DE102004003126A1 - Driving method for heating elements and device - Google Patents

Abstract

The method according to the invention makes it possible to have a subarea (30, 32) of a heating field consisting of a plurality of subelements (30a, 30b, 30c, 32a, 32b, 32c, 32d, 32e, 32f, 32g) with a freely selectable and uniform over the entire subarea operate distributed power, even if the heating elements (30a, 30b, 30c, 32a, 32b, 32c, 32d, 32e, 32f, 32g) can deliver only power with discrete power levels. For this purpose, some heating elements are operated with the highest power, possibly a heating element in the cycle mode and the remaining heating elements remain without performance.

Description

The The invention relates to a driving method for a partial area of a heating surface the features of the preamble of claim 1 and a device and a hob, where the driving method application place.

at modern hobs with several burners, each with one or more heating elements will increase the power output of the hobs controlled by dependent from a given target power at the heating elements individual Half-waves are hidden in the AC supply, so that the desired Target power achieved by not hidden half-waves becomes. A disadvantage of this solution is that it is too much with an increasing number of heating elements huge Fluctuations in the power consumption of the hob can occur if several heating elements hide half-waves parallel to each other.

Of the Invention is based on the object, a driving method for one Part of a heating field consisting of individual heating elements but it should be possible with the procedure, over this Subarea a uniform and to achieve a specifically determinable power output.

Is solved this task by a driving method with the features of claim 1. Advantageous and preferred embodiment of The invention are specified in the further claims and are in following closer explained. The wording of the claims is by express Reference made to the content of the description.

• 1. Ermitteln einer vorgegebenen Soll-Leistung P_Soll,
• 2. Errechnen einer höchsten Zahl n_On von Heizelementen, die bei jeweils höchster Leistungsstufe gemeinsam die Soll-Leistung P_Soll nicht überschreiten,
• 3. Errechnen der Leistungsdifferenz P_Muster zwischen der Soll-Leistung P_Soll und einer von der ermittelten Zahl n_On von Heizelementen bei höchster Leistungsstufe abgegebenen Leistung P_On,
• 4: Festlegen von n_Muster Mustern von Takten mit gegebenenfalls verschiedenen Leistungsstufen, die im Mittel zu einer Leistungsabgabe von P_Muster führen, wobei n_Muster maximal (n_Bereich-n_On) beträgt,
• 5. Betreiben von n_On Heizelementen mit höchster Leistungsstufe, n_Muster Heizelementen im Musterbetrieb, das heißt mit der jeweilig vom jeweiligen Muster vorgegebenen Leistungsstufe, und (n_Bereich-n_On-n_MusterHeizelementen ohne Leistungsabgabe und
• 6. permanenter Wechsel der Zuordnung der unter 5. angegebenen Funktion zu den tatsächlichen Heizelementen in einem Rotationsverfahren, wobei die festgelegten Muster durchlaufen und nach Beendigung jeweils wieder neu begonnen werden.

According to the invention, the driving method for a subarea of a heating surface with n _{heating surface heating} elements, wherein the subarea n _{range has} heating elements with discrete power levels, of six process steps, of which the steps 1 to 4 are preparatory and the steps 5 and 6 are performed permanently during the heating process :

• 1. determining a predetermined desired power P _desired ,
• 2. Calculating a highest number n _On of heating elements that together do not exceed the target power P _set at the highest power level,
• 3. calculating the power difference P between _patterns of the target power P _set and an output from the determined n number of heating elements _on at maximum power output P _On,
• 4: specifying n _{patterns of} patterns of clocks with possibly different power levels, which lead on average to a power output of P _pattern , where n _{pattern is} maximum (n _range -n _On ),
• 5. Operating n _On heating elements with highest power level, n _pattern heating elements in the _pattern mode, that is, with the respective power level given by the respective pattern, and (n _range -n _On -n _pattern heating elements without power output and
• 6. permanently changing the assignment of the function specified under 5. to the actual heating elements in a rotation process, passing through the defined patterns and restarting each time after completion.

The heating surface can be both a heating surface for only one cooking vessel having a plurality of heating elements, so that the heated surface can be adapted to the size of the cooking vessel, as well as a heating surface for one or more cooking vessels, in which the cooking vessels can be arranged arbitrarily on the heating surface and in which the heating surface is divided into a plurality of elements which can be controlled separately, so that specifically only the heating elements are supplied with energy, which are arranged so that they stand on the heating surface cooking vessels can heat up. The partial area can also be the entire heating surface with all n _{heating surface} heating elements. The heating elements have discrete power levels that determine what amount of power they can deliver. In the smallest case, there are two power levels, with one of the power levels 0% of the maximum power are delivered and the other of the power levels 100% of the maximum power are delivered. For example, a heater with four discrete power levels could deliver 0%, 33.3%, 66.6%, and 100% of its maximum power. The power to be determined in the first step of the method can be set directly by an operator or originate from a control unit which, for example, on the basis of an automatic cooking program or a manual input with certain performance curves, the target power P _setpoint . The target power P _target should be the maximum output of all heating elements of the sub-area at the highest power level can not be exceeded. In the second step, the number of heating elements is determined which, when operating at the highest power level, together approach as close as possible to the desired power P _setpoint without exceeding it. The number of these heating elements n _on is zero in the least case, if already the power output of a heating element at the highest power level would exceed the target power P _set , and in the highest case n _range , provided that all heating elements of the sub-range at the highest power level, the target power P _Should just reach or the target power P _{target is} above the maximum achievable by all heating elements of the sub-range power. In the third method step, it is determined how large the difference between the power P _On which can be output by n _On heating elements at the highest power level and the desired power P _Soll is. This power must be applied by one or more heating elements which can not be consistently operated at the highest power level, so as not to exceed the power P _desired . If this power difference P _{pattern is} not zero, in the fourth method step, a number n _patterns of patterns are composed of clocks of different power levels, which can achieve this power difference P _pattern . The patterns consist of any number of bars of equal length, each executed at a particular power level. The respective average power outputs of these patterns must sum up the power difference P _pattern . Due to the fixed number of clocks and the discrete power levels of the heating elements, it is not necessarily possible to achieve the power P _pattern exactly. By increasing the number of bars per pattern and increasing the number of discrete power levels, a more accurate fit can be made possible, which is not normally required. Although the method in principle allows to use more than one pattern of clocks with different power levels, preferably only one pattern should be defined, which runs on a heating element in the pattern mode. The number of samples shall not exceed the number n _range of heating elements in the sub-area less the number n _On of heating elements operating at the highest power level.

Within these first four process steps are therefore the number of heating elements, the highest Power stage, the number of heating elements in the model operation, and the patterns themselves set.

in the actual operation of the heating elements of the subregion are the Functions "Power output at highest Power level "," power output according to specified Pattern "and" None Power output "rotating assigned to the heating elements of the subarea. Unless in the preparatory Steps one to four so it was established that it Each will give at least one heating element of each function Heating element in the sub-area rotating also assigned to each function. After each fixed number of cycles, preferably in each case after each bar, the function assignment continues to rotate. As a result, be all heating elements, over averaged the duration of the samples, operated at approximately the same power. Nevertheless, it is despite the discrete power levels of the heating elements always only with respect a heating element - that Heating element, which is currently operating in pattern mode - required, to control an adjusted power output. The other heating elements are each operated without power output or at the highest power level. The heating elements are preferably induction heating elements.

In a further development of the method, the number n _{patterns of} the pattern is one. This represents a particularly expedient embodiment of the method, since in each case only one heating element is in the pattern mode. As a result, the remaining heating elements are operated at full power or are not in operation.

In In a further development of the method, the discrete power levels the heating elements by the omission of individual half-waves of a Clock in the AC power supply generated.

In this form of driving, a number of half waves, which is preferably straight, are combined into one clock. By omitting a different number of half waves within such a clock, the various discrete power levels can be achieved. If standards or regulations stipulate that the negative and positive halfwaves must be balanced within a certain number of halfwaves, the result is a reduced number of power stages. In the case of six-half cycle clocks, where the number of negative and positive halfwaves per clock must be balanced, the four alternatives for the clock have zero halfwaves, two halfwaves, four halfwaves, or six halfwaves. Such a clock can therefore assume the discrete power levels "no power output", "one-third of the maximum power", "two-thirds of the maximum power" and "maximum power". Particularly advantageous in the use of the driving method according to the invention with clocks which differ by omitting half-waves with respect to their power output is the minimization of fluctuations in the power consumption of the heating field, since in the sub-areas only the pattern-driven heating elements, preferably only one heating element, alternating half-waves partly omit and sometimes not omit.

In one embodiment of the invention, the pattern is composed exclusively of clocks of two different power levels, wherein no power is delivered at the one power level and wherein it is at the other power level to the power difference P _pattern next higher power level.

at Such a method is the number of clocks in which a Intermediate between no power output and the maximum Power is applied, as far as possible reduced. This is in Meaning of a simple control of the heating elements advantageous.

In another embodiment of the method, the pattern is composed exclusively of clocks of two different power levels, wherein it is at the one power level to the power difference P _pattern next higher power level and the other power level to the power difference P _pattern next lower power level. In this way, a relatively balanced power output is achieved.

In In a further development of the method, the clocks are different Performance levels evenly in the pattern distributed. The even distribution The clocks of different power levels will cause the power output within the duration of a passage through the pattern is very even.

In a further development of the method, the clocks are arranged in blocks of identical power levels in a pattern. This is the simplest way to distribute the bars of different power levels within the pattern. With regard to a control device for such a method, this offers the advantage that the control unit can specify clocks of a higher power level as long as the required power P _{pattern has been achieved} within the pattern, and thereafter only cycles without it until the end of the pass through the pattern Specify power output.

In a further development of the invention, the number of cycles of the pattern is a prime number, which is greater than the number of heating elements n _{area of} the subarea, preferably greater than the number of heating elements n _{heating surface of} the entire heating surface.

By means of such a determination of the number of cycles of the pattern is achieved that no irregular distribution occurs in the rotating assigning the functions to the heating elements. Such an irregular distribution could cause a heating element to be in pattern operation again and again at the same strokes of the pattern and, as a consequence, the power output across the subarea would be inhomogeneous. By selecting such a prime number as the number of strokes of the pattern, each heating element has the function of "power output according to pattern" as the first heating element in each pass through the pattern It is particularly useful if the number of strokes of the pattern is greater than the number of strokes is heaters n _{heating area} of the entire heating surface. such a method does not require that depends on the number n _area of the heating elements in the partial area in each case a prime number are determined must instead. a uniquely determined for the entire heating surface prime will always be used These may be fixed in one. Control unit programmed to perform the method.

The The object underlying the method can also be achieved by a device preferably a control unit, to be used to control heating elements of a hob, this device being adapted to the described method perform.

A such device can be part of several heating elements a hob.

In Further development of such a hob are preferred as heating elements Induction facilities provided.

These and further features of preferred embodiment of the invention go out from the claims also from the description and the drawings, wherein the individual features in each case alone or to several in the form of subcombinations in one embodiment of the invention and in other fields be realized and advantageous also for protectable versions can represent for the protection is claimed here.

Summary the drawings

embodiments The invention are shown schematically in the drawings and will be closer in the following explained. In the drawings show:

1 a schematic representation of the method,

2 a plan view of a heating surface with two operating subregions,

3 a pattern of 41 clocks, in which for each clock for each of the three heating elements of the first sub-range, the power output is set,

4 a pattern of 41 clocks, in which for each clock for each of the seven heating elements of the second sub-range, the power output is set,

5 three operating states of the first of the two operating areas of 2 .

6 seven operating states of the second of two operating areas of 2 and

7 a representation of a complete pattern of 41 clocks, which is shown for each clock, what is the power output and which of the heating element just maximum power, which gives the heater no power and which of the heating elements power according to pattern specification.

detailed Description of the embodiments

In 1 is shown a schematic representation of the method according to the invention. Input parameters of the method are the maximum power P _{heating element} , each of which can emit a heating element, the number of heating elements n _range , which belong to the partial area to be heated, and the power P _target to be achieved in the entire _subrange . Starting from these given values becomes in a first step 10 determines the number n _On of heating elements that in operation at full power P _{heating element} the total target power P _set just barely. In a subsequent step 12 the power P _{On is} calculated, which makes this number n _On of heaters at full power P _{heating element} in operation. In the following step 14 the power difference P _{pattern is} calculated, which is between the total target power P _target and the power P _On of n _On heating elements at each full power P _{heating element} . In a next step 16 n _{Patterns are} set, which are composed of bars of possibly different performance levels and the average sum together the performance P _pattern yield. The number of bars per pattern n _{TakePro pattern} is fixed in the present case. Alternatively, however, it would also be possible to flexibly determine the number of clocks per pattern n _{clock samples} depending on other values, preferably the number n _{range of} the heating elements in the partial area.

In the phase 18 In operation, the heating elements are operated on the basis of the determined values and the specified pattern. The heating elements can basically perform one of three different functions. A number n _on of heating elements is operated with maximum power P _{heating element} . A number n of _patterns of heating elements, which is preferably only one heating element, are included in step 16 operated patterns. The remaining heating elements of the sub-area do not deliver any power. The assignment of these functions to the actual heating elements changes permanently. At short intervals, preferably at intervals of the time length of a clock, the assignment is changed.

2 shows a heating surface with a total of 38 heating elements. The maximum power of each heating element is 300 watts. Two sections 30 . 32 the heating surface are in operation. The subarea 30 consists of a total of three heating elements 30a . 30b . 30c , The target performance of this subarea 30 is 360 watts. The second part 32 consists of a total of seven heating elements 32a . 32b . 32c . 32d . 32e . 32f . 32g , The target power of this second subarea 32 is 1350 watts.

To the target power of 360 watts in the subrange 30 To achieve a heating element is operated with its maximum power of 300 watts and a second heating element in the pattern mode, that is, operated with a pattern of clocks of different power levels. This is so that it leads over the length of a complete passage to a power output of about 60 watts. A third heating element of the part range 30 is not needed to reach the target power of 360 watts. In the illustrated operating state of the subarea 30 becomes the crosshatched heating element 30b operated with its maximum power of 300 watts, the field simply hatched 30a operated with the pattern and the heating element 30c has no power delivery.

To the target power of 1350 watts with respect to the second sub-range 32 to achieve a total of four heating elements are operated with their full power of 300 watts and another heating element operated in the model mode. Two heating elements of the subarea 32 are not needed to reach the target power of 1350 watts. In the illustrated operating state, the four fields 32a . 32e . 32f . 32g each from their maximum power. The heating element 32d is operated with the pattern. The two heating elements 32b . 32c give no performance.

The 3 and 4 show the drive patterns 34 . 36 each located in the pattern mode heating elements of the sections 30 . 32 , Since the total heating surface has thirty eight heating elements is called the number of cycles per pattern 41 chosen as the next prime. The patterns accordingly consist of forty-one clocks, with each clock being able to take on one of four discrete power levels. The power levels are 0%, 33.3%, 66.6% and 100% of the power. Converted to absolute power, this means that the power levels are 0 watts, 100 watts, 200 watts and 300 watts.

The heater operated with the pattern in the first section 30 For example, the power difference between the target power of 360 watts and that of the one heater operated at maximum power must be 300 watts. Since the power difference of 60 watts is still below the second of the discrete power levels of 100 watts, the pattern is composed of clocks with 0 watts of power and 100 watts of power. In 3 is the corresponding pattern 34 shown. It consists of 25 clocks with 100 watts of power and 16 clocks with 0 watts of power. The clocks of the same power are combined into blocks. For the entire pattern results in the average power of 60.97 watts. Based on the entire subarea 30 This results in an average output of 360.97 Watts over one run of the sample. This is only slightly above the target power of 360 watts for this subarea 30 ,

4 shows the pattern 36 of the patterned heating element of the subregion 32 , The of this heating element of the subarea 32 applied power is 150 watts. The next highest discrete power level is 200 watts. The pattern has 31 cycles with the discrete power level of 200 watts. In addition, the pattern shows ten bars without power output. As with the pattern of the first section 30 also is the pattern of the second section 32 divided into blocks with bars of the same power level. The power dissipated by the AC heater in this pattern is, on average, 151.21 watts over a single pass of the sample. Together with the four heating elements of the second section 32 Operating at full power, this results in a total output of 1351.21 watts. This is the target power of the second section 32 exceeded just over a watt.

5 and 6 show the different assignments of the functions of the heating elements to the different heating elements for the first part 30 and the second subarea 32 , The cross-hatched heating elements are each the heating elements that are operated at maximum power. The simply hatched heating elements are the heating elements on which runs the respective pattern of the sub-area.

5 shows three operating states of the first subarea 30 , In operating condition 40 becomes the heating element 30b operated at full power, the heating element 30a with the pattern 34 operated and the heating element 30c not operated. After a fixed time, preferably after one cycle of the pattern, the heating elements change their assignment to the functions, so that the second operating state 42 established. This is followed by the third operating state after the same period of time 44 , Subsequently, the system returns to the first operating state 40 continued. It can be seen that in this way each of the heating elements has once taken over each function. By choosing the prime number 41 the number of strokes of the pattern is achieved so that the same heating element does not begin to execute the pattern on each passage through the pattern. In the event that the pattern on the first pass on the heating element 30a started, it will be the second pass with the heating element 30b kick off. In this way it is ensured that the heating elements deliver very evenly.

6 shows the assignment of the functions to the heating elements for the second partial area 32 , The second part 32 has a total of seven different phases 50 . 52 . 54 . 56 . 58 . 60 . 62 on. In the phase 50 represents the heating element 32g the heating element, according to the pattern 36 Delivers performance. The four hei zelemente 32b . 32c . 32d . 32e are operated at full power. The two heating elements 32a . 32f are operated without power. Each time you change from one phase to the next, the assignment changes so that after seven phase changes, each heater will fire a total of four times at full power, twice at no power, and once in accordance with the pattern 5 was operated. This results in one for the entire second subarea 32 uniform power output.

7 shows for the first section 30 a complete run through the pattern. It is shown for each of the 41 clocks, which heating element is in the respective clock in the alternating mode and thus performs a power output according to the pattern. The pattern starts with phase 70 in which the heating element 30a represents the Wechselheizelement. Starting from there, the assignment of the functions to the heating elements of the subarea becomes with each clock 30 changed. During the first 25 cycles, the power output of the Wechselheizelements is 100 watts each. At the next 16 bars, from phase 95 until phase 110 the power output of the Wechselheizelements is 0 watts. Thus, after a complete run of the pattern, 1. that the heating element 30a 14 bars long with 300 watts, 9 bars long with 100 watts and 18 bars long with 0 watts, average so with 124.39 watts was operated, 2. that the heating element 30b 14 bars long with 300 watts, 8 bars long with 100 watts and 19 bars long with 0 watts, average so with 121.95 watts was operated and 3. that the heating element 30c 13 bars with 300 watts, 8 bars with 100 watts and 20 bars with 0 watts, average so with 114.63 watts was operated.

In that the next pass through the pattern the heating element 30b starting with the execution of the pattern, it is achieved that these differences in performance during longer operation are compensated.

Claims (11)

Driving procedure for a subarea ( 30 . 32 ) of a heating surface with n _{heating surface} heating elements, wherein the subregion ( 30 . 32 ) n _area heating elements ( 30a . 30b . 30c . 32a . 32b . 32c . 32d . 32e . 32f . 32g ) with discrete power levels, whereby it is possible with the method, one over the subrange ( 30 . 32 ) to achieve uniform and specifically determinable power output, with the preparatory process steps: 1. Determining a predetermined target power P _Soll , 2. Calculate a highest number n _On of heating elements that do not exceed the target power P _setpoint at the highest power level 3. calculating the power difference P between _patterns of the target power P _set and an n _on heating elements at the highest power level output by the determined number of power P _on, 4. setting n _pattern patterns ( 34 . 36 ) of clocks with possibly different power levels, which lead on average to a power output of P _pattern , where P _{pattern is} maximum (n _range -n _On ), and the method steps in the execution of: 5. operating n _On heating elements with highest power level, n _pattern heating elements with the power level specified by the respective pattern and (n _range -n _on -n _pattern ) heating elements without power output and 6. permanent change of the assignment of the functions specified under 5 to the actual heating elements ( 30a . 30b . 30c . 32a . 32b . 32c . 32d . 32e . 32f . 32g ) in a rotation process, whereby the established patterns ( 34 . 36 ) and restart each time after completion. A method according to claim 1, characterized in that the number of patterns n is one _pattern . Method according to claim 1 or 2, characterized that the discrete power levels of the heating elements by the omission individual half-waves of a clock in the AC power supply are generated. Method according to one of claims 1 to 3, characterized in that the pattern ( 34 . 36 ) is composed exclusively of bars of two different power levels, with the one quiet no power is output and where the other power level is the power level next to the power difference P _pattern . Method according to one of claims 1 to 3, characterized in that the pattern is composed exclusively of cycles of two different power levels, wherein it is at the one power level to the power difference P _pattern next higher power level and at the other power level to the power difference P _pattern next lower power level. Method according to one of the preceding claims, characterized characterized in that the bars of different power levels evenly in the pattern are distributed. Method according to one of claims 1 to 5, characterized in that the clocks in blocks of equal power levels summarized in the pattern ( 34 . 36 ) are arranged. Method according to one of the preceding claims, characterized in that the number of cycles of the pattern ( 34 . 36 ) is a prime number greater than the number of heating elements ( 30a . 30b . 30c . 32a . 32b . 32c . 32d . 32e . 32f . 32g ) n _{area of} the subarea ( 30 . 32 ), preferably the number of bars of the pattern ( 34 . 36 ) is greater than the number of heating elements n _{heating surface of} the entire heating surface. Device, preferably control device, for controlling heating elements ( 30a . 30b . 30c . 32a . 32b . 32c . 32d . 32e . 32f . 32g ), in particular for controlling heating elements ( 30a . 30b . 30c . 32a . 32b . 32c . 32d . 32e . 32f . 32g ) of a hob as a heating surface, characterized in that it is designed for carrying out the method according to one of claims 1 to 8. Hob as a heating surface with several heating elements ( 30a . 30b . 30c . 32a . 32b . 32c . 32d . 32e . 32f . 32g ) and a control device for controlling the heating elements ( 30a . 30b . 30c . 32a . 32b . 32c . 32d . 32e . 32f . 32g ), characterized in that the control device is a device according to claim 9. Hob according to claim 10, characterized in that the heating elements ( 30a . 30b . 30c . 32a . 32b . 32c . 32d . 32e . 32f . 32g ) Induction devices are.