JPH07120063A - Hot water storage type electric water heater - Google Patents

Abstract

PURPOSE:To make it possible to prevent occurrence of insufficiency of hot water by continuing heating of water even when abnormality occurs in a temperature sensor for detecting a ready-bath temperature. CONSTITUTION:It is detected by a sensor abnormality detecting means 5 whether a temperature sensor 1 for detecting a ready-bath temperature and temperature sensors 2a to 2c for detecting the quantity of residual hot water are normal or not. When the temperature sensor 1 for detecting the ready-bath temperature is normal, an operation control means 6 outputs an electrification stop command to a heater electrification control means 9 on the basis of an output of this temperature sensor. In the case when the temperature sensor 1 turns abnormal, the operation control means 6 outputs the electrification stop command when all of the temperature sensors 2a to 2c for detecting the quantity of residual hot water detect a set temperature. When the sensor abnormality detecting means 5 detects that the temperature sensors 2a to 2c for detecting the quantity of residual hot water are abnormal, the operation control means 6 stops an operation of heating water.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a hot water storage type electric water heater capable of continuing the boiling water operation as much as possible even if an abnormality occurs in a temperature sensor.

[0002]

2. Description of the Related Art A hot water storage type electric water heater described in Japanese Utility Model Publication No. 5-17556 discloses a boiling temperature detecting temperature sensor for detecting the boiling temperature of hot water and a feed water temperature detecting temperature sensor for detecting the feed water temperature. In addition, if there is an abnormality in the boiling temperature detection temperature sensor (including related parts such as connecting wires) among the plurality of remaining hot water amount detection temperature sensors for detecting the remaining hot water amount, boiling water is boiled. The control means is provided for stopping the operation and executing a boiling operation of the hot water when an abnormality occurs in another temperature sensor. By providing such control means, it is possible to prevent a shortage of hot water when an abnormality occurs in a temperature sensor other than the boiling temperature detecting temperature sensor.

[0003]

In the conventional hot water storage type electric water heater, when the temperature sensor for detecting the boiling temperature is abnormal, the boiling operation of the hot water is stopped for detecting the boiling temperature. It is based on the common sense that there is no temperature sensor other than the temperature sensor that can prevent hot water from boiling to an abnormally high temperature. However, even if the plurality of remaining hot water amount detection temperature sensors are normal, the boiling water operation was stopped when an abnormality occurred in the boiling temperature detection temperature sensor, so the shortage of hot water should be minimized. It is not possible.

An object of the present invention is to provide a hot water storage type electric water heater capable of preventing boiling water shortage by continuing boiling water even if an abnormality occurs in the boiling temperature detecting temperature sensor. is there.

[0005]

SUMMARY OF THE INVENTION A hot water storage type electric water heater, which is the object of the present invention, comprises a boiling temperature detecting temperature sensor for detecting the boiling temperature of hot water, and a feed water for detecting the feed water temperature. Temperature detection temperature sensor, a plurality of remaining hot water amount detection temperature sensors for detecting the amount of remaining hot water, sensor abnormality detection means, heater energization control means, and display means for displaying operation contents etc. in response to a display command. And operation control means. The heater energization control unit controls energization to the heater according to the operation control command output from the operation control unit.

According to the first and second aspects of the invention, the operation control means determines whether or not to perform the boiling water operation based on the output of the sensor abnormality detection means, and based on the outputs of the plurality of temperature sensors, the heater. Hot water storage that outputs an operation control command to the energization control unit, outputs a display command to the display unit, and outputs an energization stop command to the heater energization control unit to stop energization of the heater when the temperature of the hot water reaches a preset temperature. The electric hot water heater is targeted for improvement.

According to the first aspect of the invention, when the sensor abnormality detecting means detects that the boiling temperature detecting temperature sensor is normal, the energization stop command is issued based on the output of the boiling temperature detecting temperature sensor. When the sensor abnormality detecting means detects that the temperature sensor for boiling temperature detection is abnormal, at least one of the other temperature sensors that the sensor abnormality detecting means determines to be normal. The operation control means is configured to output the energization stop command based on the output.

When the boiling temperature detecting temperature sensor also serves as the feed water temperature detecting temperature sensor, the feed water temperature detecting temperature sensor is not included in the "other temperature sensor".

The sensor abnormality detecting means detects whether or not the temperature detected by each of the plurality of temperature sensors is out of a preset normal temperature detection range, thereby detecting an abnormality in the temperature sensor. Here, "normal temperature detection range" means
It means a preset range as the temperature range of hot water and water. "Abnormality of the temperature sensor" means not only the abnormality of the temperature sensor itself but also the abnormality of related parts such as the connection wire and the connection terminal (disconnection, connection failure etc.) ) Is also included.

The operation mode used for the boiling operation in the normal state is arbitrary. As the operation mode when the normal temperature sensor remaining when the sensor abnormality is detected is used, an operation mode in which the normal temperature sensor is used to prevent the temperature of the hot water from boiling to an abnormally high temperature is used.

If the boiling operation is continued when all the other temperature sensors become abnormal, the temperature of the hot water becomes abnormally high, so it is necessary to prevent such a situation. For example, the boiling operation can be stopped when all the other temperature sensors become abnormal. In addition, if the energization stop command is output by using the output of all the remaining hot water amount detection temperature sensors among the other temperature sensors, if even one of the remaining hot water amount detection temperature sensors becomes abnormal, the boiling operation is performed. Stop. Furthermore, when outputting the energization stop command by using only the output of some of the other temperature sensors, it is necessary to stop the boiling operation when some of the temperature sensors become abnormal. Become.

When outputting the energization stop command by using another temperature sensor, how to output the energization stop command is arbitrary. For example, the set temperature of the upper limit temperature may be set in advance for all other temperature sensors, and the energization stop command may be output when at least one normal temperature sensor detects the set temperature. . In this way, even if some of the other temperature sensors become abnormal, the energization stop command can be output easily and reliably by the output of the remaining temperature sensors.
Alternatively, the other temperature sensors may be prioritized and the energization stop command may be output using the output of the temperature sensor having the higher priority. In this case, when the temperature sensor in the higher priority order becomes abnormal, the energization stop command is output using the output of the temperature sensor in the next order. When prioritizing, it is preferable to give higher priority to the temperature sensor located below the hot water storage tank.

According to the second aspect of the present invention, when all of the plurality of remaining hot water amount detecting temperature sensors detect the set temperature, an energization stop command is output, and it is detected that there is an abnormality in the plurality of remaining hot water amount detecting temperature sensors. The operation control means is configured to stop the boiling operation of the hot water when the means detects.

According to the third aspect of the invention, when the sensor abnormality detecting means detects that at least one of the boiling temperature detecting temperature sensor and the other temperature sensor is a normal temperature sensor, the normal temperature sensor is detected. The operation control means is configured to execute the boiling operation of the hot water based on the output, and stop the boiling operation of the hot water when the sensor abnormality detecting means detects that all the temperature sensors are abnormal.

[0015]

In the past, when the temperature sensor for detecting the boiling temperature becomes abnormal, the hot water is boiled to an abnormally high temperature.
At that time, I thought that the boiling operation should be stopped. This is when the temperature sensor for boiling temperature detection disappears,
It comes from the stereotype that too much boil cannot be detected. However, in the hot water storage type electric water heater, the water or hot water located above the heater during boiling is convected in the hot water storage tank, so the temperature sensor other than the temperature sensor for boiling temperature detection must also detect the boiling temperature. Can be done. The basic idea of the present invention is to use at least one of the other temperature sensors as a boiling temperature detecting temperature sensor when the boiling temperature detecting temperature sensor becomes abnormal.

Therefore, in the invention of claim 1, when the sensor abnormality detecting means detects that the temperature sensor for detecting the boiling temperature is abnormal, the other temperature which the sensor abnormality detecting means determines to be normal. The operation control means outputs an energization stop command based on the output of at least one temperature sensor of the sensors. As a result, when the boiling temperature detecting temperature sensor becomes abnormal, it becomes possible to use a temperature sensor other than the boiling temperature detecting temperature sensor as the boiling temperature detecting temperature sensor.

When all of the plurality of remaining hot water amount detecting temperature sensors detect the set temperature, an energization stop command is output, and at least the remaining hot water amount at the bottom of the hot water storage tank is set. Hot water can be sufficiently boiled up to the position of the temperature sensor for detection.

According to the third aspect of the present invention, if at least one of the boiling temperature detecting temperature sensor and the other temperature sensor is a normal temperature sensor, the normal temperature sensor is used to perform the boiling operation. If the boiling temperature detecting temperature sensor is abnormal, another temperature sensor is used as the boiling temperature detecting temperature sensor to perform the boiling operation. Only when all the temperature sensors become abnormal, the boiling water boiling operation is stopped. Therefore, according to the present invention, the boiling operation of the hot water can be continued until all the temperature sensors become abnormal, so that the shortage of hot water can be minimized.

[0019]

Embodiments of the present invention will now be described in detail with reference to the drawings. FIG. 1 is a block diagram showing a configuration of a control unit according to an embodiment of the present invention, and FIG. 2 is a diagram showing an installation state of each temperature sensor. In these figures, reference numeral 1 denotes a boiling temperature detecting temperature sensor, and this temperature sensor 1 detects the boiling temperature of hot water and the temperature of the supplied water, so that a hot water storage tank 13 is provided.
Is installed above the heater 11 in the lower region of the.
This temperature sensor is also used as a temperature sensor for detecting the supply water temperature. 2a to 2c are temperature sensors for detecting the amount of remaining hot water, which are provided above the temperature sensor 1 at predetermined intervals to detect the amount of remaining hot water.

The outputs of these temperature sensors 1 to 2c are A
It is input to the / D converter 3, converted into a digital value, and sent to the sensor abnormality detection means 5 and the operation control means 6. The output from the timer means 4 is also input to the operation control means 6. When the power is turned on in a specific power time zone such as the midnight power time zone, the timer means 4 sends the power supply information of the midnight power to the operation control means 6 and starts counting the time limit.
When power is stopped, it goes into reset state.

The sensor abnormality detecting means 5 is provided for each temperature sensor 1
It is detected whether or not each of the detected temperatures of ~ 2c is out of a preset normal temperature detection range, and an abnormality of each temperature sensor is detected. Therefore, the sensor abnormality detection means 5 stores in advance data of the normal temperature detection range for each of the temperature sensors 1 to 2c. It should be noted that this data may be stored in the storage means 7 for storing the operation program and data used for the calculation in the operation control means 6. Here, the normal temperature detection range when a thermistor is used as the temperature sensor can be set to −25 to + 110 ° C. as described in detail in Japanese Utility Model Publication No. 5-17556. When other temperature sensors are used, the normal temperature detection range is determined according to the characteristics of the temperature sensor used.

Upon receiving the power input information from the timer means 4, the operation control means 6 uses the water temperature measured by the temperature sensor 1, the set temperature set by the temperature setting means (not shown), and the outputs of the temperature sensors 2a to 2c. The amount of remaining hot water obtained, the capacity of the hot water storage tank 13, the capacity of the heater, and the like are used to calculate the energization start time (energization shift time) to the heater 11 according to a predetermined arithmetic expression. The data necessary for the calculation and the operation program are stored in the storage means 7. Generally, the energization shift time is obtained so that the hot water boil up to the set temperature at the end time of the midnight power time zone. The calculation formula used to calculate the energization shift time is arbitrary. As is well known, the operation mode of the hot water storage type electric water heater is not limited to the operation mode in which the energization start time is shifted as in the present embodiment, and the operation mode in which energization of the heater is started at the same time when the power supply to the night is started. There are various operation modes such as an operation mode in which reheating is performed when a large amount of hot water is used.

Further, when the sensor abnormality detecting means 5 detects an abnormality in the temperature sensor, the operation mode used for executing the boiling operation is such that a normal temperature sensor is used and the temperature of the hot water is not raised to an abnormally high temperature. Any operation mode can be used as long as it can do so. However, when the boiling temperature detecting temperature sensor 1 becomes abnormal, an operation mode in which at least one of the other temperature sensors 2a to 2c is used as a boiling temperature detecting temperature sensor is adopted.
For example, when the boiling temperature detecting temperature sensor 1 becomes abnormal and the remaining hot water amount detecting temperature sensors 2a to 2c are all normal, the energization start time is shifted in consideration of the remaining hot water amount to detect the remaining hot water amount. At least one of the temperature sensors 2a to 2c for use
An operation mode in which one temperature sensor is used as a temperature sensor for detecting a boiling temperature can be used. Further, when some of the remaining hot water amount detecting temperature sensors 2a to 2c become abnormal, the remaining hot water amount cannot be detected. Therefore, the energization start time is shifted without considering the remaining hot water amount to detect the normal remaining hot water amount. An operation mode in which at least one temperature sensor of the temperature sensors is used as a boiling temperature detecting temperature sensor can be used. Furthermore, when any one of the temperature sensors is detected to be abnormal, it is possible to use an operation mode in which the boiling of the hot water is immediately started without shifting the energization start time.

In the operation mode in which the energization start time is shifted, the water temperature is required for the calculation, but when the boiling temperature detecting temperature sensor 1 also serves as the feed water temperature detecting sensor as in this embodiment. Cannot know the water temperature.
In such a case, the previous water temperature may be stored in the storage means 7 and the stored water temperature may be used as in the technique disclosed in Japanese Utility Model Laid-Open No. 3-77152.
Further, in such a case, a predetermined constant water temperature (for example, 10 ° C.) may be used.

The operation control means 6 is a sensor abnormality detection means 5
When the sensor abnormality is detected, a display command is output to the display control means 8 to display that the temperature sensor has an abnormality and the sensor in which the abnormality has occurred.

The sensor abnormality detecting means 5 and the operation controlling means 6 are constructed by using a microcomputer.

FIG. 3 shows an algorithm of an example of a program used to realize an embodiment of the present invention using the configuration of FIG. In this embodiment, as specified in claim 2, when all of the remaining hot water amount detecting temperature sensors 2a to 2c detect the set temperature, the operation control means 6 outputs an energization stop command, and the remaining hot water amount detecting temperature sensor 2a. When the sensor abnormality detecting means 5 detects that there is at least one abnormality in .about.2c, the boiling water operation is stopped. In step ST1, it is determined whether or not the boiling temperature detecting temperature sensor 1 is normal. If the temperature sensor 1 is normal, in step ST2, the boiling operation is performed in the normal operation mode. Details of step ST2 are as shown in FIG.
First, in step ST21, the water temperature is detected, and then in step ST2
At 2, it is determined whether or not it is in the midnight power time. If it is in the midnight power time zone, the energization shift time is calculated in step ST23. The calculation at this time is
The amount of remaining hot water detected by the temperature sensors 2a to 2c is also considered. After determining the energization shift time, it is determined in step ST24 whether the energization shift time has elapsed. If the energization shift time has elapsed, the temperature of the hot water is measured in step ST25. If the temperature of the hot water is equal to or lower than the set temperature, the operation control means 6 outputs to the heater energization control means 9 an energization start command for starting energization. After starting the energization of the heater, when it is detected in step ST25 that the temperature of the hot water detected by the temperature sensor 1 reaches the set temperature, the operation control means 6 causes the heater energization control means 9 to stop the energization of the heater. Outputs a power stop command. This completes the normal boiling.

Returning to FIG. 3, if it is determined in step ST1 that the boiling temperature detecting temperature sensor 1 is abnormal,
In step ST3, the operation control means 6 outputs to the display control means 8 a display command for displaying that the temperature sensor 1 is abnormal. Then, in step ST4, it is determined whether or not all of the remaining hot water amount detecting temperature sensors 2a to 2c are normal. If all of the temperature sensors 2a to 2c are normal, boiling water is boiled using the temperature sensors 2a to 2c in step ST5. Temperature sensor 2a for detecting the amount of remaining hot water
If there is an abnormality in any one of to 2c, the operation control means 6 causes the display means 10 to display the temperature sensor 2a.
Outputs a display command for displaying that there is an abnormal temperature sensor among the elements 2c to 2c to the display controller 8. Then, in step ST7, the boiling operation is stopped. Since it is extremely rare that an abnormality occurs in the boiling temperature detecting temperature sensor 1 and further an abnormality occurs in the temperature sensors 2a to 2c, even in this case, there is almost no shortage of hot water.

FIG. 5 shows an example of the operation mode in step ST5. In this operation mode, steps ST51 to ST54 are basically the same as steps ST21 to ST24 in FIG. However, since the temperature sensor 1 is abnormal and the water temperature cannot be detected, the calculation of the energization shift time in step ST53 is performed using the assumed water temperature as described above. Through steps ST55 to ST57, the temperature sensors 23a to 23a
The heater 11 is energized until all c reaches the set temperature. When all the temperature sensors 23a to 23c reach the set temperature, the process proceeds to step ST58 and the operation control means 6 outputs an energization stop command to the heater energization control means 9 to turn off the heater 11. Therefore, in this embodiment, 3
The temperature sensors 23a to 23c are used as boiling temperature detecting temperature sensors.

FIG. 6 shows an algorithm of a program used when implementing another embodiment of the present invention. In this embodiment, when the boiling temperature detecting temperature sensor 1 becomes abnormal, the remaining hot water amount detecting temperature sensors 2a to 2c are further detected.
Even if an abnormality occurs in the inside, boiling water is boiled if there is one normal temperature sensor. In order to make this possible, steps ST7 to ST9 are provided. FIG. 7 shows a program algorithm for actually realizing step ST9. Here, a particularly important point is that by providing steps ST94 to ST101, even if any of the temperature sensors 2a to 2c is abnormal, another normal temperature sensor can be used as the temperature sensor for boiling temperature detection. This is the point. With such a configuration, for example, when the temperature sensor 2a is abnormal, when the temperature sensor 2b or the temperature sensor 2c detects the set temperature, the operation control unit 6 outputs an energization stop command to the heater energization control unit 9. Therefore, the boiling water can be boiled without boiling the water to an abnormally high temperature. Temperature sensor 2
When all of a to 2c become abnormal, the process proceeds to step ST7 by the determination in step ST8 of FIG. 6 and the boiling operation is stopped.

[0031]

According to the invention of claim 1, when the sensor abnormality detecting means detects that the boiling temperature detecting temperature sensor is abnormal, the sensor abnormality detecting means determines that the temperature is normal. Since the operation control means outputs an energization stop command based on the output of at least one of the other temperature sensors, when the temperature sensor for boiling temperature detection becomes abnormal, other than the temperature sensor for boiling temperature detection The temperature sensor of can be used as a temperature sensor for detecting the boiling temperature, and the shortage of hot water can be prevented as much as possible. Claim 2
According to the invention, since all of the plurality of remaining hot water amount detection temperature sensors output the energization stop command when the set temperature is detected, at least the position of the remaining hot water amount detection temperature sensor located at the bottom of the hot water storage tank. Until, there is an advantage that you can boil water sufficiently.

According to the third aspect of the present invention, since the boiling water operation can be continued until all the temperature sensors become abnormal, there is an advantage that the occurrence of hot water shortage can be minimized. .

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration of a control unit according to an exemplary embodiment of the present invention.

FIG. 2 is a diagram showing how each temperature sensor is installed in a hot water storage tank.

FIG. 3 is a flowchart showing an algorithm of an example of a program used when implementing an embodiment of the present invention using the configuration of FIG.

FIG. 4 is a flow chart showing details of step ST2 in FIG.

5 is a flowchart showing an example of an operation mode in step ST5 of FIG.

FIG. 6 is a flow chart showing an algorithm of an example of a program used when implementing the other embodiments of the present invention using the configuration of FIG.

7 is a flowchart showing an example of an operation mode in step ST9 of FIG.

[Explanation of symbols]

 1 Boiling Temperature Detection Temperature Sensors 2a to 2c Remaining Hot Water Amount Detection Temperature Sensor 3 A / D Converter 4 Timer Means 5 Sensor Abnormality Detection Means 6 Operation Control Means 7 Storage Means 8 Display Control Means 9 Heater Energization Control Means 10 Display Means 11 heater 13 hot water storage tank

Claims (3)

[Claims] 1. A boiling temperature detecting temperature sensor for detecting a boiling temperature of hot water, a feed water temperature detecting temperature sensor for detecting a feed water temperature, and a plurality of residual hot water amount detecting temperature sensors for detecting a residual hot water amount. And a sensor abnormality detecting means for detecting whether or not the detected temperatures of the plurality of temperature sensors are out of a preset normal temperature detection range to detect an abnormality of the temperature sensor, and an operation control command Heater energization control means for controlling energization to the heater according to the display command, display means for displaying the operation content etc. according to the display command, and boiling water operation based on the output of the sensor abnormality detection means. It is determined whether or not, and the operation control hand that outputs the operation control command to the heater energization control means and outputs the display command to the display means based on the outputs of the plurality of temperature sensors. The operation control means is a hot-water storage electric water heater that outputs an energization stop command for stopping energization of the heater to the heater energization control means when the temperature of the hot water reaches a preset temperature. The control means outputs the energization stop command based on the output of the boiling temperature detecting temperature sensor when the sensor abnormality detecting means detects that the boiling temperature detecting temperature sensor is normal, When the sensor abnormality detecting means detects that the temperature sensor for detecting the boiling temperature is abnormal, the sensor abnormality detecting means determines that the output of at least one of the other temperature sensors is normal. A hot water storage type electric water heater configured to output the energization stop command based on the above. 2. The operation control means, when the sensor abnormality detecting means detects that the boiling temperature detecting temperature sensor is abnormal, all of the plurality of remaining hot water amount detecting temperature sensors are operated. When the set temperature is detected, the energization stop command is output, and when the sensor abnormality detecting means detects that there is an abnormality in the plurality of remaining hot water amount detection temperature sensors, the boiling water operation is stopped. The hot water storage type electric water heater according to claim 1. 3. A boiling temperature detecting temperature sensor for detecting a boiling temperature of hot water, a feed water temperature detecting temperature sensor for detecting a feed water temperature, and a plurality of residual hot water amount detecting temperature sensors for detecting a residual hot water amount. A sensor abnormality detecting means for detecting whether or not the detected temperature of each of the plurality of temperature sensors is out of a preset normal temperature detection range to detect an abnormality of the temperature sensor; An operation control unit that determines whether or not to perform the boiling operation of the hot water based on the output of the detection unit and that generates an operation control command based on the outputs of the plurality of temperature sensors, and according to the operation control command. A hot water storage type electric water heater comprising: heater energization control means for controlling energization of a heater, wherein the operation control means includes a temperature sensor for detecting the boiling temperature and a temperature sensor When the sensor abnormality detecting means detects that at least one is a normal temperature sensor, the boiling water operation is executed based on the output of the normal temperature sensor, and all the temperature sensors are abnormal. The hot water storage type electric water heater is configured to stop the boiling operation of the hot water when the sensor abnormality detecting means detects that