JP3395723B2 - Electric hot water storage container - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electric hot water storage container, and more particularly to boiling judgment in an electric hot water storage container.

[0002]

2. Description of the Related Art Conventionally, as a boiling judgment method in an electric hot water storage container, there is a method of detecting water vapor, or a boiling judgment is made when an increase rate of an inner container temperature or a temperature gradient detected by a temperature detecting means falls below a set value. There was a method to do.

[0003]

However, in the former case, it is necessary to provide a sensor for detecting water vapor in the vapor passage provided in the lid or the like, and the wiring of the signal line to the sensor is connected to the lid and the main body. There was a problem that it was necessary during.

In the latter case, since only the rate of temperature rise or the temperature gradient is used as an index, when the steam-saving boiling control method of reducing the output of the heating means to suppress the amount of generated steam is adopted, the main body There is a risk that the microcomputer may make an erroneous determination before it actually boils due to variations in the above.

The present invention has been made in view of the above points, and it is an object of the present invention to make it possible to perform accurate boiling determination by performing boiling determination using two determination indexes.

[0006]

According to the invention of claim 1, as means for solving the above-mentioned problems, an inner container for storing hot water, a heating means for heating the inner container, and a temperature of the inner container are detected. time of the electric hot water storage vessel and a temperature detection means for the temperature detected by said temperature detecting means water in the inner container from the time it reaches the predetermined temperature is passed while during heating that would lead to boiling When the temperature detected by the temperature detecting means in is equal to or higher than a preset temperature ,
Or at that time despite the elapse of the heating time
Of the temperature detected by the temperature detecting means of
The inner container from the time of its if not a constant temperature or higher
Reset the heating time in which the water in the
When the heating time has elapsed, the temperature detection means detects the temperature.
Boiling determination means for determining boiling when the output temperature is equal to or higher than a preset temperature is additionally provided.

With the above arrangement, the temperature detecting means is heated from the time when the temperature detected by the temperature detecting means reaches a predetermined temperature to the time when the water in the inner container is heated for a heating time that would bring the water to boiling. When the temperature detected by is above the preset temperature , or before
Detecting temperature at that time despite the elapse of heating time
The temperature detected by the means is above the preset temperature.
If not, the water in the inner container will boil from that time.
The heating time will be reset and the heating time has elapsed
The temperature detected by the temperature detecting means at the time point is preset
When the temperature exceeds the set temperature, it will be judged as boiling. In other words, the boiling determination is performed based on two of the elapsed heating time and the set temperature, so that the boiling determination with less erroneous determination can be performed.

According to the second aspect of the invention, as means for solving the above-mentioned problems, an inner container for storing hot water, a heating means for heating the inner container, and a temperature detecting means for detecting the temperature of the inner container are provided. In an electric hot water storage container provided, a temperature increase rate calculating means for calculating an increase rate of the temperature detected by the temperature detecting means, and a preset increase rate for the temperature increase rate calculated by the temperature increase rate calculating means. When the temperature detected by the temperature detecting means at the time when the temperature becomes below becomes a preset temperature or higher , or when the temperature rises above
Is it likely that the rate of increase will fall below the preset rate of increase?
However, the temperature detected by the temperature detection means at that time is
If the temperature is not higher than the preset temperature,
Repeated calculation of temperature rise rate by temperature rise rate calculation means
However, the temperature rise rate obtained each time is set in advance.
When the temperature falls below the rate of rise,
Boiling determination means for determining boiling when the output temperature is equal to or higher than a preset temperature is additionally provided.

With the above arrangement, the temperature detected by the temperature detecting means is preset when the temperature increasing rate detected by the temperature detecting means becomes equal to or lower than the preset set increasing rate. When the temperature exceeds the set temperature , or the temperature rise rate is set in advance
Even if the rate of increase was less than or equal to
If the temperature detected by the output means exceeds the preset temperature
If not, the temperature rise rate calculation means
Repeatedly calculating the temperature rise rate, the temperature rise rate obtained each time
Temperature detection when the temperature rises below the preset rate of rise
If the temperature detected by the output means exceeds the preset temperature
When it becomes, it will be judged as boiling. In other words, the boiling determination is performed based on two of the temperature increase rate and the set temperature, so that the boiling determination with less erroneous determination can be performed.

[0010]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Some preferred embodiments of the present invention will be described in detail below with reference to the accompanying drawings.

First Embodiment FIGS. 1 to 3 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 is made of a synthetic resin outer case 7 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 composed of a stainless steel inner cylinder 10 having a bottom and a stainless steel outer cylinder 11 having a substantially cylindrical shape.
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. Reference numeral 13 is a temperature sensor which functions as a temperature detecting means for detecting the temperature of the inner container 3.

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 joined to the upper plate 14 by welding. The hinge receiver 16 provided at the rear portion is supported by a hinge pin 17 so as to be openable / closable and detachable. Code 1
Reference numeral 8 is a steam discharge passage.

A metal cover member 19 is fixed to the lower plate 15 of the lid body 2.
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 equipped with various switches described later, and 23 is a control board.

As shown in FIG. 2, the operation panel 22 is provided with a hot water supply switch 24, a lock release switch 25, a cupmen timer 26, a reboil switch 27, a heat retention selection switch 28 and the like.

FIG. 3 is a block diagram showing the structure of the main part of the control board 23. Reference numeral 4 is an electric heater, 13 is a temperature sensor composed of a thermistor, and 27 is a reboil switch.

Reference numeral 29 is a microcomputer unit (hereinafter abbreviated as a microcomputer), which has a processing unit CPU, a memory RAM, and a program memory RO inside.
M, input port A with analog / digital conversion function
/ D, 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 29. The microcomputer 29 has an interrupt signal input terminal INT
When an interrupt signal is input to, interrupt processing is performed.

Reference numeral 34 is a zero-cross detection circuit of the commercial AC power supply 33, which sends out a signal at the moment when the sine wave of the commercial AC power supply 33 becomes 0 V and sends a timer interrupt signal to the interrupt signal input terminal INT of the microcomputer 29. give. Upon receiving the timer interrupt signal, the microcomputer 29 counts 10 seconds by counting the internal timer. The output signal of the temperature sensor 13 is fetched every 10 seconds, converted into temperature data, and sequentially stored in the internal memory.

The microcomputer 29 uses the temperature sensor 1
And a function as a heating time calculation means for calculating a heating time ta at which the water in the inner container 3 will boil from the time when the temperature T detected by 3 reaches a predetermined temperature T ₀ , and the heating time calculation And a function as a boiling determination means that determines that the temperature T is boiling when the temperature T detected by the temperature sensor 13 at the time when the heating time ta calculated by the means exceeds a preset temperature Ts or more, It has a function as heating control means for reducing the output of the electric heater 4 from the time when the temperature T detected by the temperature sensor 13 reaches a predetermined temperature T ₀ .

Reference numeral 30 is a light emitting diode of the display means, 3
Reference numeral 1 denotes a buzzer which is a notification means, and the light emitting diode 30 and the buzzer 31 display or notify the amount of water contained in the inner container 3, the heat retention operation state, the abnormal state display and the like. .

Reference numeral 32 is a relay, and 33 is a commercial AC power supply. The output from the microcomputer 29 causes the relay 32
By controlling the heating power applied to the electric heater 4 from the commercial AC power supply 33.

Next, the boiling determination control in the electric hot water storage container having the above configuration will be described with reference to the flowcharts shown in FIGS. 4 and 5 and the time chart shown in FIG.

(I) Boiling Determination Control (Refer to Flowchart of FIG. 4) When it is determined in step S1 that boiling is being performed (that is, the electric heater 4 is fully energized), step S2
At, the temperature information from the temperature sensor 13 (that is, the detected temperature T) is input to the microcomputer 29. Then, in step S3, the detected temperature T and the predetermined temperature T ₀ are compared. Here, the predetermined temperature T ₀ is a temperature at which the temperature of the hot water in the inner container 3 is uniform (that is, a temperature at which the rise in the hot water temperature is constant), and is set to 93 ° C., for example. T in step S3
Although boiling heating is continued while <T ₀ is determined,
If it is determined that T ≧ T ₀ , a water amount determination process (described in detail later) in the inner container 3 is performed in step S4. In this water amount determination process, the output of the electric heater 4 is lowered by a predetermined value as described later (see the time chart in FIG. 6).

Based on the result of the water amount determination process, the heating time ta (see the time chart of FIG. 6) at which the water in the inner container 3 will boil from that point is set by the timer in step S5, and step If the count-up of the timer is confirmed in step S6, step S
At 7, the detected temperature T of the temperature sensor 13 is compared with the preset temperature Ts. Here, the set temperature Ts is set to a temperature (eg, 99 ° C.) that is as close as possible to the boiling temperature (eg, 100 ° C.). If it is determined in step S7 that T <Ts, it means that the boiling point has not reached the boiling point despite the elapse of the heating time ta. Therefore, in step S8, the amount of water and the detected temperature T at that time causes the water in the inner container 3 to boil. The heating time ta ′ (see the time chart of FIG. 6) is reset by the timer, but as shown by the dotted line in the time chart of FIG. 6, if it is determined that T ≧ Ts after the heating time ta has elapsed, In step S9, the boiling notification is given by the sound of the buzzer 31.

On the other hand, when the timer is reset in step S8, the process returns to step S6, waits for the timer to count up, and the detected temperature T is compared with the set temperature Ts in step S7, and T ≧ Ts. It is repeated until it is determined that, but when it is determined that T ≧ Ts, the boiling notification is issued by the buzzer 31 in step S9.

When the boiling notification is issued in step S9, the output of the electric heater 4 is further reduced in step S10, and the electric heater 4 is energized after waiting for the predetermined time t ₁ to be determined in step S11. Is stopped (see the time chart in FIG. 6). That is,
The additional heating is performed for the predetermined time t ₁ . The additional heating after the boiling notification is not always necessary, but when the additional heating is performed, the additional heating can be surely performed.

(II) Water Volume Determination Process (Refer to Flowchart of FIG. 5) First, in step S 1, the output of the electric heater 4 is lowered by a predetermined value as shown in the time chart of FIG. 6 (for example, 905 W to 800 W). Down to intermittent energization). In this way, the amount of heating from the predetermined temperature T ₀ to boiling is reduced, and the amount of vapor discharged during boiling can be reduced.

Next, in step S2, the temperature information from the temperature sensor 13 (that is, the detected temperature T) is input to the microcomputer 29, and in step S3, the three detected temperatures Tn (n = 0 to 2) every 10 seconds. is the memory in the microcomputer 29, T ₂ -T ₀ is calculated in step S4, the result is a temperature rise of x, compared with the temperature rise of x and the set value X _1, X ₂ in step S5 and S6 Is done. Here, X ₁ > X ₂ . Step S5
If x ≦ X ₁ is determined in step S7, step S7
When it is determined that the water amount = W ₁ (that is, a large amount) in step S6 and when X ₁ <x ≦ X ₂ is determined in step S6, it is determined that the water amount = W ₂ (that is, a medium amount) in step S8, and the step When it is determined that x> X _{2 in} S6, it is determined in step S9 that the water amount = W ₃ (that is, a small amount).

As described above, in the present embodiment, the heating time ta at which the water in the inner container 3 will boil after the temperature T detected by the temperature sensor 13 reaches the predetermined temperature T _0. When the temperature T detected by the temperature sensor 13 becomes equal to or higher than a preset temperature Ts at the time of heating only, it is determined to be boiling. That is, the boiling determination is performed with reference to the elapse of the heating time ta and the set temperature Ts, so that the boiling determination with less erroneous determination can be performed.

Second Embodiment FIG. 7 and FIG. 8 show flowcharts of boiling judgment control and boiling judgment processing in an electric hot water container according to a second embodiment of the present invention.

In this case, the microcomputer 29 functions as a temperature increase rate calculating means for calculating the increase rate α of the temperature T detected by the temperature sensor 13, and the temperature increase rate α calculated by the temperature increase rate calculating means. When the temperature T detected by the temperature sensor 13 becomes equal to or higher than the preset set temperature Ts when the preset rise rate A becomes equal to or lower than the preset rise rate A, the function as a boiling determination unit that determines that the temperature is boiling It also has a function as heating control means for reducing the output of the electric heater 4 from the time when the temperature T detected by the temperature sensor 13 reaches a predetermined temperature T ₀ . Other configurations are the same as those in the first embodiment, and thus the description thereof will be omitted.

Next, the boiling judgment in this embodiment will be described with reference to the flowcharts shown in FIGS. 7 and 8.
It will be described with reference to the time chart shown in FIG.

(I) Boiling determination control (see the flowchart in FIG. 7) When it is determined in step S1 that boiling is being performed (that is, the electric heater 4 is fully energized), step S2
At, the temperature information from the temperature sensor 13 (that is, the detected temperature T) is input to the microcomputer 29. Then, in step S3, the detected temperature T and the predetermined temperature T ₀ are compared. Here, the predetermined temperature T ₀ is a temperature at which the temperature of the hot water in the inner container 3 is uniform (that is, a temperature at which the rise in the hot water temperature is constant), and is set to 93 ° C., for example. T in step S3
Although boiling heating is continued while <T ₀ is determined,
If it is determined that T ≧ T ₀ , a boiling determination process (described in detail later) is performed in step S4. In the boiling determination process, as will be described later, the degree of increase α of the detected temperature T is a predetermined value A
It is performed depending on whether or not the following. In this boiling determination process, the output of the electric heater 4 is lowered by a predetermined value, as will be described later (see the time chart in FIG. 9).

When it is determined in step S5 that the boiling determination process has been completed, the temperature T detected by the temperature sensor 13 is compared with the preset temperature Ts in step S6. Here, the set temperature Ts is a temperature (eg, 99 ° C.) that is as close as possible to the boiling temperature (eg, 100 ° C.).
C)). When it is determined that T <Ts in step S6, boiling is not actually reached even though it is determined to be boiling in the boiling determination process.
The odor boiling determination data is cleared, the process returns to step S2, and the control thereafter is repeated. When it is determined that T ≧ Ts in step S6, boiling notification is given by buzzer 31 in step S8.

When the boiling notification is given in step S8, the output of the electric heater 4 is further reduced in step S9, and the electric heater 4 is energized after waiting for the predetermined time t ₁ to be determined in step S10. Is stopped (see the time chart in FIG. 9). That is, the additional heating is performed for the predetermined time t ₁ . The additional heating after the boiling notification is not always necessary, but when the additional heating is performed, the additional heating can be surely performed.

(II) Boiling Determination Process (Refer to Flowchart of FIG. 8) First, in step S1, the output of the electric heater 4 is lowered by a predetermined value as shown in the time chart of FIG. 9 (for example, 905W to 800W). Down to intermittent energization). In this way, the amount of heating from the predetermined temperature T ₀ to boiling is reduced, and the amount of vapor discharged during boiling can be reduced.

Next, in step S2, the temperature information from the temperature sensor 13 (that is, the detected temperature T) is input to the microcomputer 29, and in step S3, the four detected temperatures Tn (n = 0 to 3) every 10 seconds. It is stored in the microcomputer 29, and it is determined in step S4 whether or not the calculation of x = T ₂ −T ₀ has already been performed. If a negative decision is made here, the operation proceeds to step S5, where x = T ₂ −T ₀ is calculated, and as a result, the set value A is set in step S6. Step S7 calculation of the temperature rise rate y = T ₃ -T ₀ is made in comparison with the set value A and the temperature increase rate y is made at step S8.

The set value A is the inclination at the point P where the inclination of the temperature rise line Z in the time chart of FIG. 9 changes greatly. The reason is that the rate of temperature increase greatly changes (that is, approaches 0) as the temperature approaches boiling.

If y≤A is determined in step S8, the boiling flag is set, and the boiling determination process ends.

If an affirmative determination is made in step S4, the process directly proceeds to step S7 and the following control is executed.

As described above, in the present embodiment, the temperature detected by the temperature sensor 13 at the time when the increase rate y of the temperature T detected by the temperature sensor 13 becomes equal to or less than the preset set value A. When T becomes equal to or higher than the preset temperature Ts, it is determined that the boiling occurs. That is, the boiling determination is performed with reference to the temperature increase rate α and the set temperature Ts, so that the boiling determination with less erroneous determination can be performed.

[0045]

According to the invention of claim 1, an electric hot water storage container is provided with an inner container for storing hot water, a heating means for heating the inner container, and a temperature detecting means for detecting the temperature of the inner container. , setting the detection temperature detected temperature by the temperature detecting means at the time when the water has passed during the time of heating that would lead to boiling of the inner container from the time it reaches the predetermined temperature by the temperature detecting means in advance When the temperature exceeds the set temperature , or when the heating time has elapsed
The temperature detected by the temperature detecting means at the point is preset.
If the temperature is not higher than the set temperature,
Reset the heating time that the water in the container will boil,
By the temperature detecting means at the time when the heating time has elapsed
When the detected temperature exceeds a preset temperature , a boiling determination means for determining boiling is additionally provided, and the temperature in the inner container is reached from the time when the temperature detected by the temperature detection means reaches a predetermined temperature. When the temperature detected by the temperature detecting means is equal to or higher than a preset temperature at the time of heating for a heating time that would bring the water to boiling , or the heating
Despite the passage of time, the temperature detection means at that time
The detected temperature is higher than the preset temperature.
If not, the water in the inner container may boil from then on.
Reset the heating time, and when the heating time elapses
The temperature detected by the temperature detection means is preset temperature
I decided to boil when it became over, so
The boiling judgment is performed with reference to the elapse of the heating time and the set temperature, and there is an effect that the boiling judgment can be performed with few erroneous judgments.

According to the second aspect of the invention, there is provided an electric hot water storage container comprising an inner container for storing hot water, heating means for heating the inner container, and temperature detecting means for detecting the temperature of the inner container. A temperature rise rate calculating means for calculating a temperature rise rate detected by the temperature detecting means, and the temperature rise rate calculated by the temperature rise rate calculating means when the temperature rise rate is equal to or lower than a preset set rise rate. When the temperature detected by the temperature detecting means exceeds a preset temperature ,
Alternatively, the temperature increase rate is less than or equal to a preset increase rate.
The temperature detection hand at that time even though it became lower
The temperature detected by the step exceeds the preset temperature.
If not, the temperature rise by the temperature rise rate calculation means
Repeatedly calculating the temperature rise rate, the temperature rise rate obtained each time
The temperature at the time when it falls below a preset rate of rise
The temperature detected by the temperature detection means is below the preset temperature.
A boiling determination means for determining boiling when the temperature rises is additionally provided, and the temperature detection means detects the temperature rise rate when the temperature rise rate detected by the temperature detection means is equal to or lower than a preset rise rate. When the temperature exceeds a preset temperature , or the rate of temperature rise is preset
At that time, even though it was below the set rate of increase
The temperature detected by the temperature detection means in
If the temperature is not higher than the temperature,
Repeated calculation of temperature rise rate by
When the rate of increase is below the preset rate of increase
The temperature detected by the temperature detection means in
Since it is determined to be boiling when the temperature becomes equal to or higher than the temperature, the boiling determination is performed based on two of the temperature increase rate and the set temperature, and it is possible to perform the boiling determination with less erroneous determination. effective.

[Brief description of drawings]

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 showing a main part of a control board in the electric hot water container according to the first embodiment of the present invention.

FIG. 4 is a flowchart showing the contents of boiling determination control in the electric hot water storage container according to the first embodiment of the present invention.

FIG. 5 is a flowchart showing the content of a water amount determination process in the electric hot water storage container according to the first embodiment of the present invention.

FIG. 6 is a time chart showing changes in temperature and changes in the output of the electric heater during boiling control in the electric hot water storage container according to the first embodiment of the present invention.

FIG. 7 is a flowchart showing the contents of boiling determination control in the electric hot water storage container according to the second embodiment of the present invention.

FIG. 8 is a flowchart showing the contents of boiling determination processing in the electric hot water container according to the second embodiment of the present invention.

FIG. 9 is a time chart showing changes in temperature and changes in output of the electric heater during boiling control in the electric hot water storage container according to the second 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), and 29 is a microcomputer.

Claims (2)

(57) [Claims] 1. An electric hot water storage container comprising an inner container for storing hot water, a heating means for heating the inner container, and a temperature detecting means for detecting the temperature of the inner container, wherein the temperature detecting means detects the temperature. a temperature detection temperature is a preset temperature or more by the temperature detecting means at the time when the water has passed during the time of heating that would lead to boiling of the inner container from the time of reaching a predetermined temperature Or when the heating time
Despite the progress, by the temperature detection means at that time
The detected temperature has exceeded the preset temperature.
In that case, the water in the inner container will boil from that time.
When the brazing time is reset and the heating time has elapsed
The temperature detected by the temperature detecting means in
An electric hot water storage container characterized by being equipped with a boiling determination means for determining boiling when the temperature exceeds a set temperature . 2. An electric hot water storage container comprising an inner container for storing hot water, heating means for heating the inner container, and temperature detection means for detecting the temperature of the inner container, the temperature detection means detecting the temperature. Temperature rise rate calculating means for calculating the temperature rise rate, and detection by the temperature detecting means at the time when the temperature rise rate calculated by the temperature rise rate calculating means is equal to or lower than a preset set rate of rise When the temperature rises above the preset temperature, or the temperature rise rate is
Even though the rate of increase is less than the set rate of increase
The temperature detected by the temperature detecting means at that time is preset.
If the temperature is not higher than the set temperature, the temperature will rise.
Repeating the calculation of the temperature rise rate by the rate calculation means,
The temperature rise rate obtained is less than or equal to the preset temperature rise rate.
The temperature detected by the temperature detecting means when
An electric hot water storage container is provided with a boiling determination means for determining boiling when the temperature exceeds a preset temperature .