KR100367749B1 - Heating cooker - Google Patents

Abstract

The present invention relates to a heating cooker, comprising a weight sensor 16 and a control circuit 17 for outputting a signal according to the weight of food, etc., wherein the control circuit 17 is output from the weight sensor 16 It functions as a weight determination means for determining the weight of the food at the reference zero point set at the signal level and at the present time, and also as a zero point changing means, and the function as the zero point changing means is performed every time before the start of heating. 17) When the signal is read out and the signal level is within the range of the predetermined level corresponding to the predetermined weight in view of the reference zero point, the reference zero point is changed and set based on the signal level. Regardless of the temporal change of the weight sensor, the weight determination result can always be obtained with high precision.

Description

Heat Cooker {HEATING COOKER}

The present invention relates to a heating cooker having a weight sensor.

Conventionally, the heating cooker is provided with a weight sensor for outputting a signal according to the weight of the food accommodated in the food support plate in the heating cooking chamber. These weight sensors include capacitance type and inductance type. The capacitive weight sensor includes a movable electrode and a fixed electrode or an oscillation circuit, and the capacitance changes due to the change in the separation distance from the fixed electrode due to the bending of the movable electrode according to the food weight. The minute is derived from the change of the output frequency of the oscillator circuit. That is, it is derived as a frequency signal. This output frequency is transmitted to a weight determining means made of, for example, a microcomputer. In this weight determination means, the frequency when the food weight is zero (the state in which nothing is placed on the food support plate) is stored in advance as a zero point, and the food weight is determined at the output frequency and zero point from the weight sensor.

In addition, the inductance type weight sensor is provided with a core member so as to be displaced according to the food weight, and a winding is installed at the stationary part, and an oscillation circuit is provided so that the displacement distance of the core member with respect to the winding is determined by the food weight. Therefore, it changes, and this uses the change in inductance of a winding. Also in this case, the inductance change is derived from the change of the output frequency of the oscillator circuit. The weight determination result is used as control data for heating cooking time and heating intensity.

However, conventionally, in a heating cooker, the environmental temperature of winter season and summer season is different, and the heating cooker main body itself is influenced by the temperature by heating cooking (initial temperature is different in initial cooking and continuous cooking), so that the weight sensor In addition, depending on the temperature, even if the food of the same weight, the level of the output signal may change, and as time passes, the signal level may increase or decrease as a whole.

However, in the above structure, since the zero point is fixedly set at the heating cooker side, the weight determination accuracy may deteriorate depending on the temperature situation or the temporal change, thereby causing unevenness in the cooking finish.

SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances, and its object is to provide accurate weight determination results at all times regardless of changes in temperature conditions or time changes of the weight sensor, and heating capable of good cooking. To provide a cooker.

1 is a block diagram of an electrical configuration showing one embodiment of the present invention;

2 is a perspective view of a heating cooker,

3 is a longitudinal sectional view of a heating cooker,

4 is a flowchart of a zero point change setting operation;

5 is a diagram illustrating a relationship between an output frequency and a food weight;

6 is a diagram showing a state of storing frequency data;

7 is a diagram illustrating an example of a change in frequency data.

* Explanation of symbols for the main parts of the drawings

4: heating cooking chamber 7: base plate

8: Question 16: Weight sensor

17: control circuit (weight determination means, zero point change means)

19: door open and close sensor (door open and close detection means)

The invention of claim 1 is a weight sensor for outputting a signal according to the weight of the food and the like contained in the heating cooking chamber,

Weight determination means for determining the weight of the food from the level of the signal output from the weight sensor and the reference zero point set at the present time;

When the signal from the weight sensor is read every time before the start of heating, and the signal level is within a range of a predetermined level corresponding to a predetermined weight when viewed from the reference zero point, the reference zero point is changed and set based on the signal level. It is characterized by including a zero point changing means.

In the above configuration, the weight determining means judges the weight of the food by judging the level of the signal output from the weight sensor by the reference zero point set at this point. In this case, before the start of heating by the zero point changing means, i.e. Since the reference zero point is changed every time before the food is accommodated in the heating cooking chamber, this reference zero point becomes the latest reference zero point before heating cooking. This sets the reference zero point according to the environmental temperature when the heating cooker is used in winter or summer, and also sets the reference zero point at the temperature state in the case of initial cooking or continuous cooking. Moreover, even if the output signal level changes with the temporal change of the weight sensor, the reference zero point corresponding to the level is set. As a result, when performing the weight determination by the output signal from the weight sensor, the output signal level can be determined by the appropriate reference zero point, and the weight determination accuracy is always appropriate.

In particular, for changing and setting the zero point, when the signal level from the weight sensor is within a range of a predetermined level corresponding to the predetermined weight as seen from the reference zero point set at the present time, the reference zero point is based on the signal level. Since the reference zero point to be changed this time is not set to a value which is extremely out of the reference zero point before the change. That is, the reference zero point change setting is made within an appropriate range in consideration of the temperature condition change or the temporal change, so that the reference zero point with high reliability is set.

The invention according to claim 2 reads a signal from the weight sensor every time before starting the zero point changing means, and the signal level is within a predetermined level range corresponding to a predetermined weight in view of the reference zero point for a predetermined time. Next, it is set as the structure which changes and sets the said reference zero point based on the signal level.

In this configuration, when the level of the signal from the weight sensor is within a predetermined level range corresponding to the weight of the predetermined range from the reference zero point continues for a predetermined time, the reference zero point is changed and set so that the setting accuracy of the reference zero point is set. Becomes higher. That is, when the weight sensor portion vibrates when the signal is introduced from the weight sensor (the weight sensor is likely to vibrate structurally), an error may occur temporarily in the signal level due to the influence thereof. Since the reference signal is stably obtained, the reference zero point is changed and set, and the setting accuracy of the reference zero point is increased.

According to the invention of claim 3, the signal from the weight sensor is read every time before the zero point changing means starts heating, and the situation is continued for a predetermined time when the signal level is within a range of a predetermined level corresponding to the predetermined weight as viewed from the reference zero point. And when the difference between the maximum value and the minimum value of the signal level is less than or equal to the predetermined value, the reference zero point is changed and set based on the signal level.

Even if the signal from the weight sensor is maintained for a predetermined time within a predetermined level range, it is advantageous for the reference zero point to set the smaller deviation of the signal level. As described above, in the above configuration, when the signal level is within the range of the predetermined level corresponding to the predetermined weight in terms of the reference zero point, the signal level is continued when the difference between the maximum value and the minimum value of the signal level is less than or equal to the predetermined value. Since the reference zero point is changed and set based on the above, the reference zero point can be set more appropriately.

In the invention according to claim 2 or 3, the zero point changing means may set the zero point of the food weight based on a value obtained by averaging the levels of signals read multiple times (invention of claim 4). In this way, a more appropriate reference zero point setting can be made.

In the invention of claim 5, the zero point changing means has a fixed zero point set as an invariant value separately from the reference zero point, and reads the signal from the weight sensor each time before starting heating, and the signal level thereof is the reference zero point. The reference zero point is changed and set based on the signal level when the signal level is within a range of a predetermined level corresponding to a predetermined weight and the signal level is less than or equal to a predetermined value for a predetermined weight as seen from the fixed zero point. It is characterized by that.

If the reference zero point is updated when the read signal level is within a predetermined range with respect to the reference zero point, the absolute value of the reference zero point may greatly deviate from the original reference zero point as the number of updates increases. In this case, it becomes inadequate as a reference zero point. By the way, in the said structure, it has a fixed zero point set as an invariant value separately from a reference zero point, and the level of the signal from a weight sensor exists in the range of the predetermined level corresponding to a predetermined weight by the reference zero point, and the said signal Since the reference zero point is set to be changed based on the signal level when the level is less than or equal to the allowable value for a predetermined weight as seen from the fixed zero point, the setting setting of the reference zero point is not executed when the allowable value is exceeded. In other words, there is no problem that an inappropriate reference zero point is set.

According to the invention of claim 1, the invention according to any one of claims 1, 2, 3 or 5 includes a door for opening and closing the heating cooking chamber, a door opening and closing detection means for detecting the opening and closing of the door,

The zero point changing means performs a zero point change setting operation when the door opening is detected by the door opening and closing detecting means before cooking.

When the cooking is finished, the door is opened to take out the food in the cooking chamber, and then closed. In addition, the door is opened immediately before the start of heating and closing after food storage. As can be understood from this, the change from the door opening to the door closing is often at the time of taking out food or at food receiving. The situation in which the door is left open is often a situation in which there is no food. By carrying out the zero point change setting operation at the time of opening the door, the zero point change setting operation in the state where food is accommodated can be completely eliminated, and the wrong setting is eliminated.

In this case, when the door opening is detected by the door opening / closing detection means before cooking, the zero point changing means does not execute the zero point changing setting operation even after the door opening is detected thereafter after the zero point changing setting operation is executed. You may make it (invention of Claim 7). This eliminates the missetting of the reference zero point.

That is, when the reference zero point is changed and set on the condition that the signal level from the weight sensor when the door is open is within a range of a predetermined level corresponding to the predetermined weight as viewed from the reference zero point, When food below the predetermined range weight is accommodated, it is feared to make the food weight a reference zero point. However, in the above configuration, after the zero point change setting operation is executed, the zero point change setting operation is not executed even if the door opening is detected thereafter. Therefore, the door is opened after the reference zero point setting and the food is accommodated. Even if the reference zero point is misconfigured.

The invention of claim 8 is the invention according to any one of claims 1, 2, 3 or 5, wherein the door for opening and closing the heating cooking chamber, the door opening and closing detection means for detecting the opening and closing of the door, and the predetermined condition is satisfied after the completion of cooking. Automatic power cut means for turning off the power when

The zero point changing means is configured to perform zero point changing setting in a state where the power is turned off by the automatic power cutting means and when the door is detected to be opened by the door opening / closing detecting means.

The situation where the power is turned off by the automatic power cut means is before the start of the next cooking (also after the last cooking is finished), and in this situation, the door is often opened just before the start of cooking. In the automatic power cut situation, a considerable time has elapsed since the end of cooking, and almost no food is accommodated in the heating cooking chamber. Therefore, it is most suitable as the zero point change timing to perform the zero point change setting in a state where the power is turned off by the automatic power cut means as described above and when the door is opened.

Embodiment of the Invention

EMBODIMENT OF THE INVENTION Hereinafter, one Example of this invention is described, referring drawings. First, in FIG. 2 and FIG. 3, the heating cooker main body 1 is comprised by the outer box 2 and the inner box 3, and the inside of the inner box 3 is used as the heating cooking chamber 4. As shown in FIG. The drive shaft 5a is inserted through the bottom plate in the heating cooking chamber 4, and the lower end thereof is supported by the weight sensor 16 described later, and the drive shaft 5a is driven by the turntable motor 5. It is supposed to rotate. At the upper end of the drive shaft 5a, a rotating body 6 made of a metal disk formed in a mesh shape is connected. The supporting plate 7 on which food is placed is detachably attached to this rotating body 6. In addition, the heating cooking chamber 4 is opened and closed by the door 8. Moreover, the upper heater 9 which consists of tubular heaters is provided in the upper surface of the heating cooking chamber 4, and the lower heater 10 which consists of surface heaters is provided in the outer side of a bottom plate.

The panel 11 is provided in front of the side of the door 8 of this heating cooker main body 1, and various switch groups 12, the indicator 13, etc. are provided in this. In addition, the switch group 9 includes a selection switch for selecting the magnetron heating cooking and the heater heating cooking, a start switch, a time setting switch for setting the heating cooking time or a cancellation switch. A machine room (not shown) is formed inside the panel 11, and the magnetron 14 and cooling fan 15 shown in FIG. 1 are provided inside the panel 11.

A weight sensor 16 is provided below the bottom plate of the heating cooking chamber 4, which supports the drive shaft 5a, and outputs a signal corresponding to the load applied thereto. In other words, the weight sensor 16 is of capacitance type and includes a movable electrode, a fixed electrode, an oscillation circuit, and the like, although the movable electrode is bent according to the food weight, and the separation distance from the fixed electrode is changed. The capacitance changes, and this change is derived from the change in the output frequency of the oscillator circuit. That is, it is derived as a frequency signal. This output frequency is transmitted to the control circuit 17 shown in FIG.

The control circuit 17 includes, for example, a microcomputer, to which each switch input from the switch input unit 18 including the switch group 12 is transmitted, and for example, a limit switch. A signal is transmitted from the door open / close sensor 19 which consists of a switch. The door open / close sensor 19 corresponds to a door open / close detection means, and outputs a door open detection signal So when the door 8 is opened, and outputs a door close detection signal Sc when the door 8 is closed. It is supposed to output. The control circuit 17 drives and controls the indicator 13 according to the heating cooking control program, and opens the drive circuit 20 to open the turntable motor 5, the upper heater 9, the lower heater 10, and the magnetron ( 14) and the cooling fan 15 are drive controlled, and the writing and reading of the nonvolatile memory 21 is performed.

The weight sensor 16 outputs a frequency, for example, as shown in FIG. 5. In this FIG. 5, the base plate 7 is disposed on the rotating body 6, and the food is “0g”. In this state, the frequency level corresponding to this "0g" is a so-called zero point. In addition, in this FIG. 5, the case in which the temperature in the heating cooking chamber 4 is 25 degreeC is shown, and when this temperature becomes high, the characteristic line Pa tends to shift to a low frequency direction (refer the dashed-dotted line). In other words, the zero point is lowered.

The control circuit 17 functions as a weight determination means and a zero point change means, and this weight determination method is as follows. That is, the control circuit 17 stores the relationship between the frequency data and the food weight data indicated by the relationship of FIG. 5, and this zero point (in this case, the output frequency 50.00 kHz) and the output frequency from the weight sensor 16 The weight is determined based on.

The control circuit 17 stores data used for weight determination in the ROM in advance, and the data will be described as follows (see Fig. 7).

Fixed Zero Point (WF): This is what the manufacturer remembered before shipping.

Permissible value (gamma): It is the frequency of predetermined weight with respect to the fixed zero point WF, and the predetermined weight is "250g", for example.

The predetermined level (alpha): It is the frequency level corresponding to the predetermined weight with respect to the reference zero point (W0 or Wa (described later)), The predetermined weight is "60g", for example.

On the other hand, the reference zero point W0 is stored in the nonvolatile memory 21, which is set and stored by a user's operation. That is, the setting operation method of the reference zero point W0 is described in the instruction manual accompanying this heating cooker, and this reference zero point W0 is memorize | stored when operating according to the setting operation method. The setting operation method is, for example, connecting a power plug to a commercial power source, placing the support plate 7 (no food), closing the door 8, and on-operating the cancel switch. When this operation is made, the control circuit 17 writes the frequency level output from the weight sensor 16 to the nonvolatile memory W0 as the reference zero point W0. This reference zero point W0 is used initially as an initial value of the change setting of the reference zero point, and when the change setting of the reference zero point is made, the reference zero point is then used as the reference zero point Wa.

The reference zero point Wa is automatically executed by the setting control of the control circuit 17 each time before the start of cooking. The control of the reference zero point Wa is also referred to in the flowchart of FIG. 4. Explain.

This flowchart starts when the power plug is connected to a commercial power source. In this flowchart, the control of setting the reference zero point W0 based on the user's operation described above is omitted.

Now, the first reference zero point change setting operation will be described. In this case, it is assumed that the reference zero point W0 for the initial value by the user's operation is set, the support plate 7 is arranged, the cooking is finished, and the food is not placed (not accommodated). The flow of the flowchart will be described.

In step S1, the fixed zero point WF, the allowable value γ, and the predetermined level α are read. In step S2, it is determined whether or not the reference zero point W0 for the initial value by the user operation is set (determining whether or not the reference zero point W0 is stored in the nonvolatile memory 21). In this case, since this reference zero point W0 is assumed to be set, the flow advances to step S3 to determine whether or not it is before cooking. That is, it is determined whether the cooking operation is not performed by the heating cooking control program. In this case, since the cooking operation is not performed, it is determined that the cooking operation has been performed, and the flow proceeds to step S4.

In this step S4, it is determined whether the door 8 is opened from the closed state, that is, whether the door open / close sensor 19 has input of the door open detection signal So, and the door 8 is opened. If yes, the flow proceeds to step S5.

In this step S5, as shown in Fig. 6A, all the stored values of the frequency data storage units E1 to E5 (see Fig. 6) of the RAM are cleared, and the zero point setting operation starts and ends. The parameter Q is set to "1" ("1" means start and "0" means end or stop). In the next step S6, it is determined whether the zero point setting operation is being performed, that is, whether the parameter Q is "1", and if it is during the zero point setting operation, the flow advances to step S7 to output the frequency from the weight sensor 16. Is read and stored in the first-stage storage unit E1 of the frequency data storage units E1 to E5 as frequency data Wa1 (see FIG. 6 (b)). In this case, the stored contents of each of the storage sections E1 to E4 are shifted upward. This frequency integrates the frequency pulse for 0.25 second per one time, and the frequency is measured from the integrated value.

In the next step S8, the difference between the maximum value and the minimum value of the stored data of each of E1 to E5 (in the case of Fig. 6B, difference between "Wa1" and "0", this difference is treated as an absolute value). Is converted into weight. And in step S9, it is determined whether this converted weight is "20g" or less. "20g" is a weight conversion value of a predetermined value corresponding to the difference between the maximum value and the minimum value. Here, the weight conversion value of the difference between the frequency data "Wa1" and "0" is usually "20g" or more, and returns to step S2 according to "NO" of step S9. In this step S2, since the reference zero point W0 is already set, the process shifts to steps S3 and S4 once again. If the door 8 is open, there is no change from the door opening to the door closing. Therefore, the flow proceeds to step S15 in accordance with "NO".

In step S15, it is determined whether there has been a change from the door opening to the door closing. If the door 8 remains in the open state, the process proceeds to step S6 described above, and this step S6 (reference zero point setting). Judgment of whether it is in operation or not, step S7 (reading and storing frequency data), step S8 (weight conversion of the difference between the maximum value and the minimum value) and step S9 (determination of whether or not 20g or less) In a normal case, the flow proceeds from step S9 to step S2 again, and the above-described flow is repeated.

That is, if the door 8 remains open, the frequency data from the weight sensor 16 is read in sequence, and the frequency data Wa1 to Wa5 for five times is shown in Fig. 6D. If all data are stored in the data storage units E1 to E5, the frequency data "O" is lost. If there is no abnormality in each value of the frequency data Wa1 to Wa5, the weight conversion of the difference between the maximum value and the minimum value in step S8 is performed. The value becomes below the weight conversion value "20g". In addition, if any one of the abnormal values appears in the frequency data Wa1 to Wa5, the value exceeds "20 g". Therefore, the frequency data Wa1 to Wa5 for five consecutive times is shifted to "YES" in step S9. It is necessary to be an approximate value (continuously stable value). In this case, in this flowchart, reading of each signal takes about 0.25 seconds, and therefore, when stable frequency data is obtained between 1.25 seconds, the process shifts from "YES" in step S9 to step S10.

In this step S10, three frequency data except for the maximum value and the minimum value among the frequency data Wa1 to Wa5 for five consecutive times are averaged, and the average frequency data is set to the reference zero point set at this time. When the weight is converted based on the reference zero point (W0)). In step S11, it is determined whether or not this converted weight (weight converted from the reference zero point W0) is within a predetermined weight "60g" (this corresponds to a predetermined level "α").

Here, the frequency data Wa1 to Wa5 for five consecutive times are stable values in which the mutual difference is within " 20 g ", among which the frequency data of three intermediate values are converted weights equal to " 60 g " as seen from the reference zero point W0. That is, all the data of the frequency data Wa1 to Wa5 for five consecutive times show the value close to "60g +/- 10g".

In step S11, when it is determined that it is within " 60 g ", the average frequency data is converted into the weight at the fixed zero point WF, and in step S13, the converted weight is a preset allowable value ( It is determined whether or not the above "25Og", which is the weight equivalent to γ), and if within "250g", the average frequency data is stored in the RAM, for example, as a new reference zero point Wa (change setting).

If it is determined in step S15 that there is a change from the door opening to the door closing in step S15, the flow advances to step S16 to determine whether the zero point setting operation is in progress, and if the zero point setting operation is in step S17. The above-mentioned parameter Q is made into "O", and it progresses to step S6. In other words, the zero point setting operation started on the condition that the door 8 is opened stops when the door 8 is closed halfway (while not satisfied with 5 proper frequency data readings). Therefore, as the reference zero point, the previous reference zero point is used for the weight determination.

The relationship between the flowchart and the user's situation will be described with reference to FIG. 7. Now, it is assumed that the supporting plate 7 is not set. When the door 8 is opened before cooking (time t1), the frequency data storage units E1 to E5 of the control circuit 17 are cleared (frequency "O"). The control circuit 17 reads and stores the frequency from the weight sensor 16 once for 0.25 seconds. This read memory operation continues until the frequencies of the memory units E1 to E5 do not have a difference of "20 g" from each other. At the time point t1, the base plate 7 is not provided, but the frequency sensor 16 outputs a frequency Wx that is considerably higher than "O", and there is a difference of "20g".

After the support plate 7 is installed (time t2), the frequency corresponding to food zero is read and stored, but the maximum value and the minimum value of the five stored values Wa1 to Wa5 are less than or equal to "20 g." When the converted weight is less than or equal to "60 g" (absolute value) from the reference zero point W0, the reference zero point Wa is set (time point t3). At the same time, this zero point change setting operation is completed.

In addition, at the time t2 where the support plate 7 is installed, the frequency is abnormally high or low due to the vibration, and the frequency of this part is temporarily stored, but the condition of "20 g" is not cleared. The frequency five times after the frequency generation point of the portion is stored.

Thereafter, food is received (time t4), the door 7 is closed (time t5), cooking starts at time t6 (when the start switch is operated), and the weight determination operation is executed. Will be. In this case, the frequency is read out and measured for 0.25 seconds from the weight sensor 16, and this frequency data is converted into the present weight at the reference zero point Wa at this point in time.

When the cooking is finished, the above-described reference zero point setting operation is executed before each cooking start. In the reference zero point change setting operation of the second transition as described above, the previously set reference zero point Wa is changed and set (the reference zero point W0 is used only for the first time).

According to the present embodiment as described above, the following effects can be obtained.

That is, since change setting control with respect to the reference zero point W0 or Wa is performed before every heating start, this newly set reference zero point Wa becomes the reference zero point Wa according to the situation before heating cooking. Thus, when the heating cooker is used in winter or summer, the reference zero point Wa according to the environmental temperature is set, and the reference zero point at the temperature state in the case of initial cooking or continuous cooking ( Wa), and even if the output frequency level changes with the temporal change of the weight sensor 16, the reference zero point Wa corresponding to the level is set.

Thus, when the food weight determination is made by the control circuit 17, the output frequency level can be determined by the appropriate reference zero point Wa, and the weight determination accuracy is always appropriate.

In particular, for changing and setting the reference zero point W0 or Wa, the level of the frequency from the weight sensor 16 is a predetermined level corresponding to the predetermined weight as seen from the reference zero point W0 or Wa set at this point. When the reference zero point (W0 or Wa) is set to be changed based on the frequency level in the range, in this case, in the range of the equivalent weight range of "60 g ± 10 g," the reference zero point Wa that has been changed this time is set. It is not set to a value that deviates extremely from the reference zero point W0 or Wa before the change. That is, a change setting of the reference zero point W0 or Wa is made within an appropriate range in consideration of the temperature condition change or the temporal change, so that a reliable reference zero point is set.

In this embodiment, the frequency from the weight sensor 16 is read out, and the converted weight is approximately within the range of " 60 g ± 10 g " when the frequency level is viewed from the reference zero point W0 or Wa at this point. Since the reference zero point W0 or Wa is changed and set based on the frequency level when the present condition continues for a predetermined time and 1.25 seconds, the reference zero point is obtained after the frequency from the weight sensor 16 is stably obtained. (Wa) is changed and set, and the setting precision of the reference zero point (Wa) is increased.

The weight sensor 16 is structurally easy to vibrate, and when the cooker main body 1 vibrates when the door 8 is opened, the weight sensor 16 also vibrates, until the vibration is attenuated. It may take time. In such a case, even if the frequency level is within the predetermined range from the reference zero point W0 or Wa, the frequency level change from the weight sensor 16 is severe and there is a fear that the setting accuracy of the reference zero point Wa is lowered.

By the way, in the present embodiment, when the difference between the maximum value and the minimum value of the frequency from the weight sensor 16 is equal to or less than a predetermined value (20 g in terms of weight), the reference zero point W0 or Wa is changed and set, so that an error such as vibration may occur. In a state where there is no factor, the reference zero point W0 or Wa is changed and set, and the setting precision of the reference zero point Wa is increased.

In particular, since the reference zero point Wa of the food weight is set based on the average value of the frequencies of the frequency read five times in this case, a more appropriate reference zero point can be set.

However, if the reference zero point Wa is updated when the frequency level read with respect to the reference zero point W0 or Wa is within a predetermined range, the absolute value of the reference zero point Wa initially increases as the number of updates increases. There is a fear that the deviation from the standard zero point Wa. In this case, it becomes inadequate as a reference zero point.

By the way, in the said structure, the reference zero point W0 or Wa has the fixed zero point WF set separately as an invariant value, and the level of the frequency from the weight sensor 16 is seen from the fixed zero point WF. If the reference zero point (W0 or Wa) is set to be changed based on the frequency level when the value is equal to or smaller than the allowable value (γ) corresponding to the weight "250g," the reference zero point (W0 or Wa) is exceeded. ) Change settings are not executed. In other words, it is possible to eliminate the setting of an inappropriate reference zero point.

In addition, according to the present embodiment, it is possible to satisfactorily capture the time when food is not accommodated and perform the zero point change setting operation. That is, when the heating cooking is finished, the door 8 is opened to take out the food in the heating cooking chamber 4, and then closed. In addition, the door 8 is opened immediately before the start of cooking, and closed after food storage. As can be understood from this, the change from the opening of the door 8 to the closing of the door 8 is often at the time of taking out food or at food receiving. And the situation in which the door 8 is in the open state is a situation where there is no food in many cases. By performing the zero point change setting operation at the time of opening the door 8, the zero point change setting operation in a state where food is accommodated can be completely eliminated, and thus incorrect setting is eliminated.

In addition, since the initial reference zero point W0 is set on the user side, an appropriate value can be obtained as the initial reference zero point. That is, it is conceivable to use the fixed zero point (WF) as the initial reference zero point, but this fixed zero point (FW) is set before shipment of the heating cooker, which is a product. It is also concerned that errors occur in the output. Therefore, it can be said that it is slightly unsuitable as an initial reference zero point. If there is no concern as described above, the fixed zero point WF can be used as the first reference zero point.

In addition, you may change this invention as follows (A)-(C).

(A) Before cooking, after opening of the door 8 is detected by the door opening / closing sensor 19 and the zero point changing setting operation is executed, even after opening of the door 8 is detected, the zero point changing setting operation You may not run. This eliminates the missetting of the reference zero point.

That is, when the door 8 is open, the reference zero is provided on the condition that the level of the frequency from the weight sensor 16 is within a range of a predetermined level corresponding to the predetermined weight as viewed from the reference zero point W0 or Wa. In the case of changing the point setting, the weight of the food is taken as the reference zero point even when food having a predetermined weight or less (e.g., light food of 60 g ± 10 g or less) is accommodated at the time when the door 8 is opened. I'm concerned.

Therefore, after performing the zero point change setting operation as described above, the door 8 is opened after the reference zero point setting so as not to execute the zero point change setting operation even after the door 8 is opened. Even if food is received, the missetting of the reference zero point is lost.

(B) An automatic power supply cutting means for turning off the power when a predetermined condition is satisfied after the completion of cooking, wherein the door is detected to be opened by the automatic power cutting means and the door opening and closing detection means. It is good also as a structure which implements a zero point change setting.

The situation where the power is turned off by the automatic power cut means is before the start of the next cooking (also after the last cooking is finished), and in this situation, the door is often opened just before the start of cooking. The automatic power supply cutting situation is a case where a considerable time has elapsed since the end of cooking, and the food is rarely stored in the heating cooking chamber. Therefore, it is most suitable as the zero point change timing to perform the zero point change setting in a state where the power is turned off by the automatic power cut means as described above and when the door is opened.

(C) In the above embodiment, the frequency data from the weight sensor 16 is read five times, but this may be once, and the desired purpose can be achieved.

The present invention may be modified in various ways in addition to the above. For example, the weight sensor may be an inductance type or an optical sensor or the like as the door opening / closing detection means. As the output signal from the weight sensor, it is also possible to use a frequency-voltage converter to form a voltage signal.

As will be apparent from the above description, the present invention can obtain the following effects.

According to the invention of claim 1, since the reference zero point is changed and set every time before the start of heating by the zero point changing means, this reference zero point becomes an appropriate reference zero point according to the temperature situation or the temporal change situation of the weight sensor. When performing the weight determination by the output signal from the weight sensor, the output signal level can be determined by an appropriate reference zero point, and the weight determination accuracy is very appropriate. Further, in changing and setting the reference zero point, when the level of the signal from the weight sensor is within a range of a predetermined level corresponding to the predetermined weight as seen from the reference zero point set at the present time, the reference zero point is based on the signal level. Since the point is changed and set, the reference zero point set this time is not set to a value which is extremely out of the reference zero point before the change, so that a reliable reference zero point can be set.

In the invention of claim 2, when the signal level from the weight sensor is within a predetermined level range corresponding to the predetermined weight at the reference zero point, the reference zero point is changed and set based on the signal level. After the signal from the sensor is obtained stably, the reference zero point is changed and set, whereby the setting accuracy of the reference zero point is increased.

According to the invention of claim 3, when the signal level from the weight sensor is within a range of a predetermined level corresponding to the predetermined weight at the reference zero point, the situation continues for a predetermined time, and when the difference between the maximum value and the minimum value of the signal level is less than or equal to the predetermined value, Since the reference zero point is changed and set based on the signal level, the reference zero point can be changed and set without any error factor such as vibration, thereby improving the setting accuracy of the reference zero point.

According to the invention of claim 4, since the reference zero point of the food weight is set based on the average value of the signals read multiple times, more appropriate reference zero point can be set.

According to the invention of claim 5, it has a fixed zero point set as a constant value separately from the reference zero point, and reads the signal from the weight sensor every time before the start of heating, and its signal level corresponds to the predetermined weight as seen from the reference zero point. The reference zero point is changed to be set based on the signal level when the signal level is within a range of a predetermined level and the signal level is less than an allowable value for a predetermined weight from the fixed zero point. There is no problem that the point is set.

According to the invention of claim 6, since the zero point change setting operation is performed when the door opening is detected by the door opening / closing detection means before cooking, the zero point change setting operation in the state where food is accommodated is not performed. The setting is lost.

According to the invention of claim 7, after performing the zero point change setting operation when the door opening is detected by the door opening / closing detection means before cooking, the zero point change setting operation is not executed even after the door opening is detected thereafter. By doing so, the missetting of the reference zero point is eliminated.

According to the invention of claim 8, since the zero point change setting is made in the state where the power is turned off by the automatic power cut means and when the door is detected by the door open / close detection means, it is most suitable as the zero point change timing. Do.

Claims (8)

A weight sensor that outputs a signal according to the weight of foods contained in the heating cooking chamber; Weight determination means for determining the weight of the food at the level of the signal output from the weight sensor and the reference zero point set at this time; and Each time before the start of heating, the signal from the weight sensor is read out and the reference zero point is changed and set based on the signal level when the signal level is within a range of a predetermined level corresponding to a predetermined weight as seen from the reference zero point. Heating cooker characterized in that it comprises a zero point changing means. A weight sensor that outputs a signal according to the weight of foods contained in the heating cooking chamber; Weight determination means for determining the weight of the food at the level of the signal output from the weight sensor and the reference zero point set at this time; Each time before the start of heating, a signal from the weight sensor is read out, and when the situation continues for a predetermined time when the signal level is within a range of a predetermined level corresponding to a predetermined weight as seen from the reference zero point, the signal is based on the signal level. And a zero point changing means for changing and setting the reference zero point. A weight sensor that outputs a signal according to the weight of foods contained in the heating cooking chamber; Weight determination means for determining the weight of the food at the level of the signal output from the weight sensor and the reference zero point set at this time; Each time before the start of heating, the signal from the weight sensor is read out, and the situation in which the signal level is within the range of the predetermined level corresponding to the predetermined weight in view of the reference zero point continues for a predetermined time, and the maximum value of the signal level And zero point changing means for changing and setting the reference zero point based on the signal level when the difference between the minimum values is less than or equal to a predetermined value. The method of claim 2 or 3, And the zero point changing means sets the zero point of the food weight based on a value obtained by averaging the levels of the signals read out a plurality of times. A weight sensor that outputs a signal according to the weight of foods contained in the heating cooking chamber; Weight determination means for determining the weight of the food at the level of the signal output from the weight sensor and the reference zero point set at this time; It has a fixed zero point set as an invariant value separately from the reference zero point, and reads the signal from the weight sensor every time before the start of heating, and the signal level is of a predetermined level that corresponds to the predetermined weight as seen from the reference zero point. And a zero point changing means for changing and setting the reference zero point based on the signal level when the signal level is within a range and the signal level is equal to or less than a allowable value for a predetermined weight as viewed from the fixed zero point. . The method according to any one of claims 1, 2, 3 or 5, Door to open and close the heating cooking room, and It is provided with a door opening and closing detection means for detecting the opening and closing of the door, And the zero point changing means is configured to perform a zero point change setting operation when the door is detected to be opened by the door open / close detection means before cooking. The method of claim 6, The zero point changing means is configured not to execute the zero point change setting operation after the zero point change setting operation is performed after the door opening is detected by the door opening / closing detection means before cooking. Heat cooker, characterized in that. The method according to any one of claims 1, 2, 3 or 5, Doors to open and close heating cooking rooms, Door opening and closing detection means for detecting opening and closing of the door, and It is equipped with an automatic power cut means for turning off the power when a predetermined condition is satisfied after the end of cooking, And the zero point changing means is configured to perform the zero point change setting in a state where the power is turned off by the automatic power cutting means and when the door is detected by the door open / close detection means.