JP2022042093A - Stove - Google Patents

Abstract

To provide a stove that can reduce power used for display.SOLUTION: A stove 1 is battery operated. The stove 1 includes a display module. The display module includes a display control circuit and a display unit 62. The display unit 62 is provided on the front surface of an upper panel 91 of a left panel unit 9 of a housing 2. The display unit 62 is composed of an electronic paper that can hold a display content and can be electrically updated. The display unit 62 can display various types of information. The display control circuit displays and updates various pieces of information on the display unit 62. As a result, the stove 1 can continue to display information without power consumption after displaying the information on the display unit 62. Therefore, the stove 1 can save power consumption.SELECTED DRAWING: Figure 1

Description

The present invention relates to a stove.

Conventionally, a dry battery-powered gas stove in which an operation panel portion is provided on the front surface of an instrument is known (see, for example, Patent Document 1). The operation panel unit is provided with various display units such as a timer display unit, a temperature display lamp, and a battery replacement sign. The timer display unit is a 7-segment display and displays the set time of the stove timer and the grill timer. The temperature display lamp can display the set temperature set in the temperature keeping function, and is composed of four LEDs corresponding to, for example, 200 ° C, 180 ° C, 160 ° C, and 140 ° C, respectively. The battery replacement sign lights up when the dry battery voltage falls below a predetermined threshold.

Japanese Unexamined Patent Publication No. 2020-18136

In the gas stove described in Patent Document 1, in addition to the igniter electrode driven when the burner is ignited, electric power is also used in various display units of the operation panel unit, so that there is a problem that the decrease in the dry battery voltage is likely to accelerate. Further, since the battery replacement sign is turned on when the dry battery voltage drops, there is also a problem that the drop in the dry battery voltage is further accelerated.

An object of the present invention is to provide a stove capable of reducing the electric power used for display.

The stove according to claim 1 is a battery-powered stove, which is composed of an electronic paper that can hold display contents and can be electrically updated, and has a display unit capable of displaying various information and various types of the display unit. It is characterized by having a display control unit for displaying and updating information.

The display unit of the stove according to claim 2 may be provided on the front surface of the stove.

The display unit of the stove according to claim 3 may be provided on the top plate of the stove.

The controller according to claim 4 includes a voltage measuring unit that measures the voltage of a dry battery and a remaining battery remaining amount calculating unit that calculates the remaining battery level based on the voltage measured by the voltage measuring unit, and the display control unit is the balance. The remaining amount display unit may be provided to display the remaining battery level calculated by the quantity calculation unit on the display unit.

The remaining amount display unit of the stove according to claim 5 may display the remaining battery level stepwise by the length of the data bar corresponding to the remaining battery level.

The remaining amount display unit of the stove according to claim 6 may display the remaining amount of the battery stepwise by a numerical value.

The stove according to claim 7 includes a drive unit for operating the stove and a power supply unit for supplying electric power from the dry battery to the drive unit, and the display control unit may be supplied with the electric power from the power supply unit. good.

The stove according to claim 8 is the display from a drive unit for operating the stove, a power supply unit for supplying electric power from the dry battery to the drive unit, and a display dry battery as a power source for driving the display unit and the display control unit. A display power supply unit that supplies electric power to the unit and the display control unit may be provided.

The control according to claim 9 includes a display voltage measuring unit that measures the voltage of the display dry battery, a determination unit that determines whether the voltage measured by the display voltage measurement unit is less than a threshold value, and the determination unit that determines whether the voltage is less than the threshold value. If it is determined that the voltage is less than the threshold value, may include a supplementary power supply unit for supplying the power from the power supply unit to the display control unit and the display unit.

According to the stove of claim 1, since the display unit is composed of electronic paper, after displaying the information on the display unit, it is possible to continue displaying the information without power consumption. As a result, the stove can save power consumption.

According to the stove of claim 2, since the display unit is provided on the front surface of the stove, various information displayed on the display unit can be easily visually recognized at a position easily visible to the user.

According to the stove of claim 3, since the display unit is provided on the top plate, various information displayed on the display unit can be easily visually recognized at a position easily visible to the user.

According to the stove of claim 4, the remaining battery level of the dry battery can be displayed on the display unit with low power consumption.

According to the control of claim 5, since the remaining battery level is displayed stepwise on the data bar in the electronic paper, the remaining battery level can be visually recognized.

According to the stove of claim 6, since the remaining battery level is displayed in a numerical value stepwise on the electronic paper, the remaining battery level can be easily recognized.

According to the stove of claim 7, since the display control unit and the display unit receive electric power from the power supply unit, the existing stove can be used.

According to the stove of claim 8, since electric power can be supplied to the display control unit from a display power supply unit separate from the power supply unit, it is possible to prevent the battery life of the dry battery from being affected.

According to the stove of claim 9, when the battery level of the display dry battery is low, the electric power can be replenished from the power supply unit, so that the display can be changed.

It is a perspective view of the stove 1 (the first embodiment). It is a block diagram which shows the electric structure of a stove 1. It is a figure which shows three aspects (A)-(C) that the battery icon 80 is displayed on the display part 62. It is a figure which shows the display mode (A)-(E) of the battery icon 80 according to the battery remaining amount of 5 steps. It is a flowchart of battery remaining amount display processing. It is a flowchart of the power supply confirmation process for display. It is a block diagram which shows the electric structure of the stove 100 (second embodiment). It is a flowchart of the battery remaining amount display processing (second embodiment). It is a perspective view of a stove 200 (a modified example).

Hereinafter, the first and second embodiments of the present invention will be described. Unless otherwise specified, the external configuration, electrical configuration, control processing, and the like of the device described below are not intended to be limited thereto, but are merely explanatory examples. The drawings are used to illustrate the technical features that can be adopted by the present invention.

The stove 1 of the first embodiment will be described. The structure of the stove 1 will be described with reference to FIG. The stove 1 is a built-in stove. The stove 1 includes a housing 2 and a top plate 3. The upper part of the housing 2 is open, and the top plate 3 is installed in the opening portion. On the upper surface of the top plate 3, the right stove burner 4 (hereinafter referred to as the right stove 4) is on the right front side, the left stove burner 5 (hereinafter referred to as the left stove 5) is on the left front side, and the back stove is on the back side of the center. A burner 6 (hereinafter referred to as a back stove 6) is provided. A large number of flame holes are provided on the side surfaces of the right stove 4, the left stove 5, and the back stove 6. An ignition electrode of an igniter 51 (see FIG. 2) and a thermocouple 53 (see FIG. 2) are provided in the vicinity of each of the right stove 4, the left stove 5, and the back stove 6 so as to face the flame hole. When the igniter 51 is driven, a spark discharge is generated at the ignition electrode and ignites the gas ejected from the flame hole. The thermocouple 53 is heated by the flame formed in the flame hole to generate a thermoelectromotive force. The stove 1 can detect the disappearance of the right stove 4, the left stove 5, and the back stove 6 based on the thermoelectromotive force generated in the thermocouple 53.

A thermistor 52 projecting upward is provided at substantially the center of each of the right stove 4, the left stove 5, and the back stove 6. The thermistor 52 comes into contact with the bottom of the pot placed on the trivet and is pushed down to detect the temperature of the bottom of the pot. An exhaust port 7 of a grill device (not shown) installed in the housing 2 is provided at the rear portion of the top plate 3. A grill door 10 is provided at substantially the center of the front surface of the stove 1. The grill door 10 opens and closes an opening on the front side of a grill storage (not shown) provided in the grill device. A grill burner (not shown), an igniter 51, a thermocouple 53, and the like are provided in the grill chamber. The grill burner heats the food to be cooked on the gridiron (not shown) arranged in the grill. The ignition electrode of the igniter 51 and the thermocouple 53 are provided so as to face the flame hole of the grill burner.

A right panel portion 8 is provided in the area on the right side of the grill door 10. The right panel portion 8 includes an upper panel 81 and a lower panel 82. The upper panel 81 is provided with two operation knobs 11 and 12. The operation knobs 11 and 12 are provided side by side in the horizontal direction, and are operated to ignite, extinguish, and adjust the thermal power of the right stove 4 and the grill burner. When the lower panel 82 is pushed in with a finger, the operation panel 23 (see FIG. 2) fixed to the back surface of the lower panel 82 is pulled out by rotating forward with the lower part as a base point by a well-known push-push mechanism (not shown). Is done. Although not shown, the operation panel 23 is provided with a right stove 4, a left stove 5, a back stove 6, an operation unit for making various settings of the grill device, a display unit for displaying the timer time, and the like. The display unit of the operation panel 23 is, for example, a 7-segment display, a liquid crystal display, or the like.

A left panel portion 9 is provided in the area on the left side of the grill door 10. The left panel portion 9 includes an upper panel 91 and a lower panel 92. The upper panel 91 is provided with two operation knobs 13 and 14 and a display unit 62. The operation knobs 13 and 14 are provided side by side in the horizontal direction, and are operated to ignite, extinguish the fire, and adjust the thermal power of the back stove 6 and the left stove 5. The display unit 62 is provided on the lower side of the operation knobs 13 and 14, and is formed in a substantially rectangular shape in front view. The display unit 62 is an electronic paper and is incorporated in a display module 60 described later. The display unit 62 displays the remaining battery level, which will be described later. The lower panel 92 is detachably attached to the front surface of the left panel portion 9, and when the lower panel 92 is removed, two dry battery boxes (not shown) are exposed. The two dry battery boxes are a first battery box and a second battery box. The first battery box stores the dry battery 17 for the stove (see FIG. 2). The second battery box stores the dry battery 18 (see FIG. 2) for display in the display unit 62.

The electrical configuration of the stove 1 will be described with reference to FIG. The stove 1 includes a control circuit 30. The control circuit 30 includes a CPU 31, a ROM 32, a RAM 33, a flash memory 34, and the like. The CPU 31 controls the operation of the stove 1 in an integrated manner. The ROM 32 stores various programs including a battery level display program. The battery remaining amount display program is a program for executing the battery remaining amount display process (see FIGS. 5 and 6) described later. The RAM 33 temporarily stores various information. The flash memory 34 is non-volatile and stores various data.

The control circuit 30 includes a power supply circuit 35, a switch input circuit 36, a panel control circuit 37, a display module 60, an igniter circuit 41, a thermista circuit 42, a misfire detection circuit 43, a safety valve circuit 44, a solenoid valve circuit 45, and a power supply switching unit 601. Etc. are connected.

The board switch 21 and the igniter switch 22 are connected to the switch input circuit 36. The board switch 21 is turned on and off in conjunction with the operation of the corresponding operation knobs 11 to 14. The switch input circuit 36 detects the state of the board switch 21 and inputs it to the power supply circuit 35 and the control circuit 30. The igniter switch 22 is turned on after the board switch 21 is turned on in the process of pushing the corresponding operation knobs 11 to 14, and the board switch 21 is turned off in the process of pushing back the operation knobs 11 to 14. Also turns off first. The switch input circuit 36 detects the state of the igniter switch 22 and inputs it to the control circuit 30.

The power supply circuit 35 supplies electric power supplied from the dry battery 17 housed in the first battery box to various circuits when the board switch 21 of any of the operation knobs 11 to 14 is turned on. The power of the stove 1 is turned on. The power supply circuit 35 stops the power supply from the dry battery 17 to various circuits when all the board switches 21 of the operation knobs 11 to 14 are turned off. The power of the stove 1 is turned off. The control circuit 30 operates when power is supplied from the power supply circuit 35, and stops operating when the power supply is cut off. The voltage measuring unit 351 is connected to the positive pole side and the negative pole side of the dry battery 17. The voltage measuring unit 351 receives a control command from the control circuit 30, measures the output voltage of the dry battery 17, and inputs the measurement result as a measurement signal to the control circuit 30.

The operation unit and the display unit provided on the operation panel 23 are connected to the panel control circuit 37. The panel control circuit 37 detects the operation of the operation unit and inputs it to the control circuit 30. The panel control circuit 37 receives a control command from the control circuit 30 and displays a timer time or the like on the display unit.

The igniter circuit 41 receives a control command from the control circuit 30 and drives various stoves 4 to 6 of the stove 1 and an igniter 51 provided in the grill device. The thermistor circuit 42 inputs detection signals from the thermistors 52 of each of the various stoves 4 to 6 to the control circuit 20.

The misfire detection circuit 43 detects misfires of various stoves 4 to 6 and the grill device based on the thermoelectromotive force generated by the thermocouple 53, and inputs them to the control circuit 30. The safety valve circuit 44 receives a control command from the control circuit 30 and controls the energization of the safety valve 54. Safety valves 54 are provided in each of the various stoves 4 to 6 and four gas supply pipes (not shown) that supply gas to each of the grill devices. The safety valve 54 is a magnetic safety valve, and is mechanically opened by pushing the operation knobs 11 to 14, and the valve is opened. The safety valve circuit 44 receives a control command from the control circuit 30 and energizes the safety valve 54. The safety valve 54 maintains the valve open state. For example, if the burner misfires in the various stoves 4 to 6 and the grill device, the thermoelectromotive force generated in the thermocouple 53 is lost, so that the misfire detection circuit 43 inputs the misfire signal to the control circuit 30. The safety valve circuit 44 receives a control command from the control circuit 30 and shuts off the energization of the safety valve 54. As a result, the safety valve 54 is closed by the urging force of the spring (not shown).

The solenoid valve circuit 45 receives a control command from the control circuit 30 and opens and closes the solenoid valve 55 for adjusting the amount of gas. The solenoid valve 55 is a gas shutoff keep solenoid valve. The solenoid valve 55 is provided in a bypass pipe (not shown) that branches from the middle of the gas supply pipe and joins again. By opening and closing the solenoid valve 55, the flow path of the bypass pipe is opened and closed, and the amount of gas supplied to each of the various stoves 4 to 6 and the grill device is increased or decreased. As a result, the heating power of various stoves 4 to 6 and the grill device can be adjusted in two stages, high heating power and low heating power.

The display module 60 includes a display control circuit 61, a display unit 62, a display power supply circuit 65, a voltage measurement unit 651, a dry battery 18, and the like. The display control circuit 61 displays and updates the remaining battery level on the display unit 62 based on the control command from the control circuit 30. As described above, the display unit 62 is a well-known electronic paper, and the displayed contents can be held and electrically updated. The display power supply circuit 65 receives a control command from the control circuit 30 and supplies electric power supplied from the dry battery 18 housed in the second battery box to the display control circuit 61 and the display unit 62, respectively. The voltage measuring unit 651 is connected to the positive pole side and the negative pole side of the dry battery 18. The voltage measuring unit 651 receives a control command from the control circuit 30, measures the output voltage of the dry battery 18, and inputs the measurement result as a measurement signal to the control circuit 30.

The power supply switching unit 601 is provided in the middle of the wiring 600 connected between the power supply circuit 35 and the display control circuit 61 and the display unit 62. The power supply switching unit 601 includes a switching element (not shown) and is connected to the control circuit 30. The power switching unit 601 is turned on and off based on a control command from the control circuit 30. When the power switching unit 601 is turned on, power can be supplied from the power supply circuit 35 to the display control circuit 61 and the display unit 62. When the power switching unit 601 is turned off, the power supply from the power supply circuit 35 to the display control circuit 61 and the display unit 62 is cut off.

A mode of displaying the remaining battery level on the display unit 62 will be described with reference to FIGS. 3 and 4. As shown in FIG. 3A, the battery icon 80 is displayed on the display unit 62. The battery icon 80 includes a data bar 85, and the length of the data bar 85 displays the remaining battery level of the dry battery 17 in five stages (see FIGS. 4A to 4E). The data bar 85 extends in the left-right direction and is divided into four blocks. By displaying the contents in black according to the remaining battery level in the four blocks constituting the data bar 85, the remaining battery level can be displayed by the length of the data bar 85.

The battery icon 80 shown in FIG. 4A indicates that the remaining battery level is 80% or more, and “FULL” is displayed on the right side. The battery icon 80 shown in FIG. 4B indicates that the remaining battery level is 75% or more and less than 80%, and is displayed as “75%” on the right side. The battery icon 80 shown in FIG. 4B indicates that the remaining battery level is 75% or more and less than 80%, and is displayed as “75%” on the right side.

The battery icon 80 shown in FIG. 4C indicates that the remaining battery level is 50% or more and less than 75%, and is displayed as “50%” on the right side. The battery icon 80 shown in FIG. 4D indicates that the remaining battery level is 25% or more and less than 50%, and is displayed as “25%” on the right side. The battery icon 80 shown in FIG. 4 (E) indicates that the remaining battery level is less than 25%, and "LOW" is displayed on the right side.

As shown in FIG. 3B, when the remaining battery level is less than 25% and “LOW”, it is necessary to replace the dry battery 17 in the first battery box. The stove 1 displays a first battery caution mark 87 on the right side of the battery icon 80 on the display unit 62 in order to encourage the user to replace the battery in the first battery box. "1st battery" is displayed below the 1st battery caution mark 87. The "first battery" means a dry battery 17 for a stove. As a result, the stove 1 prompts the user to replace the battery of the first battery box (replacement of the dry battery 17).

For example, even if the remaining battery level is 50%, the remaining battery level of the second battery box of the display module 60 may decrease. In that case, in order to encourage the user to replace the battery of the second battery box, the stove 1 displays the second battery caution mark 88 on the right side of the battery icon 80 on the display unit 62 as shown in FIG. 3C. do. "Second battery" is displayed below the second battery caution mark 88. As a result, the stove 1 prompts the user to replace the battery of the second battery box (replacement of the dry battery 18).

The battery remaining amount display process will be described with reference to FIGS. 5 and 6. For example, when the user pushes the operation knob 11 for cooking on the right stove 4, the board switch 21 and the igniter switch 22 are turned on in this order. When the board switch 21 is turned on, the power supply circuit 35 supplies electric power to various circuits based on the signal from the switch input circuit 36. The CPU 31 of the control circuit 30 reads the battery remaining amount display program from the ROM 32 and executes this process. When the igniter switch 22 is turned on, the CPU 31 operates the igniter 51 based on the input signal from the switch input circuit 36, and the right stove 4 is ignited by the ignition electrode. The right stove 4 is in a burning state.

As shown in FIG. 5, the CPU 31 measures the voltage of the dry battery 17 for the stove by the voltage measuring unit 351 (S11). The CPU 31 calculates the remaining battery level of the dry battery 17 based on the measured voltage (S12), and stores the calculated remaining battery level in the RAM 33 (S13). The CPU 31 executes a display power supply confirmation process before displaying or updating the remaining battery level on the display unit 62 (S12).

As shown in FIG. 6, the CPU 31 measures the voltage of the dry battery 18 for display by the voltage measuring unit 651 (S21). The CPU 31 determines whether the measured voltage is equal to or higher than the threshold value (S22). The threshold value is preferably set to a voltage higher than the minimum voltage that can be driven by the display control circuit 61 and the display unit 62, but it may be set to the minimum voltage. When the measured voltage is equal to or higher than the threshold value (S22: YES), the CPU 31 determines whether or not the second battery caution mark 88 is being displayed on the display unit 62 (S23). When the second battery caution mark 88 is not displayed (S23: NO), the CPU 31 turns off the power switching unit 601 (S25), and the power supply source of the display control circuit 61 and the display unit 62 is set to the second battery box. Set to the dry battery 18. When the second battery caution mark 88 is displayed on the display unit 62 (S23: YES), the CPU 31 erases the second battery caution mark 88 (S24) and then turns off the power switching unit 601 (S25). ), The power supply source of the display control circuit 61 and the display unit 62 is set to the dry battery 18 of the second battery box.

When the measured voltage is less than the threshold value (S22: NO), the voltage of the dry cell 18 is low. If this state continues, there is a possibility that the display and update on the display unit 62 cannot be performed. Therefore, as shown in FIG. 3C, the CPU 31 displays the second battery caution mark 88 on the display unit 62 (S27), so that the user can replace the battery of the second battery box (dry battery 18). Exchange) is urged. Further, the CPU 31 determines whether the remaining battery level of the dry battery 17 for the stove stored in the RAM 33 is 25% or more (S28). When the remaining battery level is 25% or more (S28: YES), the CPU 31 turns on the power switching unit 601 (S29). This makes it possible to replenish and supply electric power from the power supply circuit 35 to the display control circuit 61 and the display unit 62. Therefore, the stove 1 can continuously display and update the display unit 62.

On the other hand, when the remaining battery level is less than 25% (S28: NO), the voltage of the dry battery 17 is low, so that if power is replenished from the power supply circuit 35, the battery life of the dry battery 17 may be affected. be. In this case, the CPU 31 turns off the power switching unit 601 (S25), and sets the power supply source of the display module 60 to the dry battery 18. The CPU 31 ends this process and proceeds to S15 in FIG.

As shown in FIG. 5, the CPU 31 displays or updates the battery icon 80 based on the remaining battery level of the dry battery 17 stored in the RAM 33 (S15). Specifically, the CPU 31 outputs a control signal to the display power supply circuit 65 when the power supply switching unit 601 is off. The display power supply circuit 65 supplies the electric power supplied from the dry battery 18 to the display control circuit 61 and the display unit 62, respectively, based on the control signal. When the power switching unit 601 is on, the CPU 31 supplies the power of the dry battery 17 supplied from the power supply circuit 35 to the display control circuit 61 and the display unit 62 via the wiring 600, respectively. The CPU 31 transmits a control signal including information on the remaining battery level of the dry battery 17 stored in the RAM 33 to the display control circuit 61. The display control circuit 61 displays or updates the battery icon 80 on the display unit 62 based on the control signal (S15).

For example, when the remaining battery level of the dry battery 17 for the stove is 52%, the CPU 31 displays the battery icon 80 shown in FIG. 4 (C). As a result, the stove 1 can notify the user that the remaining battery level is at least 50%. Since the battery icon 80 displays the remaining battery level by the length of the data bar 85, the user can intuitively recognize the remaining battery level. Further, since "50%" is displayed numerically on the right side of the data bar 85, the remaining battery level can be easily recognized. Further, since the display unit 62 is an electronic paper, the display of the battery icon 80 can be held without consuming electric power.

The CPU 31 determines whether the burning right stove 4 has been extinguished (S16). When the combustion is still in progress (S17: NO), the CPU 31 determines in S11 whether a predetermined time has elapsed from the time of measuring the voltage of the dry battery 17 (S17). If the predetermined time has not elapsed (S17: NO), the CPU 31 returns to S16 and monitors the extinguishing of the right stove 4. When a predetermined time has elapsed from the time of voltage measurement (S17: YES), the CPU 31 returns to S11, measures the voltage of the dry battery 17 again, and repeats the above process to change the battery icon 80 according to the change in the remaining battery level. Update the display regularly. When the right stove 4 is extinguished (S16: YES), the CPU 31 ends this process.

After the fire of the right stove 4 is extinguished, the power of the stove 1 is turned off, but the display unit 62 can hold the display content of the battery icon 80 that was last updated. Therefore, even if the power of the stove 1 is turned off, the battery is sent to the user. You can keep informing the remaining amount.

As described above, the stove 1 of the first embodiment is battery-powered. The stove 1 includes a display module 60. The display module 60 includes a display control circuit 61 and a display unit 62. The display unit 62 is composed of electronic paper that can hold the display contents and is electrically updatable, and can display various types of information. The display control circuit 61 displays and updates various information on the display unit 62. As a result, the stove 1 can continue to display the information without power consumption after displaying the information on the display unit 62. Therefore, the stove 1 can save power consumption.

Since the display unit 62 is provided on the front surface of the left panel unit 9 of the stove 1, the information displayed on the display unit 62 can be visually recognized at a position easily visible to the user.

The stove 1 includes a voltage measuring unit 351 that measures the voltage of the dry battery 17, and displays the remaining battery level calculated based on the voltage measured by the voltage measuring unit 351 on the display unit 62. As a result, the stove 1 can display the remaining battery level of the dry battery 17 on the display unit 62 with low power consumption. Further, since the stove 1 can hold the last displayed or updated display of the remaining battery level on the display unit 62 even when the power is off, it is possible to prevent the timing of prompting the user to replace the battery to be delayed.

Since the stove 1 displays the remaining battery level stepwise by the data bar 85 of the battery icon 80 and the numerical value, the user can intuitively and easily recognize the remaining battery level.

Since the stove 1 can supply electric power to the display unit 62 and the display control circuit 61 from the display power supply circuit 65, which is different from the power supply circuit 35, it is possible to prevent the stove 1 from affecting the battery life of the dry battery 17. As a result, various information can be displayed on the display unit 62 without consuming the electric power from the dry battery 17.

The stove 1 includes a voltage measuring unit 651 that measures the voltage of the dry battery 18 for display. The stove 1 determines whether the voltage measured by the voltage measuring unit 651 is less than the threshold value. When it is determined that the value is less than the threshold value, electric power is supplied from the power supply circuit 35 to the display control circuit 61 and the display unit 62 to replenish the power. As a result, the stove 1 can supply electric power from the power supply circuit 35 when the voltage of the display dry battery 18 drops, so that the display on the display unit 62 can be continued.

In the above description, the CPU 31 that executes the process of S15 in FIG. 5 is an example of the "display control unit" and the "remaining amount display unit" of the present invention. The front surface of the left panel portion 9 is an example of the "front surface of the stove" of the present invention of the present invention. The voltage measuring unit 351 is an example of the "voltage measuring unit" of the present invention. The CPU 31 that executes the process of S12 in FIG. 5 is an example of the "remaining amount calculation unit" of the present invention. The control circuit 30, switch input circuit 36, panel control circuit 37, igniter circuit 41, thermistor circuit 42, misfire detection circuit 43, safety valve circuit 44, and solenoid valve circuit 45 are examples of the "drive unit" of the present invention. The power supply circuit 35 is an example of the “power supply unit” of the present invention. The display power supply circuit 65 is an example of the “display power supply unit” of the present invention. The voltage measuring unit 651 is an example of the "display voltage measuring unit" of the present invention. The CPU 31 that executes the process of S22 in FIG. 6 is an example of the "determination unit" of the present invention. The wiring 600 and the power switching unit 601 are examples of the "supplementary power supply unit" of the present invention.

The stove 100 of the second embodiment will be described with reference to FIGS. 7 and 8. The stove 100 is a partially modified version of the configuration of the stove 1 of the first embodiment. Therefore, in the second embodiment, the parts common to the first embodiment are designated by the same reference numerals as those in the first embodiment, and the description thereof will be omitted or simplified, and the different parts will be mainly described. The stove 100 is also the same built-in stove as the stove 1.

As shown in FIG. 7, the stove 100 includes a display module 70 instead of the display module 60 (see FIG. 2) of the first embodiment. As described above, in the first embodiment, the CPU 31 of the stove 1 controls the display of the remaining battery level on the display unit 62. In the second embodiment, the CPU 75 of the display module 70 controls the display of the remaining battery level on the display unit 62. The display module 70 is an option of the stove 100 and is incorporated later.

As shown in FIG. 7, the display module 70 of the stove 100 includes a display power supply circuit 71, a display control circuit 72, a display unit 62, a voltage measuring unit 651, a dry battery 18, and the like. The display unit 62, the voltage measuring unit 651, and the dry battery 18 are the same as those in the first embodiment. The display power supply circuit 71 supplies the electric power supplied from the dry battery 18 housed in the second battery box to the display control circuit 72 and the display unit 62, respectively. A wiring 600 extending from the power supply circuit 35 is connected to the display power supply circuit 71. The wiring 600 is not provided with the power switching unit 601 (see FIG. 2) of the first embodiment. The display power supply circuit 71 is provided with a power supply switching unit 711. The power switching unit 711 receives a control command from the display control circuit 72, which will be described later, and supplies power to the display control circuit 72 and the display unit 62 from the dry battery 18 to the dry battery 17 or from the dry battery 17 to the dry battery 18. It is switchable.

The display control circuit 72 displays and updates the remaining battery level on the display unit 62. The display control circuit 72 includes a CPU 75, a ROM 76, a RAM 77, a flash memory 78, and the like. The CPU 75 controls the operation of the display module 70 in an integrated manner. The ROM 76 stores various programs including a battery level display program. The battery remaining amount display program is a program for executing the same battery remaining amount display process (see FIG. 8) as in the first embodiment. The RAM 77 temporarily stores various information. The flash memory 78 is non-volatile and stores various data. The display control circuit 72 can communicate with the control circuit 30 of the stove 1.

The battery remaining amount display process will be described with reference to FIG. The CPU 75 of the display control circuit 72 periodically reads the battery remaining amount display program from the ROM 76 and executes this process. Since the display power supply confirmation process of S34 is the same process as the display power supply confirmation process of the first embodiment shown in FIG. 6, a part of the description will be omitted with reference to FIG.

As shown in FIG. 8, the CPU 75 acquires the voltage of the dry battery 17 for the stove (S31). In the method of acquiring the dry battery 17, the CPU 75 may transmit, for example, a request signal requesting voltage measurement of the dry battery 17 to the control circuit 30 of the stove 100. Upon receiving the request signal, the CPU 31 of the control circuit 30 measures the voltage of the dry battery 17 by the voltage measuring unit 351 and returns the measured voltage value as a response signal to the display control circuit 72 of the display module 70. The CPU 75 can acquire the voltage of the dry battery 17 by receiving the response signal. If the response signal is not received within a predetermined time after the request signal is transmitted, an error may be displayed on the display unit 62 as an error. In addition to the above acquisition method, for example, the CPU 75 may measure and acquire the voltage of the dry battery 17 based on the electric power supplied to the display power supply circuit 71 through the wiring 600.

The CPU 75 calculates the remaining battery level of the dry battery 17 based on the acquired voltage (S32), and stores the calculated remaining battery level in the RAM 77 (S33). The CPU 75 executes a display power supply confirmation process (see FIG. 6) (S34).

As shown in FIG. 6, the CPU 75 measures the voltage of the dry battery 18 for display (S21), and if the measured voltage is equal to or higher than the threshold value (S22: YES), the CPU 75 turns off the power switching unit 711 (S25). As a result, the display module 70 switches the power supply source of the display control circuit 72 and the display unit 62 to the dry battery 18 of the second battery box. If the measured voltage is less than the threshold value and the remaining amount of the dry battery 17 for the stove is 25% or more (S22: NO, S28: YES), the CPU 75 turns on the power switching unit 711 (S29). As a result, the display module 70 switches the power supply source of the display control circuit 72 and the display unit 62 to the dry battery 17 of the first battery box. In this way, the CPU 75 ends the main process and proceeds to the process in S35 of FIG. The CPU 31 displays or updates the battery icon 80 based on the remaining battery level of the dry battery 17 stored in the RAM 77 (S35), and ends this process. By periodically and repeatedly executing this process, the CPU 75 can update the battery icon 80 according to the change in the remaining battery level.

As described above, the stove 100 of the second embodiment can continue to display the information without power consumption after displaying the information on the display unit 62, as in the first embodiment, so that the power consumption can be saved. Further, in the second embodiment, in particular, since the display module 70 controls the display of the remaining battery level in the display unit 62, even if the voltage of the dry battery 17 for the stove drops, the battery remaining amount in the display unit 62 The quantity can be continuously displayed and updated.

The present invention is not limited to the first and second embodiments described above, and various modifications can be made. The stoves 1 and 100 are built-in stoves, but they may be table stoves. The stoves 1 and 100 are provided with a grill device in the housing 2, but may be a stove without a grill device.

The display unit 62 of the above embodiment is an electronic paper and can display the battery icon 80, the data bar 85, the first battery caution mark 87, and the second battery caution mark 88, but the remaining battery level can be displayed in other display modes. Etc. may be displayed.

Further, in the above embodiment, the remaining battery level is displayed stepwise by the data bar 85 and the numerical value, but for example, only the data bar 85 or only the numerical value may be displayed. Further, various information other than the remaining battery level may be displayed on the display unit 62. Information to be displayed on the display unit of the operation panel 23 may be displayed on the display unit 62.

Further, although the data bar 85 is composed of four blocks, the number of blocks may be other than this, and the length of one data bar may be changed stepwise according to the remaining battery level. Further, the data bar 85 extends in the left-right direction, but the extending direction may be other than this. Further, instead of the linear shape as in the data bar 85, for example, a ring shape may be used, and the shape may be changed according to the remaining battery level.

The shape and size of the display unit 62 are not limited to the above embodiment. Further, the display unit 62 is provided on the front surface of the upper panel 91 of the left panel unit 9, but the position of the display unit 62 may be other than this, for example, the front surface of the lower panel 92 of the left panel unit 9 and the right panel unit 8. It may be provided on the front surface of the upper panel 81, the front surface of the lower panel 82, or the like. Further, as in the stove 200 shown in FIG. 9, a display unit 162 which is an electronic paper may be provided at the center portion in the left-right direction on the front side of the top plate 3.

In the above embodiment, one display unit 62 is provided on the upper panel 91 of the left panel unit 9, but the number of display units may be plural. For example, one may be provided on the upper panel 91 of the left panel portion 9 (see the display unit 62 shown in FIG. 1), and one may be provided on the upper surface of the top plate 3 (see the display unit 162 shown in FIG. 9).

In the above embodiment, in order to drive the display control circuit 61 and the display unit 62, the display module 60 that can use the electric power supplied from the display dry battery 18 instead of the existing dry battery 17 for the stove is provided. The configuration may be such that only the dry battery 17 for the stove is used. In that case, it is preferable that the display and update can be performed on the display unit 62 even if the voltage is lower than the minimum voltage required for the operation of the stove 1.

1 stove 3 top plate 9 left panel 17 dry cell 18 dry cell 31 CPU
60 Display module 61 Display control circuit 62 Display unit 65 Display power supply circuit 85 Data bar 91 Upper panel 100 Conro 162 Display unit 351 Voltage measurement unit 600 Wiring 601 Power supply switching unit 651 Voltage measurement unit

Claims (9)

It ’s a battery-powered stove.
A display unit that can display various information and is composed of electronic paper that can hold the display contents and can be electrically updated.
A stove including a display control unit for displaying and updating various information in the display unit. The stove according to claim 1, wherein the display unit is provided on the front surface of the stove. The stove according to claim 1 or 2, wherein the display unit is provided on the top plate of the stove. A voltage measuring unit that measures the voltage of dry batteries,
It is provided with a remaining amount calculation unit that calculates the remaining battery level based on the voltage measured by the voltage measuring unit.
The display control unit
The stove according to any one of claims 1 to 3, further comprising a remaining amount display unit that displays the remaining battery level calculated by the remaining amount calculation unit on the display unit. The remaining amount display unit is
The stove according to claim 4, wherein the remaining battery level is displayed stepwise by the length of the data bar corresponding to the remaining battery level. The stove according to claim 4 or 5, wherein the remaining amount display unit displays the remaining amount of the battery stepwise by a numerical value. The drive unit that operates the stove and
It is equipped with a power supply unit that supplies electric power from the dry battery to the drive unit.
The stove according to any one of claims 1 to 6, wherein the display control unit receives the power supply from the power supply unit. The drive unit that operates the stove and
A power supply unit that supplies power from the dry battery to the drive unit,
13. The stove described in any one. A display voltage measuring unit that measures the voltage of the display dry cell,
A determination unit for determining whether the voltage measured by the display voltage measurement unit is less than the threshold value, and a determination unit.
8. The eighth aspect of the present invention includes a supplementary power supply unit for supplying the power from the power supply unit to the display control unit and the display unit when the determination unit determines that the voltage is less than the threshold value. The described stove.

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