JP2004202084A - Electric pot - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To securely inhibit steam discharged from a pot body when liquid is boiled. <P>SOLUTION: A first set temperature T1 is preset so as to determine whether to perform a first boiling control processing or a second boiling control processing when a reboiling switch 13 is operated. A second set temperature T2 is preset for preliminary boiling determination in the second boiling control processing so that the temperature is higher than the first set temperature T1 and lower than the boiling point. When operation of the reboiling switch 13 is detected, a liquid temperature is detected by a temperature detecting means (a thermistor 6). If a detected temperature T is lower than the first set temperature T1, the first boiling control processing is performed. If the detected temperature T is equal to or higher than the first set temperature T1, the second boiling control processing is performed. In the second boiling control processing, after the temperature is risen to the second set temperature T2, a heating temperature (t) is set based on the detected temperature T so that each heating temperature (t) is different corresponding to the detected temperature T. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

【００３７】
次に、マイコンによる制御について具体的に説明する。
ユーザが商用電源に電源コードを接続すると、マイコンは、図２に示すように、まず、ステップＳ１で、通常沸騰制御処理を実行した後、終了するとステップＳ２で、保温処理を実行する。
【００３８】
ついで、ステップＳ３で、再沸騰スイッチ１３が操作されたか否かを検出する。そして、再沸騰スイッチ１３が操作されていない場合にはステップＳ４に進み、再沸騰スイッチ１３が操作された場合にはステップＳ７に進む。
【００３９】
ステップＳ４では、給湯スイッチが操作されたか否かを検出する。そして、給湯スイッチが操作されていない場合にはステップＳ２に戻る。一方、給湯スイッチが操作された場合にはステップＳ５に進み、給湯ポンプ７をオンして給湯動作を実行した後、ステップＳ６で、給湯スイッチの操作が停止したか否かを検出する。そして、給湯スイッチの操作が停止した場合にはステップＳ２に戻り、給湯スイッチの操作が停止していない場合にはステップＳ５に戻る。即ち、給湯スイッチの操作が停止されるまで給湯ポンプ７を動作し続ける。
【００４０】
また、ステップＳ７では、サーミスタ６によって内容器３内の液体の温度を検出した後、ステップＳ８で、その検出温度Ｔが第１設定温度Ｔ１以上であるか否かを検出する。そして、検出温度Ｔが第１設定温度Ｔ１以上である場合にはステップＳ９に進み、再沸騰制御処理を実行してステップＳ２に戻る。一方、検出温度Ｔが第１設定温度Ｔ１未満である場合にはステップＳ２に戻り、通常沸騰制御処理を実行してステップＳ２に進む。
【００４１】
次に、ステップＳ１の通常沸騰制御処理について説明する。
この通常沸騰制御処理では、マイコンは、図３に示すように、まず、ステップＳ１−１で、湯沸ヒータ４および保温ヒータ５をオンして１００％のフルパワーで加熱を開始する。
【００４２】
ついで、ステップＳ１−２で、サーミスタ６によって内容器３内の液体の温度を検出し、ステップＳ１−３で、その検出温度Ｔａが９２℃に昇温するまで待機する。
【００４３】
ついで、９２℃まで昇温すると、ステップＳ１−４で、時間を計測するタイマをリセットスタートした後、ステップＳ１−５で、サーミスタ６によって内容器３内の液体の温度を検出し、ステップＳ１−６で、その検出温度Ｔｂが９８℃に昇温するまで待機する。
【００４４】
ついで、９８℃まで昇温すると、ステップＳ１−７で、計測タイマをストップした後、ステップＳ１−８で、その計測時間に基づいて周知の容量判別処理を実行する。
【００４５】
ついで、ステップＳ１−９で、判別した容量に基づいて残りの加熱時間を設定し、ステップＳ１−１０で加熱タイマによるカウントをスタートさせた後、ステップＳ１−１１で、加熱タイマがカウントアップするまで待機する。
【００４６】
ついで、加熱タイマがカウントアップすると、ステップＳ１−１２で、湯沸ヒータ４をオフした後、ステップＳ１−１３で、１分経過するまで待機し、１分経過すると、ステップＳ１−１４で、沸騰が終了したことを意味する報知音を出力してリターンする。
【００４７】
次に、ステップＳ９の再沸騰制御処理について説明する。
この再沸騰制御処理では、マイコンは、図４に示すように、まず、ステップＳ９−１で、湯沸ヒータ４および保温ヒータ５をオンして１００％のフルパワーで加熱を開始する。
【００４８】
ついで、ステップＳ９−２で、第２設定温度Ｔ２まで昇温した後の加熱時間ｔの演算処理を実行し、ステップＳ９−３で、算出した加熱時間を設定する。
【００４９】
ついで、ステップＳ９−４で、サーミスタ６によって内容器３内の液体の温度を検出し、ステップＳ９−５で、その検出温度ＴｃがＴ２（９８℃）に昇温するまで待機する。
【００５０】
ついで、９８℃まで昇温すると、ステップＳ９−６で、加熱タイマによるカウントをスタートさせ、ステップＳ９−７で、加熱タイマがカウントアップするまで待機する。
【００５１】
ついで、加熱タイマがカウントアップすると、ステップＳ９−８で、湯沸ヒータ４をオフした後、ステップＳ９−９で、１分経過するまで待機し、１分経過すると、ステップＳ９−１０で、沸騰が終了したことを意味する報知音を出力してリターンする。
【００５２】
次に、ステップＳ２の保温処理について説明する。
この保温処理では、マイコンは、図５に示すように、まず、ステップＳ２−１で、サーミスタ６によって内容器３内の液体の温度を検出する。
【００５３】
ついで、ステップＳ２−２で、その検出温度Ｔｄがユーザが設定した保温温度Ｔhoより高いか否かを検出する。そして、ＴｄがＴhoより高い場合にはステップＳ２−３に進み、保温ヒータ５をオフしてリターンする。一方、ＴｄがＴho以下である場合にはステップＳ２−４に進む。
【００５４】
ステップＳ２−４では、保温温度Ｔhoから検出温度Ｔｄを減算した値が１０℃以上であるか否かを検出する。そして、差が１０℃未満である場合にはステップＳ２−５に進み、保温ヒータ５をオンしてリターンする。一方、ＴhoとＴｄの温度差が１０℃以上である場合にはステップＳ２−６に進む。
【００５５】
ステップＳ２−６では、検出温度Ｔｄが第１設定温度Ｔ１以上であるか否かを検出する。そして、ＴｄがＴ１以上である場合には図２に示すステップＳ９に進み、再沸騰制御処理を実行し、ＴｄがＴ１未満である場合には図２に示すステップＳ１の通常沸騰制御処理を実行する。
【００５６】
このように、本発明の電気ポットでは、確実に容量判別を行えるか否かにより第１設定温度Ｔ１を設定し、再沸騰スイッチ１３を操作した際の液体の検出温度Ｔが前記第１設定温度Ｔ１未満である場合には、即ち、確実に容量判別を行える温度であれば、容量判別を行う通常沸騰制御処理を実行する。そして、この通常沸騰制御処理では、判別した容量に基づいて予備沸騰判断用の第２設定温度Ｔ２を検出した後の加熱時間を設定するため、放出される蒸気の量を確実に抑制できる。
【００５７】
また、検出温度Ｔが第１設定温度Ｔ１以上である場合には再沸騰制御処理を実行し、この再沸騰制御処理では、予め設定した演算式によって第２設定温度Ｔ２を検出した後の加熱時間（ｔ）を、各検出温度（Ｔ）毎に異なるように設定するため、ポット本体１から放出される蒸気の量を最大限に抑制することができる。しかも、第１設定温度Ｔ１と第２設定温度Ｔ２との間で区分けし、その区分けされた温度範囲毎に異なる演算式を設定しているため、より確実に蒸気の放出を抑制できる。
【００５８】
さらに、本実施形態の電気ポットでは、前記加熱時間ｔを演算式によって算出するため、その条件を記憶させる記憶媒体に必要な容量を削減できる。しかも、サーミスタの種類を変更することにより、温度検出に係る分解能が変わっても、制御プログラムは設定変更する必要がない。そのため、コストダウンを図ることができる。
【００５９】
なお、本発明の電気ポットは、前記実施形態の構成に限定されるものではなく、種々の変更が可能である。
【００６０】
例えば、前記実施形態では、第３演算式による加熱温度ｔは一定となるようにしたが、各検出温度Ｔ毎に異ならせてもよい。
【００６１】
また、前記実施形態では、加熱時間ｔを演算式により算出させたが、各検出温度Ｔに対応する加熱時間ｔを設定したデータテーブルを搭載（記憶媒体に記憶）させてもよい。
【００６２】
さらに、前記実施形態では、保温処理において、設定された保温温度Ｔhoと検出温度Ｔｄとの温度差が１０℃以上の場合には通常沸騰制御処理または再沸騰制御処理を実行させたが、基準となる温度を設定し、その温度より検出温度Ｔｄが低下した場合に通常沸騰制御処理または再沸騰制御処理を実行させてもよい。
【００６３】
【発明の効果】
以上の説明から明らかなように、本発明の電気ポットでは、再沸騰スイッチの操作により実行される第２沸騰制御処理において、再沸騰スイッチの操作を検出した際の液体の検出温度に基づいて、第２設定温度Ｔ２を検出した後の加熱時間（ｔ）を、各検出温度（Ｔ）毎に異なるように設定するため、ポット本体から放出される蒸気の量を最大限に抑制することができる。
【図面の簡単な説明】
【図１】本発明の実施形態に係る電気ポットを示す概略図である。
【図２】マイコンによる制御を示すフローチャートである。
【図３】図２の通常沸騰制御処理を示すフローチャートである。
【図４】図２の再沸騰制御処理を示すフローチャートである。
【図５】図２の保温処理を示すフローチャートである。
【図６】加熱することによる温度検出手段による検出温度と液体の昇温温度との関係を示すグラフである。
【符号の説明】
１…ポット本体
２…蓋体
３…内容器
４…湯沸ヒータ（加熱手段）
５…保温ヒータ
６…サーミスタ（温度検出手段）
７…給湯ポンプ
１０…揚水管
１３…再沸騰スイッチ[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an electric pot.
[0002]
[Prior art]
An electric pot of this type includes, in a pot body, an inner container for storing a liquid, heating means for boiling and keeping the liquid in the inner container, discharging means for discharging the liquid in the inner container, Temperature detecting means for detecting the temperature of the liquid in the container, wherein when the liquid is stored in the inner container, the boiling control by the heating means is executed, and then the heat retention control is executed. Further, a re-boiling control function is provided for re-boiling a liquid in a warm state by the heating means.
[0003]
Prior art document information related to the electric pot of the present invention is as follows.
[0004]
[Patent Document 1]
JP-A-11-76063
In the electric pot of this patent document 1, the standard for judging that boiling has been made different between the normal boiling control process and the re-boiling control process, and the time for heating at a low current rate after judging that boiling has occurred is made different. . Further, when the reboil switch is operated, it is configured to change, based on the temperature at that time, whether to reboil by the normal boiling control or to boil by the reboil control process. Thereby, it is configured such that abnormal occurrence of steam at the time of performing the boiling control can be prevented.
[0006]
[Problems to be solved by the invention]
However, since the electric pot of Patent Document 1 is heated for a certain period of time after judging that both the normal boiling control and the re-boiling control have detected the boiling, steam may also be abnormally generated.
[0007]
That is, the temperature T of the liquid in the inner container detected by the temperature detecting means can accurately detect the temperature of the liquid in the inner container when not heated by the heating means. However, in the state where any one of the boiling control processes is performed, the ambient temperature heated by the heating means is added. Therefore, as shown in FIG. 6, the detected temperature T and the actual liquid temperature change with time. There is a difference. Further, this temperature difference is different between when the heating means does not completely generate heat and when the energization is started and when the heating means completely generates heat, and becomes larger when the heating means completely generates heat. Further, the lower the temperature at which the heating means starts heating, the greater the temperature difference near the boiling point (100 ° C.). Furthermore, when the temperature rises to 98 ° C., which is close to the boiling point, the temperature rise gradient becomes gentle even with the same heating amount.
[0008]
Therefore, the heating time after the detection of boiling is set on the assumption that the liquid volume is the maximum and the heating efficiency is the worst. As a result, there is a problem that a large amount of steam is released in a situation where the heating efficiency is the best such as when the temperature at the start of heating is low.
[0009]
In view of the above, an object of the present invention is to provide an electric pot that can reliably suppress steam released from a pot body when a liquid is boiled.
[0010]
[Means for Solving the Problems]
In order to solve the above-mentioned problems, an electric pot of the present invention includes an inner container provided in a pot main body for storing a liquid, heating means for heating the liquid in the inner container to boil and keep the temperature, Discharging means for discharging the liquid in the inner container, temperature detecting means for detecting the temperature of the liquid in the inner container, and a re-boiler switch for reheating the liquid in a warmed state by the heating means. The first boiling control process is executed when the liquid below the temperature is stored, and the second boiling control process is executed when the reboil switch is operated. In the electric pot, the reboil switch is operated. At this time, a first set temperature (T1) for determining whether to execute the first boiling control process or the second boiling control process, and a first set temperature (T1) in the second boiling control process. A second set temperature (T2) for judging preliminary boiling that is higher than the boiling point is set in advance, and when the operation of the reboil switch is detected, the liquid temperature is detected by the temperature detecting means, and the detected temperature (T) is detected. When the temperature is lower than the first set temperature (T1), the first boiling control process is performed. On the other hand, when the detected temperature (T) is equal to or higher than the first set temperature (T1), the second boiling control process is performed. A control process is executed. In the second boiling control process, a heating time (t) after the temperature is raised to the second set temperature (T2) based on the detected temperature (T) is determined for each detected temperature (T). It is configured to be set differently.
[0011]
According to the electric pot, in the second boiling control process, based on the detected temperature of the liquid when the operation of the reboil switch is detected, the heating time (t) after the detection of the second set temperature T2 is determined by Since the setting is made different for each detected temperature (T), the amount of steam released from the pot body can be suppressed to the maximum.
[0012]
In this electric pot, it is preferable that the heating time (t) is calculated by a preset arithmetic expression. In this way, the capacity for storing the conditions for setting the heating time (t) in the storage medium can be reduced. Further, even if the resolution is changed by changing the temperature detecting means, it is not necessary to change the setting of the control program. Therefore, cost can be reduced.
[0013]
In this case, a third set temperature (T3) different from the first set temperature (T1) and the second set temperature (T2) is further set, and the detected temperature (T) is set to the third set temperature (T3). It is preferable that the arithmetic expression for calculating the heating time (t) be different between the case where the temperature is equal to or higher than T3) and the case where the detected temperature (T) is lower than the third set temperature (T3). This makes it possible to more reliably suppress the release of steam.
[0014]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 shows an electric pot according to an embodiment of the present invention. This electric pot is a well-known electric pot including a pot body 1 and a lid 2 rotatably mounted on an upper portion of the pot body 1.
[0015]
Inside the pot main body 1, an inner container 3 for containing water is provided. At the bottom of the inner container 3, a water heater 4 as a heating means and a warming heater 5 are provided, and a thermistor 6 is provided as temperature detecting means for detecting the temperature of the liquid in the inner container 3. Have been. A control board 14 on which a microcomputer is mounted and a hot water supply pump 7 are provided between the exterior body of the pot body 1 and the inner container 3.
[0016]
A nose portion 9 is formed on the shoulder 8 at the upper part of the pot body 1, and a water pump 10 connected to the hot water supply pump 7 is provided so as to protrude from the lower surface of the nose portion 9. A liquid crystal panel 11 for displaying the temperature of the liquid in the inner container 3 is disposed on the upper outer surface of the nose portion 9, and an operation board connected to the control board 14 behind the liquid crystal panel 11. 12 are provided. The operation board 12 is provided with a reboil switch 13 for boiling the liquid in the warm state again. Further, a hot water supply switch for supplying the liquid in the inner container 3 and a selection switch for selecting the heat retaining temperature are provided.
[0017]
The control board 14 is mounted with a microcomputer having a built-in ROM and RAM as storage media, and is stored in the ROM based on the liquid temperature inputted from the thermistor 6 by the input from the operation board 12. The heaters 4 and 5 are controlled according to a control program to execute boiling and heat retention control.
[0018]
More specifically, the control programs stored in the ROM generally include a first boiling control process (hereinafter, referred to as a normal boiling control process) and a second boiling control process (hereinafter, referred to as a re-boiling control process). And a heat retention control process.
[0019]
In the present embodiment, a first set temperature T1 for determining whether to execute the normal boiling control process or the reboil control process when the reboil switch 13 is operated is set. When the operation of the reboil switch 13 is detected, the liquid temperature is detected by the thermistor 6. When the detected temperature T is lower than the first set temperature T1, the normal boiling control process is executed. When the detected temperature T is equal to or higher than the first set temperature T1, the re-boiling control process is executed.
[0020]
That is, the normal boiling control process is performed when a liquid having a temperature equal to or lower than a predetermined temperature is stored in the inner container 3 and the liquid temperature in the inner container 3 is reduced by 10 ° C. or more from the warming temperature and when the reboil switch 13 is operated. Is executed when the detected temperature T of the liquid is lower than the first set temperature T1. Further, the reboil control process is configured to be executed when the reboil switch 13 is operated and the detected temperature T of the liquid at that time is equal to or higher than the first set temperature T1.
[0021]
In the present embodiment, the second set temperature T2 for determining the preliminary boiling higher than the first set temperature T1 and lower than the boiling point of water is set. In the reboil control process, the heating time t after the temperature is raised to the second set temperature T2 based on the detected temperature T of the liquid when the reboil switch 13 is operated is changed for each detected temperature T. It is configured to be set.
[0022]
The heating time t is calculated based on the detected temperature T by an operation formula set in advance. Then, three types of arithmetic expressions of the present embodiment are set, and a third set temperature T3 and a fourth set temperature T4 which are different between the first set temperature T1 and the second set temperature T2 are further set. When the detected temperature T is higher than the third set temperature T3, when the detected temperature T is lower than the third set temperature T3 and higher than the fourth set temperature T4, and when the detected temperature T is lower than the fourth set temperature T4 Thus, different arithmetic expressions are applied.
[0023]
In the normal boiling control process, the heaters 4 and 5 are energized to heat the liquid at an energization rate of 100%. Next, the time required for the liquid temperature detected via the thermistor 6 to change from 92 ° C. to 98 ° C. is measured, and the volume of the liquid stored in the inner container 3 is determined based on the time, and thereafter, according to the volume, Set the heating time. Thereafter, when the heating time elapses, the power supply to the water heater 4 is stopped, and a notification sound is output informing that boiling has occurred after a predetermined time.
[0024]
In the re-boiling control process, the heaters 4 and 5 are energized to heat the liquid at an energization rate of 100%. Further, the heating time t is calculated and set by an arithmetic expression based on the detected temperature T of the liquid detected before the heating by the water heater 4, and the process waits until the temperature reaches the second set temperature T2. Then, when the second set time T2 is reached, the apparatus waits until the set heating time t elapses. When the heating time t elapses, the power supply to the water heater 4 is stopped, and a notification sound indicating that boiling has occurred after a predetermined time has elapsed. Output.
[0025]
In the present embodiment, the first set temperature T1 is 85 ° C., the second set temperature T2 is 98 ° C., the third set temperature T3 is 96.5 ° C., and the fourth set temperature T4 is 88.5 ° C. The heating time (timHi) at the third set temperature T3 is 40 seconds, and the heating time (timLo) at the fourth set temperature T4 is 60 seconds. The reference values for the set temperatures T1, T2, T3, T4 and the heating time were found by the inventor's earnest experiment based on the heating characteristics of water shown in FIG.
[0026]
(Setting of the first set temperature T1)
The setting of the heating time t after the preliminary boiling determination is preferably performed based on the determined capacity as in the normal boiling control process. However, if the heat generation by the water heater 4 is incomplete in the detection state of 92 ° C. The result of the capacity determination becomes unstable (not accurate). Therefore, in the present embodiment, the first set temperature T1 for determining which of the normal boiling control processing for performing the capacity determination and the re-boiling control processing for not performing the capacity determination is set to 85 ° C. .
[0027]
(Setting of the second set temperature T2)
The amount of steam generated by any of the boiling control processes increases as the boiling point is approached, and rapidly increases at about 99 ° C. Therefore, in the present embodiment, the second set temperature T2 for the preliminary boiling determination for determining that the boiling has substantially occurred is 98 ° C. which is the same for both the normal boiling control process and the re-boiling control process.
[0028]
(Setting of the third set temperature T3 and the fourth set temperature T4)
The rate of temperature rise of the liquid by heating is short until the water heater 4 completely generates heat, and thereafter increases. The error between the temperature T detected by the thermistor 6 and the actual liquid temperature increases when the temperature at the start of heating is low, and decreases when the temperature at the start of heating is high. Therefore, in the present embodiment, the temperature range (85.5 ° C. to 100 ° C.) in which the reboil control process is performed is divided into three, and different first to third arithmetic expressions are provided and divided. The third set temperature T3 is 96.5 ° C., and the fourth set temperature T4 is 88.5 ° C.
[0029]
(First operation expression)
The first arithmetic expression is applied when the detected temperature T when the reboil switch 13 is operated is equal to or higher than the third set temperature T3. In the heating under this condition, the rising gradient of the actual liquid temperature becomes gentler, and the error between the temperature T detected by the thermistor 6 and the actual liquid temperature is small. For this reason, the first arithmetic expression is set as in the following expression (1) to calculate a different heating time t for each detected temperature T, and set the rate of change of the heating time t to be small.
[0030]
(Equation 1)
t = timHi- (T-T3) (1)
[0031]
(Second arithmetic expression)
The second arithmetic expression is applied when the detected temperature T when the reboil switch 13 is operated is lower than the third set temperature T3 and higher than the fourth set temperature T4. In the heating under this condition, the temperature gradient of the actual liquid rises steeply, and the error between the temperature T detected by the thermistor 6 and the actual liquid temperature is larger than the case where the temperature is equal to or higher than the third set temperature T3. Therefore, the second arithmetic expression calculates a different heating time t for each detected temperature T as in the following expression (2), and the arithmetic expression (1) is applied to the rate of change of the heating time t. It is set to be larger than the case.
[0032]
(Equation 2)
t = ((T3-T) * (timLo-timHi) / (T3-T4) + timHi ... (2)
[0033]
(Third arithmetic expression)
The third arithmetic expression is applied when the detected temperature T when the reboil switch 13 is detected is lower than the fourth set temperature T4 and higher than the first set temperature T1. In the heating under this condition, the error between the temperature T detected by the thermistor 6 and the actual liquid temperature is larger than the condition using the second arithmetic expression, but the difference in the amount of generated steam due to the difference in the heating time t is small. Therefore, the third arithmetic expression is set so that the heating time t is longer than the maximum heating time t calculated by the second arithmetic expression but is constant as shown in the following expression (3). I have.
[0034]
[Equation 3]
t = timLo ... (3)
[0035]
Table 1 below shows the heating time t set for each detected temperature T in the reboil control process calculated by the first to third arithmetic expressions.
[0036]
[Table 1]

[0037]
Next, control by the microcomputer will be specifically described.
When the user connects the power cord to the commercial power supply, as shown in FIG. 2, the microcomputer first executes the normal boiling control processing in step S1, and then executes the heat retention processing in step S2 when the processing ends.
[0038]
Next, in step S3, it is detected whether or not the reboil switch 13 has been operated. When the reboil switch 13 is not operated, the process proceeds to step S4, and when the reboil switch 13 is operated, the process proceeds to step S7.
[0039]
In step S4, it is detected whether or not the hot water supply switch has been operated. When the hot water supply switch is not operated, the process returns to step S2. On the other hand, if the hot water supply switch has been operated, the process proceeds to step S5, where the hot water supply pump 7 is turned on to execute the hot water supply operation, and then, in step S6, it is detected whether or not the operation of the hot water supply switch has been stopped. When the operation of the hot water supply switch is stopped, the process returns to step S2, and when the operation of the hot water supply switch is not stopped, the process returns to step S5. That is, the operation of the hot water supply pump 7 is continued until the operation of the hot water supply switch is stopped.
[0040]
In step S7, after the temperature of the liquid in the inner container 3 is detected by the thermistor 6, in step S8, it is detected whether the detected temperature T is equal to or higher than the first set temperature T1. If the detected temperature T is equal to or higher than the first set temperature T1, the process proceeds to step S9, executes the re-boiling control process, and returns to step S2. On the other hand, if the detected temperature T is lower than the first set temperature T1, the process returns to step S2, executes the normal boiling control process, and proceeds to step S2.
[0041]
Next, the normal boiling control process in step S1 will be described.
In the normal boiling control process, as shown in FIG. 3, the microcomputer first turns on the hot water heater 4 and the heat retaining heater 5 to start heating with 100% full power in step S1-1.
[0042]
Next, in step S1-2, the temperature of the liquid in the inner container 3 is detected by the thermistor 6, and in step S1-3, the process stands by until the detected temperature Ta rises to 92 ° C.
[0043]
Then, when the temperature is raised to 92 ° C., the timer for measuring the time is reset and started in step S1-4, and in step S1-5, the temperature of the liquid in the inner container 3 is detected by the thermistor 6 in step S1-5. At 6, the control waits until the detected temperature Tb rises to 98 ° C.
[0044]
Next, when the temperature is raised to 98 ° C., the measurement timer is stopped in step S1-7, and in step S1-8, a known capacity determination process is executed based on the measured time.
[0045]
Then, in step S1-9, the remaining heating time is set based on the determined capacity. In step S1-10, the counting by the heating timer is started. In step S1-11, the heating timer is counted up. stand by.
[0046]
Then, when the heating timer counts up, in step S1-12, the water heater 4 is turned off. Then, in step S1-13, the process waits until one minute elapses. Then, a notification sound indicating that the process has been completed is output, and the process returns.
[0047]
Next, the reboil control process in step S9 will be described.
In the re-boiling control process, as shown in FIG. 4, the microcomputer first turns on the hot water heater 4 and the heat retaining heater 5 to start heating at 100% full power in step S9-1.
[0048]
Next, in step S9-2, a calculation process of the heating time t after the temperature is raised to the second set temperature T2 is executed, and in step S9-3, the calculated heating time is set.
[0049]
Next, in step S9-4, the temperature of the liquid in the inner container 3 is detected by the thermistor 6, and in step S9-5, the process stands by until the detected temperature Tc rises to T2 (98 ° C.).
[0050]
Then, when the temperature is raised to 98 ° C., counting by the heating timer is started in step S9-6, and in step S9-7, the process stands by until the heating timer counts up.
[0051]
Then, when the heating timer counts up, in step S9-8, the water heater 4 is turned off, and then, in step S9-9, the process waits for one minute to elapse. Then, a notification sound indicating that the process has been completed is output, and the process returns.
[0052]
Next, the warming process in step S2 will be described.
In this heat retention process, the microcomputer first detects the temperature of the liquid in the inner container 3 by the thermistor 6 in step S2-1 as shown in FIG.
[0053]
Next, in step S2-2, it is detected whether or not the detected temperature Td is higher than the heat retaining temperature Tho set by the user. If Td is higher than Tho, the process proceeds to step S2-3, in which the heat retaining heater 5 is turned off, and the process returns. On the other hand, when Td is equal to or smaller than Tho, the process proceeds to step S2-4.
[0054]
In step S2-4, it is detected whether or not a value obtained by subtracting the detected temperature Td from the heat retaining temperature Tho is equal to or higher than 10 ° C. If the difference is less than 10 ° C., the process proceeds to step S2-5, turns on the heat retaining heater 5, and returns. On the other hand, if the temperature difference between Tho and Td is 10 ° C. or more, the process proceeds to step S2-6.
[0055]
In step S2-6, it is detected whether the detected temperature Td is equal to or higher than the first set temperature T1. If Td is equal to or greater than T1, the process proceeds to step S9 shown in FIG. 2, and reboil control is performed. If Td is less than T1, normal boiling control is performed in step S1 shown in FIG. I do.
[0056]
Thus, in the electric pot of the present invention, the first set temperature T1 is set depending on whether or not the capacity can be reliably determined, and the detected temperature T of the liquid when the reboil switch 13 is operated is set to the first set temperature. If the temperature is less than T1, that is, if the temperature is such that the capacity can be reliably determined, the normal boiling control process for performing the capacity determination is executed. In the normal boiling control process, the heating time after the detection of the second set temperature T2 for preliminary boiling determination is set based on the determined capacity, so that the amount of released steam can be reliably suppressed.
[0057]
When the detected temperature T is equal to or higher than the first set temperature T1, the reboil control process is performed. In the reboil control process, the heating time after the second set temperature T2 is detected by a preset arithmetic expression Since (t) is set differently for each detected temperature (T), the amount of steam released from the pot body 1 can be suppressed to the maximum. In addition, since the temperature is divided between the first set temperature T1 and the second set temperature T2, and different arithmetic expressions are set for each of the divided temperature ranges, it is possible to more reliably suppress the release of steam.
[0058]
Further, in the electric pot of the present embodiment, since the heating time t is calculated by an arithmetic expression, the capacity required for a storage medium for storing the conditions can be reduced. Moreover, even if the resolution relating to temperature detection changes by changing the type of thermistor, there is no need to change the setting of the control program. Therefore, cost can be reduced.
[0059]
In addition, the electric pot of the present invention is not limited to the configuration of the above-described embodiment, and various changes can be made.
[0060]
For example, in the above-described embodiment, the heating temperature t according to the third arithmetic expression is made constant, but may be made different for each detected temperature T.
[0061]
In the above-described embodiment, the heating time t is calculated by an arithmetic expression. However, a data table in which the heating time t corresponding to each detected temperature T is set may be mounted (stored in a storage medium).
[0062]
Further, in the above embodiment, in the heat retaining process, when the temperature difference between the set heat retaining temperature Tho and the detected temperature Td is 10 ° C. or more, the normal boiling control process or the re-boiling control process is executed. The normal boiling control process or the re-boiling control process may be executed when the detected temperature Td falls below the predetermined temperature.
[0063]
【The invention's effect】
As is clear from the above description, in the electric pot of the present invention, in the second boiling control process executed by operating the reboil switch, based on the detected temperature of the liquid when the operation of the reboil switch is detected, Since the heating time (t) after detecting the second set temperature T2 is set to be different for each detected temperature (T), the amount of steam released from the pot body can be suppressed to the maximum. .
[Brief description of the drawings]
FIG. 1 is a schematic view showing an electric pot according to an embodiment of the present invention.
FIG. 2 is a flowchart showing control by a microcomputer.
FIG. 3 is a flowchart showing a normal boiling control process of FIG. 2;
FIG. 4 is a flowchart showing a reboil control process of FIG. 2;
FIG. 5 is a flowchart showing a heat retaining process of FIG. 2;
FIG. 6 is a graph showing a relationship between a temperature detected by a temperature detecting unit due to heating and a temperature at which a liquid is heated.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Pot body 2 ... Lid 3 ... Inner container 4 ... Water heater (heating means)
5: Heating heater 6: Thermistor (temperature detecting means)
7 hot water supply pump 10 pumping pipe 13 reboil switch

Claims (3)

An inner container provided in the pot body for storing the liquid, heating means for heating the liquid in the inner container to boil and keep warm, discharge means for discharging the liquid in the inner container, Temperature control means for detecting the temperature of the liquid; and a reboil switch for reheating the liquid in a warm state by the heating means. The first boiling control is performed when the liquid having a predetermined temperature or less is stored in the inner container. An electric pot that executes a second boiling control process when the reboil switch is operated,
A first set temperature (T1) for determining whether to execute the first boiling control process or the second boiling control process when the reboil switch is operated; A second set temperature (T2) for judging preliminary boiling higher than the first set temperature (T1) and lower than the boiling point is set in advance;
When the operation of the reboil switch is detected, the liquid temperature is detected by the temperature detecting means. If the detected temperature (T) is lower than the first set temperature (T1), the first boiling control process is executed. On the other hand, when the detected temperature (T) is equal to or higher than the first set temperature (T1), the second boiling control process is executed,
In the second boiling control process, the heating time (t) after the temperature is raised to the second set temperature (T2) based on the detected temperature (T) is set to be different for each detected temperature (T). An electric pot characterized in that: The electric pot according to claim 1, wherein the heating time (t) is calculated by a preset arithmetic expression. A third set temperature (T3) different between the first set temperature (T1) and the second set temperature (T2) is further set, and the detected temperature (T) is equal to or higher than the third set temperature (T3). 3. An arithmetic expression for calculating the heating time (t) is different from each other when the detected temperature (T) is lower than the third set temperature (T3). An electric pot according to claim 1.

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