KR0173005B1 - Method for preventing overheating of electric rice cooker - Google Patents

Abstract

The present invention relates to a technique for preventing overheating of a hot plate of an electric thermal cooker, and more specifically, the maximum time for overheating for each process is set in advance, and the maximum time for overheating has elapsed within the maximum temperature for each process during the cooking process. If it is determined that the overheating of the electric insulation rice cooker to determine the overheating, and to cancel the cooking process and to check the overheating from the outside so as to check the overheating, the normal absorption process-heating process- In the cooking method by a microcomputer, which proceeds to boiling boiling-moxibustion-heating process and finally ends with a cooking completion indication indicating that the rice is completed, the predetermined time (α) is applied to the maximum heating time according to each process described above. In addition, if each cooking process is started while generating the maximum process superheat time and pre-stored in the data storage, the process Set the maximum heat time, and at the same time as the initial process starts, the timer is turned on to determine whether the first step of heating proceeds and whether the count of the timer according to the first step during the heating process reaches the above process overheat maximum time. After reaching the second stage of process cancellation, hot plate heater off, and check mark display unit, if the heating temperature is reached, the process returns to the second stage if the heating maximum temperature is reached. When the temperature is at the maximum temperature, the timer is reset and the third process proceeds to the next process.

Description

How to prevent overheating of electric rice cooker

1 is a control block diagram of devices employed as an example of the present invention.

Figure 2 is a table setting the maximum overheating time for each process and the maximum temperature for each process according to the present invention as an example.

3 is a control flow diagram showing the operation according to the present invention.

* Explanation of symbols for main parts of the drawings

10: inner pot temperature detection unit 20: timer

30: key input unit 40: micom

50: hot plate driving unit 60: thermal heater driving unit

70: display unit 80: data storage unit

The present invention relates to a technique for preventing overheating of a hot plate of an electric thermal cooker, and more specifically, the maximum time for overheating for each process is set in advance, and the maximum time for overheating has elapsed within the maximum temperature for each process during the cooking process. If it is determined that this is determined as overheating, and thus the overheating prevention method of the electric insulation rice cooker so that the check display output is made to the display unit to check the overheating from the outside as well as cancel the cooking process.

In general, the electric insulation rice cooker is provided with the operating conditions for each process according to the contents of the bar, which is first started the process according to each cooking operation after the state that the inner pot is settled.

As an example, if you look at the order by white rice process as follows.

First, when the inner pot is confirmed to be seated by a key for detecting the inner pot of the inner pot, select white rice as the menu key, and then press the start cooking key to activate the progress program for each process. This proceeds to the process program, i.e., the absorption process, the heating process, the boiling maintenance, the moxibustion process, and the thermal insulation process, and finally ends with the cooking completion indication indicating that the rice is completed.

Therefore, after the inner pot is normally seated in the rice cooker, it can be confirmed that the process proceeds automatically.

However, overheating of the hotplate often occurs due to insufficient methods for preparing a situation in which the hotplate is not sufficiently delivered to the inner pot of the hotplate due to carelessness and foreign matters of the user.

In other words, if the inner pot does not supply enough heat due to the foreign matter between the hot plate and the inner pot, the temperature sensor continuously detects only a low temperature, thus recognizing the end of the cooking process. As a result, overheating was caused.

Therefore, the present invention was devised to avoid the above phenomenon caused by the abnormal state in the cooking process due to insufficient heat transfer to the inner pot, for that purpose, the maximum overheating time for each process in advance If it is determined that the maximum time of overheating has elapsed within the maximum temperature of each process during the cooking process, it is determined that it is overheated, and a check mark is outputted on the display unit to cancel the cooking process and check the overheating from the outside. It is to provide a method of preventing overheating of the electric heat cooker to make.

In the present invention for achieving the above object in the normal absorption process-heating process-boiling maintenance-moxibustion process-warming process, and finally in the cooking method by the microcomputer to end with a cooking completion mark indicating that the rice is completed, A process overheating maximum time is generated by adding 25% of each process time to the maximum heating time according to each process and set in advance in the data storage unit, but the timer is turned on at the same time as the initial process is started. A first step and a second step of driving the process cancel, hot plate heater off, and check display unit if the count of the timer according to the first step during the heating process reaches the above-described process overheat maximum time. It checks whether the heating maximum temperature of each process is reached and if it is within the heating maximum temperature, it returns the process of the second stage. There is a characteristic having a timer to slow the third stage progressed to the next step with the resets.

In the present invention, the maximum time of each superheat is 12 minutes or more (12 + α) in the absorption step, 10 minutes or more (10 + α) in the heating step 1, and 10 minutes or more in the second heating step ( 10 + α), when boiling is maintained for more than 5 minutes (5 + α), during the moxibustion process is set to 12 minutes or more (12 + α), the α corresponds to 25% of each process time It shows time to do.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a control block diagram showing an embodiment of the devices employed in the present invention, the device employed in one embodiment of the present invention is the inner pot temperature sensing unit 10, timer 20, key input unit 30, The microcomputer 40, the hot plate driving unit 50, the thermal heater driving unit 60, the display unit 70, and the data storage unit 80 are configured.

In other words, a timer for sensing the temperature of the inner pot and inputting it to the microcomputer 40 and a timer for supplying the source of the maximum process overheating time to the microcomputer 40 driven by the control of the microcomputer ( 20), a key input unit 30 for inputting a command of a selection key for activating a mode according to each menu, a command of a cooking cooker to inform the start of the process progress, and the like to the microcomputer 40, and an electric thermal cooker. The microcomputer 40 for controlling the system, the hot plate driver 50 for controlling the heater for heating the hot plate by the control signal of the microcomputer 40, and the warming heater by the control signal of the microcomputer 40 Insulating heater driving unit 60 for driving control, and the display unit 70 to display the various states of the electric thermal cooker by the control signal of the microcomputer 40, and also to output the hot plate and the check display of the heat display, and the process Maximum overheating time and process heating maximum It is the temperature, storage is a data storage section 80 provided in the microcomputer 40.

3 is a control flow chart showing the operation according to the present invention, which generates the maximum process overheating time plus 25% of the heating time according to each process, and each cooking process is stored in the data storage in advance. When starting, the process overheating maximum time is set, but the first step is started and the timer is turned on at the same time as the initial process is started, and the count of the timer by the first step during the heating process reaches the above process overheating maximum time. After the determination is made, the second step of canceling the process, turning off the hot plate heater, and the check mark display unit, and confirming whether the heating maximum temperature of each process is reached is determined. If the return is higher than the heating maximum temperature is reset to the timer and is provided in the third step proceeds to the next process.

Here, each of the maximum superheat time is 12 minutes or more (25% time of each 12+ process) in the absorption process, and 10 minutes or more (10+ of each process) in the heating process, as represented in FIG. 25% hour), 10 minutes or more (2% of each 10+ steps) for heating 2 steps, 5 minutes or more (25% of each 5+ steps) for boiling, 12 minutes for moxibustion steps It sets to the above time (25% time of each 12+ process).

Referring to the operation and effect of the present invention configured as described in detail as follows.

Electric insulation rice cooker according to the present invention is carried out in the usual cooking process as it is, the process of preventing overheating as shown in FIG.

Here, FIG. 2 shows the maximum process overheat time by adding 25% of each process to the maximum process time according to each cooking process, and overheating is checked based on the above time during the start of each cooking process. .

That is, after the first state that the inner pot is placed in the normal cooking process is detected, the process starts according to the cooking operation provided in each key input unit 30, and then the inner pot is detected by the key for detecting the inner pot. When it is confirmed that the menu is selected as a menu key and press the start cooking key, the microcomputer 40 is activated by the process-specific progress program. This proceeds to the process program, i.e., the absorption process, the heating process, the boiling maintenance, the moxibustion process, and the thermal insulation process, and finally ends with a cooking completion indication indicating that the rice is completed.

The cooking process progressed as described above is not an abnormal cooking state, and is only performed within a maximum time of process superheat for each process of FIG. 2 according to the present invention, so that the above-described process can be completed without abnormality.

By the way, when the present invention is inserted into the ball contacting the hot plate and the bottom surface of the inner pot and the cooking process is in an abnormal state, first, by selecting the menu with the key provided in the key input unit 30, the cooking start key Press the microcomputer 40 is activated by the process-specific progress program, which is initially started the absorption process (S100). Then, the heating progress of heating the hot plate is started and at the same time, the timer 20 is driven to turn on the timer 20 (S101). Herein, the microcomputer 50 sets the absorption process time shown in FIG. 2, that is, 25% of each 12+ process in the data storage unit 80 and compares it with the timer described above (S103). (At this time, the heater by the hot plate driving unit 50 is driven on and heating the hot plate.)

By the way, the heating of the hot plate is normally up to 12 minutes, which is the maximum process time of the absorption process, but when 12 minutes has elapsed, it is determined that 12 minutes + 25% time of each process has been read from the data storage unit 80. It is determined that the inner pot is overheated, the microcomputer 40 instructs to cancel the process (S131), which, of course, applies a control signal to the hot plate driving unit 50 to drive off the hot plate heater and at the same time, the display unit 70. In addition, the control signal is applied to inform the outside of the hot plate overheating (S132). However, if it is determined within 12 minutes, which is the maximum process time of the absorption process, it is recognized as a normal state and it is determined whether the absorption heating maximum temperature (45 ° C.) has been reached (S103). If not, the process returns to the above-described step (S102). On the other hand, if it is determined that the state reached, the control output for resetting the timer 20 is applied (S105), and then the process proceeds to the heating one-process procedure (S107).

When the heating first process is started, the heating progress of heating the hot plate is started and at the same time, the timer 20 is driven to turn on the timer 20 (S108) (S109). Here, the microcomputer 50 sets 25% time of each 10+ process in the heating 1 process shown in FIG. 2 in the data storage unit 80 and compares it with the timer described above (S110). (Of course, at this time, the heater by the hot plate driving unit 50 is driven and heating the heat pipe.) By the way, the heating of the hot plate is normally up to 10 minutes, which is the maximum process time of the first heating step, but the 10 minutes have elapsed. If it is determined that 10 minutes + 25% time of each process read by the data storage unit 80 has elapsed, it is determined that the inner pot is overheated and the microcomputer 40 instructs to cancel the process (S131). A control signal is applied to the hot plate driving unit 50 to drive off the hot plate heater, and a control signal is also applied to the display unit 70 to inform the hot plate overheat to the outside (S132).

However, if it is determined within 10 minutes, which is the maximum process time of the heating step 1, it is recognized as a normal state and it is determined whether the process 1 heating maximum temperature (75 ° C.) has been reached (step S111). On the other hand, if it is determined that the state is reached, a control output for resetting the timer 20 is applied (S112), and then the heating 2 process proceeds (S113).

When the heating second process is started, the heating process for heating the hot plate is started and at the same time, the timer 20 is driven to turn on the timer 20 (S114) (S115). Here, the microcomputer 50 sets the heating 2 process time shown in FIG. 2, that is, 25% time of each 10+ process in the data storage unit 80 and compares it with the timer described above (S116). (At this time, the heater by the hot plate driving unit 50 is driven on and heating the hot plate.)

By the way, it is determined that heating of the hot plate is normally up to 10 minutes, which is the maximum process time of the heating 2 process, but after 10 minutes has elapsed, 10 minutes + 25% time of each process has been read by the data storage unit 80. In this case, it is determined that the inner pot is overheated so that the microcomputer 40 instructs to cancel the process (S131), which, of course, applies a control signal to the hot plate driving unit 50 to drive off the hot plate heater and at the same time, the display unit ( The control signal is also applied to 70 to inform the outside of the hot plate overheating (S132).

However, if it is determined within 10 minutes, which is the maximum process time of the heating 2 process, it is recognized as a normal state and it is determined whether the process 2 heating maximum temperature 102 has been reached (S117). On the other hand, if it is determined that the state is reached, a control output for resetting the timer 20 is applied (S118), and then the process proceeds to the boiling maintenance step (S119).

When the boiling maintenance process is started, the heating progress of heating the hot plate is started and at the same time, the timer 20 is driven to turn on the timer 20 (S120) (S121). Here, the microcomputer 50 sets 25% time of each 5+ process in the boiling maintenance process shown in FIG. 2 in the data storage unit 80 and compares it with the timer described above (S122). (At this time, the heater by the hot plate driving unit 50 is driven on and heating the hot plate.)

By the way, if the heating of the hot plate is normally up to 5 minutes, which is the maximum process time of the boiling maintenance process, it is determined that 5 minutes has elapsed and that 10 minutes + 25% time of each process has been elapsed after the 5 minutes have elapsed. This determines that the inner pot is overheated and the microcomputer 40 instructs to cancel the process (S131), of course, by applying a control signal to the hot plate driving unit 50 to drive off the hot plate heater and at the same time, the display unit 70. In addition, the control signal is applied to inform the outside of the hot plate overheating (S132).

However, if it is determined within 5 minutes, which is the maximum process time of the boiling maintenance process, it is recognized as a normal state and it is determined whether the boiling maintenance heating maximum temperature (125 ° C.) has been reached (S123). On the other hand, if it is determined that the state is reached, the control output for resetting the timer 20 is applied (S124), and then the process proceeds to the boiling maintenance process (S125).

When the moxibustion process is started, the heating progress of heating the hot plate is started and at the same time, the timer 20 is driven to turn on the timer 20 (S126). Here, the microcomputer 50 sets 25% time of each of the 12 + processes in the moxibustion process shown in FIG. 2 in the data storage unit 80 and compares them with the timer described above (S127). (At this time, the heater by the hot plate driving unit 50 is driven on and heating the hot plate.)

By the way, the heating of the hot plate is normally up to 12 minutes, which is the maximum process time of the moxibustion process, but when 12 minutes has elapsed, it is determined that 12 minutes + 25% time of each process read by the data storage unit 80 has elapsed. This determines that the inner pot is overheated, and thus the microcomputer 40 instructs to cancel the process (S131), of course, by applying a control signal to the hot plate driving unit 50 to drive off the hot plate heater and to the display unit 70. The control plate is applied to inform the outside of the hot plate overheating (S132).

However, if it is determined within 12 minutes, which is the maximum process time of the moxibustion process, it is recognized as a normal state and it is determined whether the maximum temperature of the moxibustion heating is reached (110 ° C.) (S128). On the other hand, if it is determined that the status is reached, a control output for resetting the timer 20 is applied (S129), and then the process proceeds to the boiling maintenance process (S130).

As described above, the present invention is intended to prevent overheating of the hotplate due to an inaccurate state in recognizing the end of the cooking process due to the foreign matter between the hotplate and the inner pot, while setting the maximum overheating time for each process in advance, during the cooking process. If it is determined that the maximum time of overheating has elapsed within the maximum temperature of the star, it is a useful invention that can be identified as overheating, thereby canceling the cooking process and confirming overheating from the outside.

The above description is only one embodiment of the present invention, and any change may be made within the scope of the present invention.

Claims (2)

In the cooking method by a microcomputer having a normal absorption process, heating process, boiling maintenance, moxibustion process, and thermal insulation process, a maximum process overheating time is generated by adding 25% of time to the maximum heating time for each process described above. A first step of setting a maximum process overheating time when each cooking process is started in a state of being previously stored in the data storage unit, and starting the initial process and simultaneously turning on the timer to perform heating; A second step of canceling the process, turning off the hot plate heater, and checking display unit if it is determined that the count of the timer according to the first heating step reaches the process overheat maximum time; In the first step, it is determined whether the heating maximum temperature of each process is reached, and when the heating maximum temperature is within, the process of the second step is returned. When the heating maximum temperature is higher, the timer is reset and the third process proceeds to the next process. Overheating prevention method of the electric heat cooker, characterized in that provided in the step. The method of claim 1, wherein each of the maximum overheating time is 12 minutes or more (12 + α) in the absorption process, 10 minutes or more (10 + α) in the heating step 1, or 10 minutes or more in the heating 2 step ( 10 + α), at least 5 minutes for boiling (5 + α) and at least 12 minutes for moxibustion (12 + α), wherein α is 25% of each process. How to prevent overheating of electric rice cooker.