JP3509752B2 - Electric hot water storage container - Google Patents

Description

Detailed Description of the Invention

[0002]

TECHNICAL FIELD OF THE INVENTION

The present invention relates to an electric hot water storage container, and more particularly to an electric hot water storage container having a function of displaying a remaining heat retention time until reaching a preset heat retention temperature.

[Prior art]

An electric hot water storage container having an inner container for boiling water, a heating means for heating the inner container, and a temperature detecting means for detecting the temperature of the inner container is well known in the art.

In this kind of electric hot water storage container, the remaining time from the start of boiling to the boiling (that is, remaining boiling time)
It has been proposed to improve the convenience of the user by providing a function of displaying (see, for example, Japanese Utility Model Laid-Open No. 2-90729).

[Problems to be Solved by the Invention]

[0006] By the way, as a mode of use of the electric hot water storage container, in addition to the case where hot water is supplied immediately after boiling, hot water is supplied after it is once boiled and waits for the temperature to drop to a desired heat retention temperature (for example, Sencha). In some cases, such as when adding or preparing milk). In the latter case, the remaining boiling time display alone is not sufficient, and there is a user request to know how long it takes from the start of heating to the desired set heat retention temperature through boiling.

The present invention has been made in view of the above points, and it is possible to improve the convenience for the user by displaying the remaining heat retention reaching time from the start of boiling water to the preset heat retention temperature through boiling. It is intended.

[Means for Solving the Problems]

In the invention of claim 1, as means for solving the above problems, an inner container for boiling water, a heating means for heating the inner container, and a temperature detecting means for detecting the temperature of the inner container, In an electric hot water storage container provided with a heat retention temperature setting means for setting a plurality of heat retention temperatures, the remaining boiling time from the start of boiling water by the heating means to the boiling and the boiling
Obtained by adding the insulation remaining time to reach the set retained temperature set by said retained temperature setting means later Teng
That a remaining time calculating means for calculating a heat insulating arrival remaining time, as well as attached to the remaining time display means for displaying on the display device warmth arrival remaining time obtained by said residue time calculation means, wherein
The remaining heat retention time is the temperature detected by the temperature detection means.
The correction is made according to the descent rate and the hot water temperature at that time .

With the above configuration, the remaining heat retention time from the start of boiling to the set heat retention temperature after boiling is calculated by the remaining time calculation means, and the remaining heat retention time thus obtained is calculated as the remaining time. It is displayed on the display device by the display means. Therefore, the user can recognize how long it takes to obtain hot water having a desired preset heat retention temperature after starting boiling, which is extremely convenient. Also, boiling from the start of boiling water to the boiling
Remaining time and holding after boiling until reaching the set heat retention temperature
Calculate the remaining heat retention time by calculating the remaining temperature
Therefore, the arithmetic processing becomes simple.
Also, only the information from the temperature detection means, which is an existing component,
Since it is possible to calculate the remaining heat retention time, low cost
It is possible to perform calculation processing on the computer.

As in the invention of claim 2 , claim 1
In the electric hot water storage container described, when the display switching means for selectively displaying the remaining boiling time and the remaining heat retention time on the display device is attached, the remaining boiling time and the remaining heat retention are achieved by the user operating the display switching means. The remaining time can be selectively displayed on the display device, and the user's request can be reflected.

DETAILED DESCRIPTION OF THE INVENTION

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

First Embodiment FIGS. 1 to 4 show an electric hot water storage container according to a first embodiment of the present invention.

This electric hot water storage container comprises a container body 1 having an inner container 3 for storing hot water, and a lid 2 for opening and closing the container body 1.
An electric heater 4 which is a heating means for heating the inner container 3, a pouring passage 5 for pouring the hot water in the inner container 3 to the outside, and the hot water is sent out through the pouring passage 5. And a pump device 6.

The container body 1 has an outer case 7 made of a synthetic resin forming an outer surface and an inner container 3 forming an inner peripheral surface.
And an annular shoulder member 8 for connecting the outer case 7 and the inner container 3 and a bottom plate 9 made of synthetic resin and forming a bottom surface.

The inner container 3 is made of stainless steel and has a bottomed cylindrical inner cylinder 10 and a stainless steel substantially cylindrical outer cylinder 11.
And a non-vacuum part 3a consisting of only the bottom part of the inner cylinder 10 is formed at the bottom part. The non-vacuum portion 3a
The electric heater 4 (for example, a mica heater in which a heating element is held by a mica plate) is attached to the lower surface of the. In the case of the present embodiment, the inner cylinder 10 of the inner container 3 has a wide-mouthed cylindrical shape having the same upper and lower inner diameters. Therefore, the amount of heat radiated from the upper opening 3a of the inner container 3 is slightly larger than that of a narrow mouth shape in which the upper opening 3a of the inner container 3 is narrowed. Reference numeral 13 is a temperature sensor which functions as a temperature detecting means for detecting the temperature of the inner container 3 (in other words, the hot water temperature Tw).

The lid 2 is composed of an upper plate 14 made of synthetic resin and a lower plate 15 made of synthetic resin whose outer peripheral edge is fitted and joined to the upper plate 14, and the shoulder member 8 is provided. Hinge pin 1 for hinge receiver 16 provided at the rear part of
It is supported via 7 to be openable / closable and detachable. Reference numeral 18 is a steam discharge passage.

A metal cover member 19 is fixed to the lower plate 15 of the lid body 2, and the cover member 19 is fixed.
A seal packing 21 that is pressed against the water supply port 20 of the inner container 3 when the lid 2 is closed is provided on the outer peripheral edge of the.

In FIG. 1, reference numeral 22 is an operation panel provided with various switches described later, and 23 is a control board.
The control board 23 is provided with a room temperature sensor 38 acting as a room temperature detecting means for detecting the room temperature Tr.

As shown in FIG. 2, the operation panel 22 includes a hot water supply switch 24, a lock release switch 25, a reboil switch 26, a heat retention selection switch 27, a selection switch 28 for setting the amount of hot water at the time of constant hot water supply, and a liquid crystal display. Display device 2
9, a reboil indicator light 30 and a heat retention indicator light 31 are provided. The liquid crystal display device 29 displays the temperature, the remaining time, and the amount of water alternately in seven segments, and also has a triangular indicator light 32 for displaying the set heat retention temperature (98 ° C, 90 ° C, 70 ° C, mahobin). ~ 35 are provided.

FIG. 3 is a block diagram showing a configuration of a main part of the control board 23. A microcomputer unit (hereinafter abbreviated as a microcomputer) 36 has a processing unit CPU, a memory RAM, a program memory ROM, It incorporates an input port A / D having an analog / digital conversion function, an output port for outputting a control output signal, and the like. The output from the temperature sensor 13 is input to the analog / digital conversion input port A / D of the microcomputer 36. The microcomputer 36 performs an interrupt process when an interrupt signal is input to the interrupt signal input terminal INT.

Reference numeral 37 is a timer circuit, which sends out a timer signal at every predetermined time and gives a timer interrupt signal to an interrupt signal input terminal INT of the microcomputer 36. In the microcomputer 36, when the timer interrupt signal is received, the temperature sensor 13
The output signal of is taken, converted into temperature data, and sequentially stored in the internal memory.

The microcomputer 36 has a function as a remaining time calculating means for calculating the remaining heat retention reaching time tn from the start of boiling water by the electric heater 4 to the set heat retention temperature Ts after boiling, and the remaining time calculation means. The function as a remaining time display means for displaying on the liquid crystal display device 29 the remaining heat retention time tn obtained by the above, and the remaining heat retention time tn calculated by the remaining time calculation means is corrected corresponding to the change of the room temperature Tr. It also has a function as a room temperature correcting means.

Reference numeral 39 is a relay, and 40 is a commercial AC power supply. The relay 39 is output by the output from the microcomputer 36.
By controlling the heating power applied to the electric heater 4 from the commercial AC power supply 40.

Next, the remaining time display control in the electric hot water storage container having the above configuration will be described with reference to the flowchart shown in FIG.

When boiling water by the electric heater 4 is started, temperature information from the temperature sensor 13 and the room temperature sensor 24 (that is, the hot water temperature Tw and the room temperature T is obtained in step S1).
r) is input to the microcomputer 36. And step S
In 2, the remaining boiling time tm until boiling is displayed on the liquid crystal display device 29, and in step S3, the boiling water control by the energization control to the electric heater 4 is executed. The boiling remaining time tm will be described in detail later, but the temperature sensor 1
It is calculated based on the time C required for the detected temperature Tw of 3 to rise by a predetermined temperature.

When it is confirmed that the hot water temperature Tw has reached 95 ° C. in step S4, the hot water temperature increase rate ΔTw = dTw / dt (that is, the line segment L ₁ in the time chart of FIG. The gradient) is calculated, and in step S6, the hot water amount W is calculated based on the hot water temperature increase rate ΔTw = dTw / dt. The hot water amount calculation is performed by determining the hot water amount W based on the magnitude of the hot water temperature increase rate ΔTw = dTw / dt. For example, a map is created in which the measured hot water temperature increase rate ΔTw and the remaining boiling time tm are associated with each other, and the actually measured hot water amount increase rate ΔTw = dTw / d.
The remaining boiling time tm corresponding to t may be read from the map.

When it is confirmed in step S7 that the boiling has ended, the preset heat retention temperature Ts is read from the microcomputer 36 in step S8, and the hot water amount W (calculated in step S6 is calculated in step S9. From the amount of hot water) and the room temperature Tr, the remaining heat retention time tn after boiling until reaching the preset temperature retention temperature Ts is calculated, and the remaining heat retention time tn is displayed on the liquid crystal display device 29 in step S10. For example, hot water amount W and room temperature T
A map is created in which r is associated with the remaining heat retention time tn, and the remaining heat retention time tn corresponding to the hot water amount W and the room temperature Tr is read from the map.

Next, in step S11, the remaining heat retention time tn is subtracted in steps of 1 minute, and in step S12 the hot water temperature drop rate -ΔTw = -dTw / dt is calculated.
In step S13, the remaining heat retention time tn obtained in step S9 is corrected from the hot water temperature decrease rate −ΔTw and the hot water temperature Tw at that time.

That is, the heat retention remaining time tn obtained by tn = (Ts-Tw) /-ΔTw is displayed again on the liquid crystal display device 29.

When it is confirmed in step S14 that the detected hot water temperature Tw has reached the set heat retention temperature Ts, the liquid crystal display device 29 displays the remaining heat retention time t in step S15.
It is displayed as n = 0, and in step S16, a heat retention arrival notification is given by a buzzer or the like.

As described above, in the present embodiment, the remaining boiling time t from the start of boiling water to the start of boiling
m and the remaining heat retention time tn after boiling until reaching the preset heat retention temperature Ts are calculated by the remaining time calculation means, and the boiling remaining time tm and the remaining heat retention time tn thus obtained are displayed on the liquid crystal display device 29 by the remaining time display means. Will be displayed. Therefore, the user can recognize how long it takes to obtain hot water having a desired preset heat retention temperature after starting boiling, which is extremely convenient.

The calculation and display of the remaining boiling time tm are performed as follows (see the flowchart of FIG. 6).

When hot water boiling by the electric heater 4 is started, temperature information (that is, the detected hot water temperature Tw) from the temperature sensor 13 is input to the microcomputer 36 in step S1. Then, in steps S2, S4 and S6, the detected hot water temperature Tw and the predetermined temperatures Tn, Tn + 1.
And Tn + 2. Where Tn, T
The temperature of n + 1, Tn + 2 ... Is increased by 5 ° C., for example. For example, Tn = 50 ° C., Tn + 1 = 55
C, Tn + 2 = 60 ° C ....

When it is determined that Tw = Tn in step S2, counting of the temperature rising time Cn after reaching the temperature Tn is started in step S3, and step S4
It continues until it is determined that T = Tn + 1 in.

When it is determined that Tw = Tn + 1 in step S4, counting of the temperature rise time Cn + 1 after reaching the temperature Tn + 1 is started in step S5,
It is continued until it is determined that Tw = Tn + 2 in step S6.

When Tw = Tn + 2 is determined in step S6, the temperature raising times Cn and Cn are determined in step S7.
+1 is compared, and if it is determined here that Cn = Cn + 1, the process proceeds to step S10, the remaining boiling time tm is calculated, and the remaining boiling time tm is displayed in step S11, but it is determined that Cn ≠ Cn + 1. Then, the process proceeds to step S8, and it is determined whether or not the detected hot water temperature Tw has reached 100 ° C. If it is determined that Tw = 100 ° C., the control ends. When a negative determination is made in step S8, n → n + 1 is replaced in step S9, the process returns to step S5, and the following control is repeated.
That is, the calculation of the remaining boiling time tm is started at the time when the temperature rising times of the two times coincide. The reason for doing this is that if water is added, the temperature rise will not be stable and will cause an erroneous determination.

The remaining boiling time tm in step S10 is calculated by the following equation.

Tm = Cn + 1 (100-Tn + 1) / 5
+ A Here, A is a boiling maintenance time.

As described above, when the remaining boiling time tm is calculated on the basis of the time C required for the hot water temperature Tw detected by the temperature sensor 13 to rise to a predetermined temperature, the temperature sensor 13 which is an existing component is used. The remaining boiling time tm can be calculated using only the information of (1), and the calculation processing can be performed at low cost.

Second Embodiment FIGS. 7 to 9 are vertical sectional views of an electric hot water storage container according to a second embodiment of the present invention, and show the construction of a main part of a control board in the electric hot water storage container. A block diagram and a flowchart of displaying the remaining heat retention time are shown.

In this case, as shown in FIG. 7, the water supply port 20 in the upper part of the inner container 3 has a narrow mouth shape by squeezing the inner cylinder 10. In this way, the water supply port 2 of the inner container 3
The heat radiation from 0 is suppressed, and the heat retention performance is improved. Further, in this case, a water sensor 41 of an optical sensor type is attached to the pouring passage 5. The output from the water amount sensor 41 (that is, the detected hot water amount W) is input to the microcomputer 36 as shown in FIG.
Other configurations are the same as those in the first embodiment, and thus the description thereof will be omitted.

The remaining time display control in the electric hot water storage container configured as described above will be described with reference to the flowchart shown in FIG.

When boiling water by the electric heater 4 is started, information from the temperature sensor 13, the room temperature sensor 24, and the water amount sensor 41 (that is, the water temperature Tw, the room temperature Tr, and the water amount W) is input to the microcomputer 36 in step S1. It Then, in step S2, the remaining boiling time tm up to boiling is displayed on the liquid crystal display device 29, and in step S3, boiling water control is performed by controlling the energization of the electric heater 4. As in the first embodiment, the remaining boiling time tm is calculated based on the time C required for the temperature Tw detected by the temperature sensor 13 to rise by a predetermined temperature (see the flowchart in FIG. 6). Alternatively, the remaining boiling time tm can be calculated from the data on the map obtained from the hot water amount W, the room temperature Tr, and the hot water temperature Tw.

When it is confirmed in step S4 that the boiling has ended, the preset heat retention temperature Ts is read from the microcomputer 36 in step S5, and the temperature sensor 13 and the room temperature sensor 24 are read in step S6.
And information from the water amount sensor 41 (that is, the hot water temperature Tw,
The room temperature Tr and the hot water amount W) are input to the microcomputer 36, and in step S7, the remaining heat retention time tn from the boiling water amount W and the room temperature Tr until the temperature reaches the set heat retention temperature Ts in the same manner as in the first embodiment. Is calculated, and the remaining heat retention time tn is displayed on the liquid crystal display device 29 in step S8.

Next, in step S9, the heat retention remaining time tn is subtracted in steps of 1 minute, the hot water temperature decrease rate -ΔTw = -dTw / dt is calculated in step S10, and the heat retention remaining time tn (in step S6 is calculated in step S11. The calculated remaining heat retention time) is the hot water temperature drop rate-ΔT
It is corrected from w and the hot water temperature Tw at that time.

That is, the heat retention remaining time tn obtained by tn = (Ts-Tw) /-ΔTw is displayed again on the liquid crystal display device 29.

When it is confirmed in step S12 that the detected hot water temperature Tw has reached the set heat retention temperature Ts, the remaining heat retention time t is displayed on the liquid crystal display device 29 in step S13.
It is displayed as n = 0, and in step S14, the heat retention arrival notification is given by a buzzer or the like.

As described above, in the present embodiment, the remaining boiling time t from the start of boiling water to the start of boiling
m and the remaining heat retention time tn after boiling until reaching the preset heat retention temperature Ts are calculated by the remaining time calculation means, and the boiling remaining time tm and the remaining heat retention time tn thus obtained are displayed on the liquid crystal display device 29 by the remaining time display means. Will be displayed. Therefore, the user can recognize how long it takes to obtain hot water having a desired preset heat retention temperature after starting boiling, which is extremely convenient.

In this case, a water amount sensor 41 for detecting the amount of water in the inner container 3 is additionally provided, and the remaining boiling time tm and the remaining heat retention time tn are calculated based on the detected hot water temperature Tw and the detected hot water amount W. Therefore, the remaining boiling time and the remaining heat retention time can be calculated using only the information from the temperature sensor 13 and the water amount sensor 41, which are existing components, and the calculation processing can be performed at low cost.

Third Embodiment FIG. 10 to FIG. 12 are front views of an operation panel in an electric hot water container according to a third embodiment of the present invention, a block diagram showing the configuration of a main part of a control board, and FIG. A flowchart for displaying the remaining heat retention time is shown.

In this case, as shown in FIG. 10, in addition to the switches 24 to 28 in the first embodiment, the mode switch 4 is provided on the operation panel 22 in the electric hot water storage container.
2 is additionally attached. As will be described in detail later, the mode switch 42 changes the remaining time display from the boiling remaining time tm display to the heat retention remaining time ta by the signal input from the mode switch 42 (see FIG. 11). =
It is operated to switch to the display of tm + tn. Here, tn is the heat retention remaining time from boiling to the set heat retention temperature Ts. The mode switch 42
Is to be turned on during an odd number of pressing operations and turned off during an even number of pressing operations. Also in this case,
On the liquid crystal display device 29, "until boiling" when the remaining boiling time tm is selectively displayed by operating the mode switch 42
And "up to the set temperature" are displayed when the heat retention remaining time ta is selectively displayed. Other configurations are the same as those in the first embodiment, and thus the description thereof will be omitted.

The remaining time display control in the electric hot water storage container configured as described above will be described with reference to the flowchart shown in FIG.

When boiling water by the electric heater 4 is started, temperature information from the temperature sensor 13 and the room temperature sensor 24 (that is, the hot water temperature Tw and the room temperature T is obtained in step S1).
r) is input to the microcomputer 36. And step S
In 2, the remaining boiling time tm until boiling is displayed on the liquid crystal display device 29, and in step S3, the boiling water control by the energization control to the electric heater 4 is executed. As in the first embodiment, the remaining boiling time tm is calculated based on the time C required for the temperature Tw detected by the temperature sensor 13 to rise by a predetermined temperature (see the flowchart in FIG. 6).

When it is confirmed in step S4 that the hot water temperature Tw has reached 95 ° C., the hot water temperature increase rate ΔTw = dTw / dt (that is, the line segment L ₁ in the time chart of FIG. The gradient) is calculated, and in step S6, the hot water amount W is calculated based on the hot water temperature increase rate ΔTw = dTw / dt. The hot water amount calculation is performed by determining the hot water amount W based on the magnitude of the hot water temperature increase rate ΔTw = dTw / dt. For example, a map is created in which the measured hot water temperature increase rate ΔTw and the remaining boiling time tm are associated with each other, and the actually measured hot water temperature increase rate ΔTw = dTw / d.
The remaining boiling time tm corresponding to t may be read from the map.

Next, in step S7, it is determined whether or not the boiling has ended. If a negative determination is made (in other words, during boiling), the process proceeds to step S8 and the mode switch 42 is turned on. Whether or not it is determined. Here, when a negative determination is made, step S2
Returning to, the remaining boiling time tm is displayed on the liquid crystal display device 29, but if an affirmative decision is made, the operation proceeds to step S9,
The preset heat retention temperature Ts is read out from the microcomputer 36, and is set after boiling from the amount W of hot water (the amount of hot water calculated in step S6) and the room temperature Tr in step S10 as in the first embodiment. The remaining heat retention time tn until reaching the heat retention temperature Ts is calculated.

Thereafter, in step S11, the remaining heat retention reaching time ta = tm + tn from the start of boiling to the set warming temperature Ts is calculated, and this remaining heat retention remaining time ta is displayed in the liquid crystal display device 29 in step S12. After that, the process returns to step S3.

On the other hand, if an affirmative decision is made in step S7, the preset heat retention temperature Ts is read from the microcomputer 36 in step S13, and in step S14 the temperature information from the temperature sensor 13 and the room temperature sensor 24 ( That is, the hot water temperature Tw and the room temperature Tr) are input to the microcomputer 36, and the hot water amount W is calculated in step S15.
From the (amount of hot water calculated in step S6) and the room temperature Tr, the remaining heat retention time tn after boiling until reaching the preset temperature retention temperature Ts is calculated as described above, and the remaining heat retention time tn is displayed on the liquid crystal display in step S16. It is displayed on the device 29.

Next, in step S17, the remaining heat retention time tn is subtracted in steps of 1 minute, and in step S18 the hot water temperature drop rate -ΔTw = -dTw / dt is calculated.
In step S19, the remaining heat retention time tn obtained in step S14 is corrected from the hot water temperature drop rate -ΔTw and the hot water temperature Tw at that time.

That is, the heat retention remaining time tn obtained by tn = (Ts-Tw) /-ΔTw is displayed again on the liquid crystal display device 29.

When it is confirmed in step S20 that the detected hot water temperature Tw has reached the set heat retention temperature Ts, the remaining heat retention time t is displayed on the liquid crystal display device 29 in step S21.
It is displayed as n = 0, and in step S22 a heat retention arrival notification is given by a buzzer or the like.

As described above, in the present embodiment, the remaining boiling time t from the start of boiling water to the start of boiling
m, the heat retention remaining time tn after boiling until reaching the set heat retention temperature Ts, and the heat retention remaining time ta = tm + tn between the start of boiling water and the boiling until reaching the set heat retention temperature Ts are calculated by the residual time calculation means, and thus obtained The remaining boiling time tm, the remaining heat retention time tn, and the remaining heat retention time ta
= Tm + tn is the liquid crystal display device 29 by the remaining time display means.
Will be displayed in. Therefore, the user can recognize how long it takes to obtain hot water having a desired preset heat retention temperature after starting boiling, which is extremely convenient.

Fourth Embodiment FIGS. 13 and 14 are a block diagram showing the construction of a main part of a control board in an electric hot water container according to a fourth embodiment of the present invention and a heat retention remaining time display. A flow chart is shown.

In this case, as in the second embodiment, the water supply port 20 in the upper part of the inner container 3 has a narrow mouth shape by squeezing the inner cylinder 10. By doing so, heat radiation from the water supply port 20 of the inner container 3 is suppressed, and the heat retention performance is improved. In addition, in this case, the pouring passage 5
An optical sensor type water amount sensor 41 is attached to the unit (see FIG. 7). As shown in FIG. 13, the output from the water amount sensor 41 (that is, the detected hot water amount W) is determined by the microcomputer 3
6 is to be input. In addition to the switches 24 to 28 of the first embodiment, the mode switch 4 is provided on the operation panel 22 of the electric hot water storage container.
2 is additionally attached (see FIG. 10). The mode switch 42 is connected to the mode switch 4 as described later in detail.
A signal input from 2 (see FIG. 11) is used to switch the remaining time display on the liquid crystal display device 29 from the display of the remaining boiling time tm to the display of the remaining heat retention time ta = tm + tn. Here, tn is the heat retention remaining time from boiling to the set heat retention temperature Ts. Note that the mode switch 42 is turned on when the odd-numbered pressing operation is performed and turned off when the even-numbered pressing operation is performed. Further, in this case, on the liquid crystal display device 29, "until boiling" when the remaining boiling time tm is selected and displayed by operating the mode switch 42, and "up to the set temperature" when the remaining warming reaching time ta is selectively displayed. Is displayed. Other configurations are the same as those in the first embodiment, and thus the description thereof will be omitted.

The remaining time display control in the electric hot water storage container configured as described above will be described with reference to the flowchart shown in FIG.

When boiling water by the electric heater 4 is started, information (that is, hot water temperature Tw, room temperature Tr, hot water amount W) from the temperature sensor 13, the room temperature sensor 24 and the water amount sensor 41 is input to the microcomputer 36 in step S1. It Then, in step S2, the remaining boiling time tm up to boiling is displayed on the liquid crystal display device 29, and in step S3, boiling water control is performed by controlling the energization of the electric heater 4. As in the first embodiment, the remaining boiling time tm is calculated based on the time C required for the temperature Tw detected by the temperature sensor 13 to rise by a predetermined temperature (see the flowchart in FIG. 6).

Next, in step S4, it is determined whether or not boiling has ended. If a negative determination is made (in other words, during boiling), the process proceeds to step S5, and the mode switch 42 is turned on. Whether or not it is determined. Here, when a negative determination is made, step S2
Returning to, the remaining boiling time tm is displayed on the liquid crystal display device 29, but if an affirmative determination is made, the operation proceeds to step S6,
The preset heat retention temperature Ts is read from the microcomputer 36, and in step S7, the heat retention from the boiling water amount W and the room temperature Tr to the preset heat retention temperature Ts after boiling is performed in the same manner as in the first embodiment. The remaining time tn is calculated.

Thereafter, in step S8, the remaining heat retention reaching time ta = tm + tn from the start of boiling to the set warming temperature Ts is calculated, and this remaining heat retention remaining time ta is calculated in step S9.
9, and then the process returns to step S3.

On the other hand, if an affirmative decision is made in step S4, the preset heat retention temperature Ts is read from the microcomputer 36 in step S10, and the temperature sensor 13 and the room temperature sensor 24 are read in step S11.
And information from the water amount sensor 41 (that is, the hot water temperature Tw,
The room temperature Tr and the hot water amount W) are input to the microcomputer 36, and in step S12, the remaining heat retention time tn from boiling to reaching the set warming temperature Ts is calculated as described above from the hot water amount W and the room temperature Tr. In S13, the remaining heat retention time tn is displayed on the liquid crystal display device 29.

Then, in step S14, the remaining heat retention time tn is subtracted in 1 minute increments, and in step S15 the hot water temperature drop rate -ΔTw = -dTw / dt is calculated.
In step S16, the remaining heat retention time tn obtained in step S14 is corrected from the hot water temperature drop rate -ΔTw and the hot water temperature Tw at that time.

That is, the remaining heat retention time tn obtained by tn = (Ts-Tw) /-ΔTw is displayed again on the liquid crystal display device 29.

When it is confirmed in step S17 that the detected hot water temperature Tw has reached the set heat retention temperature Ts, the liquid crystal display device 29 displays the remaining heat retention time t in step S18.
It is displayed as n = 0, and in step S19, the heat retention arrival notification is given by a buzzer or the like.

As described above, in the present embodiment, the remaining boiling time t from the start of boiling water to the start of boiling
m, the heat retention remaining time tn after boiling until reaching the set heat retention temperature Ts, and the heat retention remaining time ta = tm + tn between the start of boiling water and the boiling until reaching the set heat retention temperature Ts are calculated by the residual time calculation means, and thus obtained The remaining boiling time tm, the remaining heat retention time tn, and the remaining heat retention time ta
= Tm + tn is the liquid crystal display device 29 by the remaining time display means.
Will be displayed in. Therefore, the user can recognize how long it takes to obtain hot water having a desired preset heat retention temperature after starting boiling, which is extremely convenient.

【The invention's effect】

According to the invention of claim 1, an inner container for boiling water, a heating means for heating the inner container, a temperature detecting means for detecting the temperature of the inner container, and a heat retaining means for setting a plurality of heat retaining temperatures. in the electric hot water storage vessel and a temperature setting means, leading to boiling after the start of heating water by the heating means
When kept remaining to reach the set set retained temperature by the heat retaining temperature setting means after boiling and boil remaining time until
And a remaining time display means for displaying the remaining heat retention reaching time obtained by the remaining time calculation means on the display device . The remaining heat retention time is determined by the temperature detection means.
It is compensated by the temperature drop rate of the detected temperature and the hot water temperature at that time.
As positive to, incubated arrival remaining time up to the setting retained temperature through boiling after the start of heating water is calculated by the remaining time calculating means, thus incubated arrival remaining time obtained in the display device by the remaining time display means Since it is displayed on the screen, it becomes possible for the user to recognize how long it takes to obtain hot water having the desired preset heat retention temperature after the start of boiling, which is extremely convenient. Also,
Remaining boiling time from the start of boiling to boiling, and boiling
The remaining heat retention time until the preset heat retention temperature is reached
By calculating the remaining heat retention time
This also has the effect of simplifying the arithmetic processing.
It In addition, information from the temperature sensing means that is an existing component
The remaining heat retention time can be calculated only by
There is also an effect that arithmetic processing can be performed at a cost.

As in the invention of claim 2 , claim 1
In the electric hot water storage container described, when the display switching means for selectively displaying the remaining boiling time and the remaining heat retention time on the display device is attached, the remaining boiling time and the remaining heat retention are achieved by the user operating the display switching means. The remaining time can be selectively displayed on the display device, and the user's request can be reflected.

[Brief description of drawings]

[0075]

FIG. 1 is a vertical cross-sectional view of an electric hot water container according to a first embodiment of the present invention.

FIG. 2 is a plan view of an operation panel in the electric hot water container according to the first embodiment of the present invention.

FIG. 3 is a block diagram of a control system in the electric hot water storage container according to the first embodiment of the present invention.

FIG. 4 is a flowchart showing the contents of the heat retention remaining time display control in the electric hot water storage container according to the first embodiment of the present invention.

FIG. 5 is a time chart showing a temperature rise pattern in the electric hot water storage container.

FIG. 6 is a flowchart showing the content of remaining boiling time display control in the electric hot water container according to the first embodiment of the present invention.

FIG. 7 is a vertical cross-sectional view of an electric hot water container according to a second embodiment of the present invention.

FIG. 8 is a block diagram of a control system in an electric hot water container according to a second embodiment of the present invention.

FIG. 9 is a flowchart showing the content of the heat retention remaining time display control in the electric hot water container according to the second embodiment of the present invention.

FIG. 10 is a plan view of an operation panel in the electric hot water container according to the third embodiment of the present invention.

FIG. 11 is a block diagram of a control system in an electric hot water container according to a third embodiment of the present invention.

FIG. 12 is a flowchart showing the contents of the heat retention remaining time display control in the electric hot water container according to the third embodiment of the present invention.

FIG. 13 is a block diagram of a control system in an electric hot water container according to a fourth embodiment of the present invention.

FIG. 14 is a flowchart showing the contents of the heat retention remaining time display control in the electric hot water container according to the fourth embodiment of the present invention.

[Explanation of symbols]

3 is an inner container, 4 is heating means (electric heater), 13 is temperature detecting means (temperature sensor), 29 is a display device (liquid crystal display device), 36 is a microcomputer, 38 is room temperature detecting means (room temperature sensor). , 41 is a water amount detecting means (water amount sensor), 42
Is a display switching means (mode switch).

─────────────────────────────────────────────────── ─── Continuation of front page (58) Fields surveyed (Int.Cl. ⁷ , DB name) A47J 27/21

Claims (2)

(57) [Claims] [0001] 1. An inner container for boiling water, a heating means for heating the inner container, a temperature detecting means for detecting a temperature of the inner container, and a heat retaining temperature setting means for setting a plurality of heat retaining temperatures. An electric hot water storage container, the remaining boiling time from the start of boiling by the heating means to the boiling and after boiling
And a remaining time calculation means for calculating a remaining heat retention time obtained by adding the remaining heat retention time until the temperature reaches the set heat retention temperature set by the temperature retention temperature setting means, and the remaining time calculation. while attached to the remaining time display means for displaying on the display device warmth arrival remaining time obtained by the means, the thermal insulation
The remaining time is the temperature drop of the temperature detected by the temperature detection means.
An electric hot water storage container characterized in that it is adjusted according to the rate and the hot water temperature at that time . Wherein said claim 1 electric hot water storage vessel, wherein the annexed a display switching means for displaying alternatively display device and said boiling remaining time and the thermal insulation arrival remaining time.