EP0197604A2 - Cooking stove with a device for the automatic control of the heating process of a cooking device - Google Patents

Abstract

Cooker automatically controlling the heating process when bringing a food material to the boil on an electric hotplate and preventing it from boiling over at the end of the heating process. At the beginning of the heating process the power supplied to an electric hotplate can be set to a constant value which can be selected. A microprocessor continuously determines the rise in the temperature of the base of the pan as a function of time. At a pan-base temperature above about 70 DEG C. the actual value of the rise in temperature is compared with a present desired value and when deviations occur the heating power is switched over so as to approximate the actual value of the rise in temperature to the desired value. At a pan-base temperature above about 90 DEG C. a bending point in the temperature rise of the pan base is reached after which the heating power is switched off.

Description

The invention relates to a cooker with a device for automatically regulating a parboiling process of an electric cooking device to avoid overcooking at the end of the parboiling process, the temperature rise of the bottom of the cooking vessel being continuously determined during the parboiling process by means of a temperature sensor.

Two methods are known with which the electrical parboiling is preprogrammed to some extent. One method is time control, the other method is temperature-dependent control (see HEA picture service, August 1983, main advice center for electricity application eV, Frankfurt am Main, series electric cooker). With the time control, the owner has the option of setting the energy for the parboiling process and thus also taking large or small parboiling quantities into account. However, there is no automatic regulation; This does not prevent boiling over or switching off too early if the presetting is incorrect. The temperature-dependent control is better suited to the parboiling problem. A distinction is made between an adjustable temperature (2 or 3 point thermostat, EGO system) and a fixed temperature point (125 ^o C floor temperature, bimetal controller from Siemens). With such a regulation, a temperature sensor is arranged in a central zone free of electrical heating elements, which presses against a spring-loaded cap. This cap is off the bottom of the cook vessel depressed, so that a thermal contact is made between the sensor and the bottom of the cooking vessel. The parboiling power is switched off via the sensor.

Even the temperature-controlled switch-off of the parboil phase cannot be completely satisfactory, since the correct switch-off point is in no way linked to a fixed floor sensor temperature. The switch-off point depends on a number of other parameters, such as Filling quantity, heat capacity of the food to be cooked, heating power, shift of the cooking point due to dissolved substances (increase in boiling point) or even to a small extent from the barometer reading at the cooking location. It takes some experience of the user to find the approximate correct setting for the right pot, the filling quantity and the selected food. The presetting is generally so unreliable that no user with the devices currently on the market, e.g. Allow milk to boil unattended. Either the boil-up heating power is switched off too late, then the pan must be removed from the electric hotplate to prevent over-bubbling or boiling over, especially with milk, or it is switched off too soon, then there are time delays when reheating. In any case, supervision is necessary.

It is known from EP-OS 0 074 108 to use a temperature sensor to sense the pot bottom temperature in a gas cooker and to switch off the gas supply when the temperature of the pot bottom no longer rises when cooking begins. This measure is sufficient for gas cooking because the heat supply can be interrupted suddenly. With electric cooking, heat is still supplied despite the device being switched off. Switching off at the moment of the cooking point is therefore not enough.

It is an object of the invention to automatically complete the electrical heating process of water or other, at least partially liquid, cooking material without boiling over, so that, for example, milk can also be boiled without supervision.

• - zu Beginn des Ankochvorganges die Ankochheizleistung einer elektrischen Kochplatte auf einen anwählbaren, konstanten Wert einstellbar ist,
• - ein Mikroprozessor fortlaufend die Bodentemperatur des Kochgefäßes in gleichen Zeitabständen erfaßt und den Verlauf der Steigung der Topfbodentemperatur über der Zeit bestimmt,
• - der Mikroprozessor bei einer Topfbodentemperatur oberhalb von ca. 70⁰C den Ist-Steigungswert der Topfbodentemperatur mit einem Soll-Steigungswert vergleicht und bei Abweichungen die Ankochheizleistung umschaltet zur Annäherung des Ist-Steigungswertes an den Soll-Steigungswert,
• - der Mikroprozessor bei einer Topfbodentemperatur oberhalb von 90⁰C beim Abknicken des Steigungsverlaufes der Topfbodentemperatur die Ankochleistung abschaltet.

The task is solved according to the invention in that

• at the beginning of the parboiling process, the parboiling power of an electric hotplate can be set to a selectable, constant value,
• a microprocessor continuously records the bottom temperature of the cooking vessel at equal time intervals and determines the course of the rise in the bottom temperature of the pot over time,
• - the microprocessor compares the actual slope value of the pot bottom temperature with a target slope value at a pot bottom temperature above approx. 70 ⁰ C and, in the event of deviations, switches over the heating power to approximate the actual slope value to the target slope value,
• - the microprocessor switches off the pre-cooking at a pan-base temperature above 90 ⁰ C during bending of the slope profile of the pan bottom temperature.

After a short initial delay, the pot bottom temperature increases linearly with a constant slope. The size of the slope is mainly determined by the amount of the food to be cooked, its heat capacity and the size of the electrical power fed in. Before the cooking point is reached, the gradient of the pot bottom temperature bends. How long this time of kinking before reaching the boiling point again depends on the amount of the food, its heat capacity and the size of the food electrical power fed in. For this reason, the boil-up heating power is regulated above 700C cooking temperature so that the slope of the pot bottom temperature approaches a setpoint that is selected so that when the slope is switched off when the slope is bent, the energy stored in the cooking device is approximately the same or slightly larger than the energy to be supplied to the food to be cooked until it reaches its boiling point. It is then possible to switch off the heating power supply when the gradient curve is bent, so that the food to be cooked no longer receives the heating energy responsible for overcooking.

According to a further embodiment of the invention it is provided that slope value Is is changed above a predetermined magnitude to a reduced heating power at a pan-base temperature above approximately 70 ⁰ C and a.

In general, it will be expedient to adjust the parboiler heating output only downwards, that is, to reduce the parboiler heating output to a smaller value only if the actual slope value of the pot bottom temperature is too high. This applies in particular if, due to the type of food to be cooked, overheating is to be avoided too quickly as a result of excessive heating power.

• - zu Beginn des Ankochvorganges die Ankochheizleistung einer elektrischen Kochplatte auf einen anwählbaren, konstanten Wert einstellbar ist,
• - ein Mikroprozessor fortlaufend der zeitliche Temperaturanstieg des Kochgefäßbodens über der Zeit bestimmt,
• - der Mikroprozessor bei einer Topfbodentemperatur oberhalb von ca. 70⁰C den Ist-Steigungswert der Topfbodentemperatur mit einem Soll-Steigungswert vergleicht und bei Abweichungen die Ankochheizleistung umschaltet zur Annäherung des Ist-Steigungswertes an den Soll-Steigungswert,
• - der Mikroprozessor bei einer Topfbodentemperatur oberhalb von ca. 900C und einem nicht genügend nach oben in Richtung auf den Soll-Steigungswert korrigierbaren Ist-Steigungswert der Ankochheizleistung zeitlich verzögert nach dem Erreichen des Abknickpunktes des Steigungsver_- laufes der Topfbodentemperatur abschaltet.

According to another embodiment of the invention it is provided that

• at the beginning of the parboiling process, the parboiling power of an electric hotplate can be set to a selectable, constant value,
• a microprocessor continuously determines the temperature rise of the cooking vessel bottom over time,
• - The microprocessor with a pot bottom temperature above approx. 70 ⁰ C the actual slope value of the pot bottom compares the temperature with a target gradient value and, in the event of deviations, switches over the heating power to bring the actual gradient value closer to the target gradient value,
• - the microprocessor at a pan-base temperature above approximately 900C and an insufficient correctable upward in the direction to the target slope value actual slope value of the heating power with a time delay after reaching the elbow point of Steigungsver _- run off of the pan-base temperature.

If the actual slope value is below the target slope value above 70 ⁰ C pot bottom temperature and the actual slope value does not reach the desired slope value due to an increase in the heating power, or if an increase in the heating power is not intended or desired, the switch-off would Parboiling power does not come to a boil when the slope of the bottom temperature of the pan bends, since the energy stored in the cooking device would not be sufficient to bring the item to the boil. For this reason, the parboil heating power is not switched off when the gradient is bent, but rather delayed. The value of this delay in turn depends on the quantity of the food to be cooked, its heat capacity and the size of the electrical power fed in, and thus on the actual gradient value above 700 ° C cooking temperature. This method makes the cooking device accurate regardless of the set heating power and the amount and heat capacity of the food so much electrical energy supplied that the food just reaches its cooking point.

According to a further embodiment of the invention, it is provided that the microprocessor determines the actual slope value of the pot bottom temperature below 700C, which results from the parboiling power Pa and the pot content C, the determined value also being a measure of the heat capacity of the food from which the target slope value is determined.

With the known electrical power and known parameters of the cooking device, it is possible to draw conclusions about the heat capacity of the food from the course of the actual slope value of the pot bottom temperature. If the heat capacity of the food to be cooked is known, the target slope value of the pan bottom temperature, at which the food to be cooked when the heating-up power is switched off at the break-off point, can be determined.

According to a further embodiment of the invention it is provided that the pot bottom temperature is recorded at equal time intervals of less than 30 seconds, preferably 5 to 15 seconds. The detection of the pot bottom temperature should take place at intervals of less than 30 seconds for a sufficient speed of reaction of the cooking device in order to ensure that the actual course of the pot bottom temperature is recorded in good time so that the heating power can be switched off early enough. Detection at intervals of approximately 5 to 15 seconds has proven to be advantageous.

According to a further embodiment of the invention it is provided that the slope of the pot bottom temperature is averaged over several values. The risk of an incorrect reaction can also be reduced by averaging the slope calculated from the individual measurements of the pot bottom temperature over several values, so that individual outliers are less important when recording the pot bottom temperature and thus the risk of a wrong reaction of the automatic control of the Parboiling is reduced.

According to a further embodiment of the invention it is provided that after switching off the parboiling power is automatically switched to a pre-setting boiling power. In this way it is possible to automatically proceed to the continued cooking process by previously setting the continued cooking output.

In the cooker according to the invention, the true cooking point is detected in good time before it is reached, regardless of the cooking temperature, which fluctuates depending on the substance concentration, the height above normal zero and the air pressure. Different amounts or heat capacities of the food are also taken into account, so that boiling does not occur even with small amounts of food or small heat capacity, and on the other hand, the boiling point is reliably reached even with a larger amount of heat or heat capacity. Furthermore, an absolute calibration of the temperature sensor is not important. All that is required is a sufficiently linear relative temperature response. Previously common cookware can therefore continue to be used unchanged. Only commercially available aluminum, steel or laminate pans are suitable for electric cooking. Critical items such as Milk, regardless of the amount, can be boiled without supervision.

• Figur 1 eine übliche Kochplatte mit einem Temperaturfühler zum Ermitteln der Topfbodentemperatur eines Elektrokochtopfes,
• Figur 2 ein Schaltschema einer Schaltungsanordnung zum Betreiben einer elektrischen Kochplatte mit dem Verfahren nach der Erfindung,
• Figur 3 ein Zeitleistungsdiagramm zum Ankochen und Fortkochen,
• Figur 4 ein Zeitdiagramm der Topfbodentemperatur und deren Steigung, die bei einem Ankochvorgang einer Kochvorrichtung auftreten, bei dem die Ankochheizleistung weder verändert, noch verzögert abgeschaltet wird,
• Figur 5 ein Zeitdiagramm der Topfbodentemperaturen und deren Steigung, die bei einem Ankochvorgang derselben Kochvorrichtung auftreten, bei dem auf eine verringerte Ankochheizleistung umgeschaltet wird,
• Figur 6 ein Zeitdiagramm der Topfbodentemperaturen und deren Steigung, die bei einem Ankochvorgang derselben Kochvorrichtung auftreten, bei dem die Ankochheizleistung unverändert bleibt, jedoch verzögert abgeschaltet wird.

The invention is explained in more detail with reference to the embodiment shown in the drawings. Show it:

• FIG. 1 shows a conventional hotplate with a temperature sensor for determining the bottom temperature of an electric saucepan,
• FIG. 2 shows a circuit diagram of a circuit arrangement for operating an electric hotplate with the method according to the invention,
• FIG. 3 shows a time performance diagram for parboiling and continued boiling,
• FIG. 4 shows a time diagram of the pot bottom temperature and its rise, which occur during a parboiling process of a cooking device in which the parboiling heating output is neither changed nor switched off with a delay,
• FIG. 5 shows a time diagram of the pot bottom temperatures and their rise, which occur during a parboiling process of the same cooking device, in which a switch is made to a reduced parboiling heating power,
• FIG. 6 shows a time diagram of the pot bottom temperatures and their rise, which occur during a parboiling process of the same cooking device, in which the parboiling heat output remains unchanged, but is switched off with a delay.

The hotplate 1 shown in section in FIG. 1 consists of a plate-shaped gray cast iron body 3, in which spiral-shaped grooves 7 are provided from the underside 5. In this spiral grooves 7 heating coil 9 are inserted.

In a central zone 11 free from the heating coils 9, a guide sleeve 13a is inserted into a holding sleeve 13 which is fixedly connected to the hotplate 1 and has an inwardly projecting shoulder 17 on the underside 15. On this paragraph 17, a coil spring 19 is supported, which strives to press a contact hat 21 upwards against the bottom of an attached cooking vessel. A temperature sensor 23 is provided within the spring 19, which is in contact with the underside 25 of the hat 21. The temperature sensor 23 is largely decoupled from the thermal influence by the hotplate by means of a double-walled radiation shield 26. The bottom of a pot placed on the hotplate 1 presses the hat 21 down into the plane of the turned top 27 of the hotplate. This results in good thermal contact between the bottom of the cooking vessel and the temperature sensor 23.

FIG. 2 shows the control of the hotplate heating using a basic circuit diagram. The temperature sensor 23, which is connected to a microprocessor 27, is located in the heat-free central zone 11. In the hotplate 1 there are two separately switchable heating coils 9a and 9b. The heating coils 9a and 9b can be connected to the power supply 33 by the microprocessor 27 with the aid of a two-pole switch 31 and a single-pole switch 31a. Via the preselection buttons 29 and 35 and an energy regulator 37, with which interval control of the heating coils 9a and 9b is possible, the desired parboiling and boiling power can be specified for the microprocessor 27, so that the microprocessor can automatically switch from parboiling to the boiling process .

FIG. 3 shows a time performance diagram for the parboiling and continued boiling. As this diagram shows, pressing the button 29 or 35 preselects the heating power. Pressing one of the keys 29 or 35 is indicated by the case 39 in FIG. 3. In this example, the heating power is not changed. Arrow 41 indicates the time at which the parboiling process is ended. If continued cooking is desired, the setting of the energy regulator 37 determines the electrically fed power during the continued cooking process. The hatched areas in FIG. 3 indicate the periods in which heating power is fed into the hotplate.

Figure 4 shows the pot bottom temperature profiles and slope of a parboiling process. In this example, the quantity and heat capacity of the food to be cooked is selected so that the heating power is neither changed nor switched off with a delay. The pot bottom temperature profiles also assume that the food to be cooked is not stirred during cooking and that no new food is added.

Dieser so bestimmte Topfinhalt bestimmt mit seiner Wärmekapazität später das Sollverhalten oberhalb von 70⁰CThe food temperature TK increases after a certain time delay up to the cooking point indicated by arrow 43. The pot base temperature TB is measured with the aid of the temperature sensor 23. After a short initial delay, the pot bottom temperature increases largely linearly with a constant gradient. The size of the slope is mainly determined by the amount and heat capacity of the food to be cooked and the size of the electrical power fed in. This determination can be made according to the formula:

This so determined pot content later determines the target behavior above 70 ⁰ C with its heat capacity

For this purpose, the microprocessor 27 measures the pot bottom temperature at intervals of approximately 5 to 15 seconds and stores these values. From measured value to measured value, the microprocessor compares the current pot bottom temperature value with the previous one and determines the value of the slope ΔTB from it. This results in a curve Δ TB, which is also entered in FIG. 4. The microprocessor thus determines the actual slope value of the pot bottom temperature in the temperature range below approx. 70 ⁰ C pot bottom temperature. The heat quantity of the food to be cooked is determined from this value and from this the target slope value is determined. Above 70 ^° C., the actual gradient value is now compared with the determined target gradient value. In the example shown in FIG. 4, the actual gradient value is approximately 12 Kelvin per minute. It is assumed that this value corresponds approximately to the target slope value determined. For this reason, the parboiling power is not changed in the example shown in FIG. At a temperature above approx. 90 ^° C. pot bottom temperature, the rise in the pot bottom temperature is noticeably reduced. This area is indicated by the arrow 45 and its extension 47. In the example shown, this kinking of the slope is about 1 1/2 minutes before the boiling point is reached at arrow 43. At the moment the course of the slope of the pot bottom temperature (line 47, arrow 45) kicks off, the heating-up power is switched off. The time remaining until the boiling point is reached is sufficient to prevent boiling over even with milk.

5 shows the time profiles of the same parboiler for a parboiling process with only one liter of water shown. After the rise of temperature gradients at the beginning of the heating process, the microprocessor determines again above 70 ⁰ C pan-base temperature the value of the slope which is in the example shown in Figure 5 example, about 16 to 18 Kelvin per minute. Since this actual gradient value is above a predetermined gradient value, which for example could again be about 12 Kelvin per minute, the heating-up power is reduced, which is visible in FIG. 5 by the kink of the pan bottom temperature marked with arrow 51. After this switching over of the parboiling power, the value of the slope ATB decreases to approximately 6 Kelvin per minute, which is shown in the figure by the curve 53. The boil-off heating power is switched off again at the beginning of the kinking of the rise in the pot bottom temperature, which is marked by the arrow 45 and its extension 47. In this example, the food to be cooked reaches its boiling point about 1 minute later, which is indicated in the curve TK in the figure by the arrow 43.

FIG. 6 shows the temperature profiles of a parboiling process, again of the same cooking device, but this time with 2 liters of water. Above 70 ⁰ C pan-base temperature is the slope ΔTB in this example, only about 10 Kelvin per minute. It is assumed in this example that the parboil heating power is not increased by the microprocessor 27. Since the actual slope value of the pot bottom temperature is below an assumed nominal slope value of approximately 12 Kelvin per minute, if the heating-up power is switched off when the slope profile is bent, the pot bottom temperature would decrease, which is shown in the figure by case 45 and its extension 47 then the energy stored in the cooking device is not sufficient to bring the food to the boil. For this reason, the microprocessor determines

from the value of the slope (here about 10 Kelvin per minute) a follow-up time for the delayed switch-off of the parboiling power. In the example shown, the run-on time is approximately 1 minute.

This switch-off time calculated in this way is indicated in the figure by the arrow 63 and its extension 61. After switching off the parboiling power, the food in this example reaches its cooking temperature about 1 1/2 minutes later, which is marked in the figure by arrow 43.

Figures 4, 5 and 6 thus show three parboiling processes of the same cooking device, which is just chosen so that in the first case the actual gradient value corresponds to the target gradient value, that in the second case the actual gradient value is above the target gradient value and in the third case the actual gradient value is below the target gradient value. In the example shown in FIG. 6, it is additionally assumed that the heating power is not increased if the actual gradient value is below a predetermined target gradient value. For this reason, the parboil heating output is only switched off after a delay after the slope of the pot bottom temperature has buckled. However, it would also be possible to increase the parboiling power if the actual gradient value is below a predetermined target gradient value. If, in such a case, after an increase in the heating-up power, the actual slope value of the pot bottom temperature reaches the specified target slope value, the pot bottom temperature can be switched off as soon as the slope of the slope snaps, and not only after a delay time.

Claims (7)

1. Cooker with a device for automatic control of a parboiling process of an electric cooking device to avoid overcooking at the end of the parboiling process, the temperature rise of the cooking vessel bottom being continuously determined during the parboiling process by means of a temperature sensor, characterized in that at the beginning of the parboiling process, the parboiling power of an electric hotplate can be set to a selectable, constant value, a microprocessor continuously records the bottom temperature of the cooking vessel at equal time intervals and determines the course of the rise in the bottom temperature of the pot over time, - the microprocessor at a pot bottom temperature above approx. 700C compares the actual slope value of the pot bottom temperature with a target slope value and, in the event of deviations, switches over the heating power to approximate the actual slope value to the target slope value, - The microprocessor switches off the parboiling power at a pot bottom temperature above approx. 90 ° C when the slope of the pot bottom temperature is bent. 2. Cooker with a device according to claim 1, characterized in that at a pot bottom temperature above about 70 ⁰ C and an actual slope value above a predetermined size is switched to a reduced heating power. 3. Cooker with a device for automatic control of a parboiling process of an electric cooking device to avoid overcooking at the end of the parboiling process, the temperature rise of the cooking vessel bottom being continuously determined during the parboiling process by means of a temperature sensor, characterized in that at the beginning of the parboiling process, the parboiling power of an electric hotplate can be set to a selectable, constant value, a microprocessor continuously determines the temperature rise of the cooking vessel bottom over time, - the microprocessor compares the actual slope value of the pot bottom temperature with a target slope value at a pot bottom temperature above approx. 70 ⁰ C and, in the event of deviations, switches over the heating power to approximate the actual slope value to the target slope value, - The microprocessor switches off at a pot bottom temperature above approx. 90 ^° C. and an actual slope value of the heating power that cannot be corrected sufficiently upwards in the direction of the target slope value after the pot bottom temperature has reached the break point of the slope profile. 4. cooker with a device according to one of claims 1 to 3,
characterized in that the microprocessor determines the actual slope value of the pot bottom temperature below 700C, which results from the parboiling power Pa and the pot content C, the determined value also being a measure of the heat capacity of the food from which the desired slope value is determined . 5. cooker with a device according to one or more of claims 1 to 4,
characterized in that the detection of the pot bottom temperature takes place at equal time intervals of less than 30 seconds, preferably 5 to 15 seconds. 6. cooker with a device according to one or more of claims 1 to 5,
characterized in that the rise in the pot bottom temperature is averaged over several values. 7. cooker with a device according to one or more of claims 1 to 6,
characterized in that after switching off the parboiling power is automatically switched to a pre-setting boiling power.

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