the target output is achieved on average. It has been found that the wear on the magnetrons is unfavorable due to the uneven loading, since the magnetron, which is often switched on and off, wears out correspondingly quickly.

From the U.S. 4,900,885 A a power control of a single magnetron via pulse width modulation is known.

In the DE 31 15 517 A1 a control of two magnetrons is described, which are operated intermittently, that is, operated alternately, so that the two magnetrons are not in operation at the same time.

It is the object of the invention to further develop a control method in such a way that the magnetrons are operated gently and the energy input into the food to be cooked is evened out.

The object is achieved according to the invention by a method for controlling a cooking appliance that comprises at least two magnetrons that jointly generate a total power that can be subdivided into several power ranges, the magnetrons being switched clocked and at least in a certain power range partially in operation at the same time. The basic idea of the invention provides that the magnetrons are both switched permanently in a clocked manner, the simultaneous operation, that is to say the overlapping power of both magnetrons, only occurs temporarily in a certain power range. The clocked switching of the individual magnetrons accordingly extends over the entire power range of the cooking appliance, that is, from 0% to 100% of the total rated power. As a result, the load is distributed over the magnetrons, although the entire range of services can still be covered. The fine regulation of the total power of both magnetrons takes place via the clocking time of the individual magnetrons and the associated times of the overlapping power in the specific power range, the clocking time being the time span between two switch-on points of a respective magnetron. Clocking the magnetrons is particularly advantageous because in a low power range (in particular below around 35% of the maximum output), power control by clocking is the only sensible way of influencing the output of the magnetrons.

According to one aspect of the invention, it is provided that the magnetrons are controlled in such a way that the same clocking times are established in each case. This results in a homogeneous load distribution on the existing magnetrons, so that the load on the magnetrons is exactly the same.

In particular, the magnetrons are switched with a time offset to one another. A partial output of the total rated output can be generated by the time-shifted switching, the partial output depending on the duration of the power phases and the idle phases of an individual magnetron. When operating several magnetrons, there can be several different power phases.

According to a further aspect of the invention, the specific power range can be subdivided into power sub-areas in which the magnetrons are controlled differently, the number of power sub-areas being one less than the number of magnetrons. The service sub-areas differ in their specific control method or the design of the service phases. However, the power sub-areas have in common that the magnetrons are switched clocked and at least two magnetrons are operated at least in sections or at times at the same time. With three magnetrons, for example, there are two power sub-ranges.

Another aspect of the invention provides that the specific power range is an upper power range that lies between 100% of the total power and a limit value. The limit value is defined by the reciprocal of the number of magnetrons. The power range embodied in this way thus also depends on the number of magnetrons, with, for example, three magnetrons in the upper power range, in which at least partially two magnetrons are in operation at the same time are between 100% and 33% of the total rated power.

According to a further aspect of the invention, in a further power range, at most one magnetron is in operation at the same time. In this further power range, no simultaneous operation of two magnetrons is provided, with the desired target power being able to be set accordingly via the idle phases and the power phases. The magnetrons are switched through one after the other so that they are operated uniformly.

The further power range can be a lower power range, in particular a range between 0% of the total power and the limit value. The entire power of the cooking appliance can thus be divided into two power ranges, the upper power range being characterized in that at least two magnetrons are at least partially in operation at the same time. In the lower power range, on the other hand, only one magnetron is in operation at the same time. The more magnetrons are provided, the smaller the lower power range turns out to be.

In particular, three magnetrons are provided, which are controlled and with which the control method according to the invention is carried out, since with three magnetrons the clocking times are correspondingly long and easily controllable, whereby the load on the respective magnetrons can be distributed more homogeneously.

• - 1 eine schematische Übersicht der Leistungsbereiche eines Gargeräts mit drei Magnetrons,
• - 2 ein Leistungsdiagramm von drei Magnetrons in einem ersten Leistungsteilbereich eines oberen Leistungsbereichs,
• - 3 ein Leistungsdiagramm der drei Magnetrons in einem zweiten Leistungsteilbereich des oberen Leistungsbereichs, und
• - 4 ein Leistungsdiagramm der drei Magnetrons in einem unteren Leistungsbereich.

Further advantages and aspects of the invention emerge from the following description and the drawings, to which reference is made. In the drawings show:

• - 1 a schematic overview of the power ranges of a cooking appliance with three magnetrons,
• - 2 a power diagram of three magnetrons in a first power sub-range of an upper power range,
• - 3 a power diagram of the three magnetrons in a second power sub-range of the upper power range, and
• - 4th a power diagram of the three magnetrons in a lower power range.

In 1 an overview of the power ranges of a cooking appliance with three magnetrons is shown schematically.

The total rated power of a cooking appliance with three magnetrons can be divided into two power ranges L1 , L2 be subdivided, with the power range L1 represents an upper performance range and the performance range L2 a lower performance range.

In the exemplary embodiment shown, this means specifically that the upper power range L1 covers a range from 33% to 100% of the total nominal power, whereas the lower power range L2 covers a range from 0% to 33% of the total nominal power. The limit value of 33% results from the reciprocal value of the three magnetrons, i.e. one third.

The upper performance range L1 is also in the selected example in two power sub-areas Lt1 , Lt2 can be subdivided, whereby the two power sub-areas Lt1 , Lt2 differ in their specific control behavior or their performance phases Lp.

The two service areas also differ L1 , L2 with regard to the specific design of the control of the magnetrons or their power phases Lp.

The control behavior of the individual magnetrons results from the 2 until 4th , in which the respective powers of the magnetrons are shown in the corresponding power or power sub-areas.

The ones in the 2 until 4th The performance diagrams shown are each represented in such a way that the power is specified in percent on the Y-axis, which is plotted against the time specified on the X-axis. The specified power relates to the respective individual nominal power of the individual magnetrons, so that at 100% the entire theoretically available power of a magnetron is called up.

2 shows a performance diagram in the first power sub-range Lt1 of the upper performance range L1 , 3 the second power section Lt2 of the upper performance range L1 and 4th the lower performance range L2 .

A total of three graphs are shown in the respective graphs, the graphs being a first performance curve 10 (long dashed line) of a first magnetron, a second power curve 12th (dotted) a second magnetron and a third power curve 14th Include (dashed) a third magnetron.

In the in 2 The power diagram shown is the total power of the three magnetrons 10 , 12th , 14th exactly 80% of the total nominal power. A comparison with 1 makes it clear that this overall performance corresponds to the first performance sub-range Lt1 of the upper performance range L1 is to be assigned.

• Zu dem Zeitpunkt t0 befinden sich das erste Magnetron 10 und das zweite Magnetron 12 in Betrieb, wobei die beiden Magnetrons 100 % ihrer jeweiligen Nennleistung abrufen.

This partial output of the total nominal output is achieved by the magnetron 10 , 12th , 14th are each switched clocked. The clocked switching of the magnetrons works as follows:

• The first magnetron is located at time t0 10 and the second magnetron 12th in operation, with the two magnetrons calling up 100% of their respective nominal power.

At time t1, the third magnetron becomes 14th switched on, so that from time t1 all three magnetrons 10 , 12th , 14th are in operation and thus define a first service phase Lp1.

This operating state or this first service phase Lp1 lasts until time t2, at which the first magnetron 10 is turned off so that the first magnetron 10 an idle period or pause P. inserts and only the second magnetron 12th and the third magnetron 14th are in operation. This represents a second service phase Lp2 represents in which only two of the three magnetrons 10 , 12th , 14th operate.

At time t3, the first magnetron becomes 10 switched on again, so that again all three magnetrons 10 , 12th , 14th operated simultaneously.

This operating state corresponds to that from time t1, since there too all three magnetrons 10 , 12th , 14th were switched on, so again the first performance phase Lp1 is present.

At time t4, the second magnetron becomes 12th switched off, which means that only the first magnetron is left 10 and the third magnetron 14th are in operation, which in turn results in the second service phase Lp2 is present.

During this second service phase Lp2 there is always one of the three magnetrons 10 , 12th , 14th in an idle phase P. , with the magnetron 10 , 12th , 14th correspondingly periodically between the three magnetrons 10 , 12th , 14th changes. In the time period t4 to t5, it is the second magnetron 12th .

The second magnetron 12th is switched on again at time t5, so that all three magnetrons 10 , 12th , 14th are in operation and again the first service phase Lp1 form.

This operating state is maintained until time t6, since then the third magnetron 14th is switched off so that only the first magnetron remains 10 and the second magnetron 12th are switched on.

The third magnetron 14th is then switched on at t7, so that from time t7 all three magnetrons again 10 , 12th , 14th operated simultaneously.

The point in time t7 thus corresponds to the point in time t1, the control method of the individual magnetrons 10 , 12th , 14th repeated periodically.

The periodic repetition of the activation results in a homogeneous load distribution on the individual magnetrons 10 , 12th , 14th and leads to the fact that the individual magnetrons have a clocking time TZ that results from the time span between two switch-on times.

Using the example of the third magnetron 14th can the clocking time TZ to be determined. The magnetron 14th is switched on at time t1 and at time t7, so that the clocking time TZ also corresponds to the time between t7 and t1.

The other two magnetrons 10 , 12th have exactly the same cycle time TZ on. They are only switched at a different time. This results, for example, from the two switch-on points of the first magnetron 10 at times t3 and t9.

The time span between times t7 and t1 also constitutes an activation period AP of the entire cooking appliance, thus the clocking time TZ of the individual magnetrons 10 , 12th , 14th is equivalent to.

The periodicity can be identified using several characteristics. On the one hand, the idle phases are repeated P. periodically, since the third magnetron first 14th (t0 to t1), then the first magnetron 10 (t2 to t3), later the second magnetron 12th (t4 to t5), after which the third magnetron again 14th (t6 to t7) etc. are switched off.

On the other hand, the second work phases take place Lp2 periodically, as they exactly match the idle phases P. correspond.

The first work phases Lp 1 however, fill the gaps in the second service phases Lp2 which means they are also periodic.

The cooking appliance itself is therefore operated periodically overall, with the individual magnetrons 10 , 12th , 14th can also be operated periodically, but with a time delay.

It becomes clear that the control method is designed in such a way that the magnetrons 10 , 12th , 14th can be switched periodically clocked staggered in time, as a result of which a partial output of the total nominal output can be generated. In the example shown, the specific Design of the idle phases P. and work phases Lp1 of the individual magnetrons 10 , 12th , 14th a partial output of 80% of the total nominal output can be provided.

From the power diagram shown in this way, it becomes clear that two magnetrons are both in the first power phases Lp1 as well as in the second work phases Lp2 are in use at the same time.

In the power section shown Lt1 there are even two magnetrons permanently in use, although in the service phases Lp1 three magnetrons are turned on at the same time.

Because of the clocked magnetrons 10 , 12th , 14th as well as their same cycle times TZ is achieved that the magnetrons 10 , 12th , 14th can be operated evenly, thereby avoiding inhomogeneous wear.

In the performance diagram of the 3 is the second sub-area Lt2 of the upper performance range L1 shown, which is also characterized by the fact that two of the three magnetrons 10 , 12th , 14th are at least temporarily in operation at the same time.

In the example shown, the second power sub-range Lt2 the total output is 45% of the total rated output of the cooking appliance.

At time t0, the first magnetron becomes 10 operated with the other two magnetrons 12th , 14th are turned off. This operating state represents a third service phase Lp3 represents in which only a single one of the three magnetrons 10 , 12th , 14th is operated.

At time t1, the second magnetron becomes 12th switched on so that the first magnetron 10 and the second magnetron 12th operated at the same time, which in turn is the already known second performance phase Lp2 corresponds to in which two of the three magnetrons 10 , 12th , 14th operated simultaneously.

At time t2, the first magnetron 10 switched off, so that from time t2 only the second magnetron 12th is in operation, the third magnetron at time t3 14th is switched on.

The second magnetron is up to time t4 12th and the third magnetron 14th switched on because at time t4 the second magnetron 12th is switched off again, whereby only the third magnetron until time t5 14th is switched on.

The first magnetron then becomes at time t5 10 switched on again, whereby the first magnetron up to time t6 10 and the third magnetron 14th are in operation at the same time.

The third magnetron 14th is switched off at time t6, which means that only the first magnetron is left 10 is in use until at t7 the second magnetron 12th to the first magnetron 10 is switched on.

Both magnetrons are then in operation until the first magnetron 10 is switched off again at t8.

From the second performance sub-area Lt2 thus works in the same way as the first power section Lt1 show that the three magnetrons 10 , 12th , 14th are each switched clocked and at least two of the three magnetrons 10 , 12th , 14th are partially or temporarily in operation at the same time in order to achieve the desired target output of the total nominal output. These sections in turn correspond to the work phases Lp2 , which are already from the first power section Lt1 are known.

The individual magnetrons 10 , 12th , 14th are in turn switched with a time offset from one another, with the clocking times TZ of the individual magnetrons are exactly the same. For the second magnetron 12th there is, for example, a clocking time TZ , which is defined over the time span t1 to t7.

The clocking time TZ of the individual magnetrons 10 , 12th , 14th also corresponds in the second power section Lt2 the activation period AP of the entire cooking appliance.

Overall, the two power sub-areas form Lt1 , Lt2 therefore a performance area L1 from where the magnetrons 10 , 12th , 14th are switched clocked and at least in the power phases Lp2 two magnetrons can be operated at the same time.

4th shows a performance diagram of the three magnetrons 10 , 12th , 14th in a lower performance range L2 of the cooking appliance, the diagram shown specifically showing a total output of 25% of the total nominal output.

This partial performance is achieved by the fact that the magnetrons 10 , 12th , 14th in turn are switched evenly clocked, with fourth power phases Lp4 occur in which no magnetron is in operation. In the fourth service phase, the cooking appliance is generally in operation, but the magnetrons do not deliver any power.

The first magnetron is at time t0 10 switched on, this being switched off at time t1, so that the fourth power phase occurs up to time t2 Lp4 which results from the idle phases P. of all magnetrons 10 , 12th , 14th excels.

The second magnetron then becomes at time t2 12th switched on, which remains switched on until time t3 and thus the known third power phase Lp3 of the cooking appliance.

From t3 the second magnetron becomes 12th turned off again, so there was another break P. of all magnetrons 10 , 12th , 14th results up to time t4.

At time t4, the third magnetron becomes 14th switched on, which remains switched on until time t5, so that from time t5 again none of the three magnetrons 10 , 12th , 14th is in operation.

The first magnetron 10 is switched on at t6 until time t7, again none of the three magnetrons being in operation from time t7, since the second magnetron is not in operation until t8 12th is switched on.

Overall, the result is that the magnetrons 10 , 12th , 14th also in the lower performance range L2 exactly the same cycle times in each case TZ have, since the period between t8 and t2 is the clocking time TZ of the second magnetron 12th dictates which of those of the other two magnetrons 10 , 14th is equivalent to.

The individual third work phases Lp3 are therefore always the same length, so that also the fourth work phases Lp4 are the same length.

In the 2 until 4th thus became the two service areas L1 , L2 shown, with the upper power range L1 two performance sub-areas Lt1 , Lt2 has, which in the 2 and 3 are shown.

In the respective service areas L1 , L2 as well as the service sub-areas Lt1 , Lt2 the durations of the power phases Lp can be adapted in such a way that the desired partial power of the total nominal power is provided.

The power phases of the individual magnetrons 10 , 12th , 14th are, however, equal to one another at a certain nominal output of the cooking appliance, which means that the magnetrons 10 , 12th , 14th are evenly loaded.

Due to the periodically uniform control of the individual magnetrons 10 , 12th , 14th assigns each performance area L1 , L2 as well as each performance sub-area Lt1 , Lt2 two work phases Lp each.

Furthermore, the clocking times are TZ of the individual magnetrons 10 , 12th , 14th with a certain target output of the cooking device always the same length and correspond to the activation period AP of the entire cooking appliance.

The magnetrons 10 , 12th , 14th are also switched between zero and full power.

Overall, the control method according to the invention has achieved that the respective magnetrons are controlled uniformly, so that the load is homogeneously distributed over the magnetrons, whereby each individual magnetron is correspondingly minimally loaded.

Claims (8)

Method for controlling a cooking appliance which comprises at least two magnetrons (10, 12, 14) which together generate a total power that can be subdivided into several power ranges (L1, L2), the magnetrons (10, 12, 14) being switched and clocked are partially in operation at the same time at least in a certain power range (L1). Procedure according to Claim 1 , characterized in that the magnetrons (10, 12, 14) are controlled in such a way that the same clocking times (TZ) are formed in each case. Procedure according to Claim 1 or 2 , characterized in that the magnetrons (10, 12, 14) are switched to one another at different times. Method according to one of the preceding claims, that the specific power range (L1) can be subdivided into power sub-areas (Lt1, Lt2) in which the magnetrons are controlled differently, the number of power sub-areas (Lt1, Lt2) being one less than the number of magnetrons (10, 12, 14) is. Method according to one of the preceding claims, that the specific power range (L1) is an upper power range which lies between 100% of the total power and a limit value which is defined via the reciprocal of the number of magnetrons (10, 12, 14). Method according to one of the preceding claims, that in a further power range (L2) at most one magnetron (10, 12, 14) is in operation at the same time. Procedure according to the Claims 5 and 6th that the further power range (L2) is a lower power range, in particular a range between 0% of the total power and the limit value. Method according to one of the preceding claims, that a total of three mangetrons (10, 12, 14) are provided which are controlled.

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