JP2000213040A - Hot water tank device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent heating of an empty hot water tank due to erroneous detection of a tank full water condition due to freezing of a float switch. SOLUTION: This is a hot water tank device in which an empty tank heating prevention mode for preventing operation while a tank is empty when a water level in the hot water tank 1 does not reach a fixed level is set. In this case, the empty tank heating prevention mode is constituted in such a way that water supply into the hot water tank 1 is started when a float switch 2 is OFF through an initial operation mode for conducting electricity to a heater 3 for a predetermined period of time irrespective of ON and OFF conditions of the float switch 2 when a power supply of the device is turned on and operation moves to a normal operation mode in which electricity is conducted to the heater 3 when the float switch 2 is ON to control water temperature to a predetermined temperature.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a hot water tank device provided with a float switch for detecting a water level in a hot water tank, and more particularly, to a technique for preventing empty heating due to erroneous detection of tank fullness due to freezing of a float switch. It is.

[0002]

2. Description of the Related Art Conventionally, as a hot water tank device used for a local cleaning device or the like, for example, as shown in FIG. 5, a hot water tank 1, a heater 3 for turning the water in the hot water tank 1 into hot water, a hot water tank Float switch 2 (FIG. 6) for detecting the water level in 1 and supplying water to hot water tank 1 to raise the water level to a certain level or more when the water level is below a certain level.
And those with 5, 10 is a water supply port, 11 is a solenoid valve, 12 is a pump, and 13 is a hot water tank 1.
This is the nozzle from which the washing water is discharged.

FIG. 6 shows an example of the structure of the float switch 2. Normally, when the water level in the hot water tank 1 is equal to or lower than a certain level (including an empty state), a float 21 made of foamed polyethylene which moves up and down with the water level in which the magnet 20 is stored is located below. At this time, the magnet 20 is also lowered, and the reed switch 22 is in the OFF state. Thereafter, when water is supplied into the hot water tank 1 and the water level L rises to a certain level, the float 21 rises, and the magnet 20 rises at the same time. When a certain sensitivity point is reached, the reed switch 22 is turned on by the magnetic force of the magnet 20. . By utilizing this, the water level in the hot water tank 1 is detected. In FIG. 6, 23 is a lead wire, 24 is a contact,
25 is a stopper for the float 21.

FIG. 7 shows an example of a control flow from the initial state when the power of the conventional apparatus is turned on. Conventionally, the float switch 2 is used when starting to use the hot water tank device.
Is ON or OFF. If it is ON, hot water tank 1
Determines that the water is full, and turns on the heater 3. When the float switch 2 is OFF, the heater 3 is not turned ON,
A water supply display is performed, and the heater 3 is not turned on until water is supplied, thereby preventing the hot water tank 1 from being operated in an empty state.

[0005]

However, in a conventional apparatus provided with a float switch 2 for detecting a water level in a hot water tank 1, the apparatus is not turned on and the float switch 2 is kept on. If the surroundings are left in a cold state, the float switch 2 freezes with the ON state, so that the float switch 2 does not operate normally. In this case, the float switch 2 is ON even when the hot water tank 1 is empty or when the water level is below a certain level.
There is a problem that the inside of the hot water tank 1 is determined to be full and the energization to the heater 3 is started, and the hot water tank 1 becomes empty. Here, the case where the power of the apparatus is not turned on means, for example, the case where the product is transported from the factory to the construction site, or the case where the power is turned off and the hot water tank 1 is not used for a long time in order to leave the trip, etc. Indicates a power outage.

The present invention has been made in view of the above points, and an object of the present invention is to provide a hot water tank device capable of preventing empty heating due to erroneous detection of tank fullness due to freezing of a float switch. is there.

[0007]

SUMMARY OF THE INVENTION In order to solve the above-mentioned problems, the present invention provides a hot water tank 1, a heater 3 for heating water in the hot water tank 1, and a water level in the hot water tank 1. Hot water tank 1 when water level is below a certain level
In a hot water tank device provided with a float switch 2 for supplying water into the inside and maintaining the water level at a certain level or more,
When the water level in the hot water tank 1 is lower than a certain level, an air-fire prevention mode for preventing the air-fired operation is set. The air-fire prevention mode is an ON / OFF state of the float switch 2 when the apparatus is powered on. Irrespective of this, after the initial operation mode for energizing the heater 3 for a predetermined time, the water supply into the hot water tank 1 is started when the float switch 2 is in the OFF state, and the heater 3 is turned on when the float switch 2 is in the ON state. To a normal operation mode in which the water temperature is controlled to a predetermined temperature by supplying power to the apparatus. With this configuration, the power of the apparatus is not turned on and the float switch is not turned on. 2 is ON
When the power of the apparatus is turned on from a state where the periphery of the apparatus is left in a cold state in the state, the power supply to the heater 3 is started without immediately detecting the water level by the float switch 2, and the float switch is turned on. In this case, it is possible to prevent empty heating due to erroneous detection of tank fullness due to the freezing of the apparatus 2 and also prevent failure of the apparatus.

It is preferable that the power supply rate to the heater 3 in the initial operation mode is lower than the power supply rate to the heater 3 in the normal operation mode. When the float switch 2 is started to be warmed to be frozen, it is possible to prevent the apparatus from being broken down by the heat of the heater before the float switch 2 becomes normal, and also possible to prevent empty heating.

The hot water tank 1 in the initial operation mode
It is preferable to include a detecting means 4 for detecting the temperature in the inside and stopping the energization of the heater 3 when the temperature becomes equal to or higher than a predetermined temperature. It can be reliably prevented.

[0010]

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, an embodiment of the present invention will be described. As shown in FIG. 1, a hot water tank device includes a hot water tank 1 and a sheathed heater 3 for heating (hereinafter referred to as "heater").
That. And a float switch 2 for detecting the water level in the hot water tank 1 and supplying water to the hot water tank 1 when the water level is below a certain level to maintain the water level at or above a certain level. A control unit (not shown) for preventing empty heating is provided. The structure of the float switch 2 is the same as that of the conventional example (FIG. 6), and the detailed description is omitted. The heater 3 is arranged so as to face a position near the bottom surface in the hot water tank 1.

In the control unit for preventing the idling, the idling mode is set to prevent the idling operation when the water level in the hot water tank 1 is below a certain level.
This empty-fire prevention mode is performed when the float switch 2 is in the OFF state through an initial operation mode for performing power supply to the heater 3 for a predetermined time regardless of the ON / OFF state of the float switch 2 when the apparatus is turned on. Water supply into the hot water tank 1 is started, and when the float switch 2 is in the ON state, the heater 3 is energized to shift to a normal operation mode in which the water temperature is controlled to a predetermined temperature.

Further, in the hot water tank 1, there is provided a detecting means 4 for detecting the temperature of the hot water in the initial operation mode and stopping the energization of the heater 3 when the temperature reaches a predetermined temperature or higher. In this example, a thermistor 4a is used as the detection means 4. The thermistor 4a is disposed near the heater 3, and measures the temperature change of the hot water in the hot water tank 1 when the power to the heater 3 is started with the float switch 2 being ON.

FIG. 2 shows an example of a control flow after the power of the apparatus is turned on. When the power of the apparatus is turned on, the apparatus enters an initial operation mode. First, a heater energization timer is started, and energization of the heater 3 is performed for a predetermined time. During this time, the float switch 2 is warmed to be frozen. When the hot water tank 1 contains washing water, the temperature of the washing water is increased by the heater 3 and the float switch 2 is heated by the hot water. When the hot water tank 1 is empty, the float switch 2 is activated by the radiant heat of the heater 3. Warmed up. Then, the state where the float switch 2 can be normally operated is shifted to the normal operation mode. Here, the state of the float switch 2 is detected while the heater energization timer is counting, and the frozen state is melted and the float switch 2 is turned off.
Is reached, it is determined that the hot water tank 1 is not full, and the power supply to the heater 3 is stopped to display the initial water supply. The initial water supply display indicates a state in which the hot water tank 1 is not full and water is supplied by operating a switch for opening a water supply valve. If the state of the float switch 2 remains ON during the counting of the heater energization timer, it is determined that the hot water tank 1 is full, the energization of the heater 3 is performed as it is, and the water temperature reaches a predetermined temperature. Normal control is performed as described above.

When the float switch 2 is frozen, when the power of the apparatus is turned on, the water level is not immediately detected by the float switch 2 but the heater 3 is turned on.
, The float switch 2 can be melted from a frozen state and returned to a normal operation. Therefore, it is possible to prevent empty heating due to erroneous detection of tank fullness, and also to prevent the device from malfunctioning at the same time.

A thermistor 4a is provided in the hot water tank 1, and when the heater 3 is energized with the float switch 2 turned on in the initial operation mode, the temperature change of the hot water tank 1 is detected by the thermistor 4a. 4a, the failure of the device can be prevented. In particular, when the hot water tank 1 is empty, the hot water tank 1
The temperature change in the inside is higher in the empty case (T _{1 in} FIG. 4) than the temperature change in the full state (T _{2 in} FIG. 4). T ₃ ) is set, and when the temperature in the hot water tank 1 exceeds this upper limit value (T ₁ > T ₃ ), the power supply to the heater 3 is stopped. When the power supply to the heater 3 is stopped, the temperature in the hot water tank 1 decreases, and when the temperature falls below the lower limit (T ₁ <T ₃ ), the power supply to the heater 3 is performed. However, if the float switch 2 is ON during a predetermined time, the hot water tank 1 is determined to be full and normal processing is performed. If the float switch 2 is OFF during the predetermined time, the heater 3 is immediately turned off. To OFF to display the initial water supply.

In the initial operation mode,
It is preferable that the power supply rate to the heater 3 be lower than the power supply rate to the heater 3 in the normal operation mode. Incidentally, in the initial operation mode, when the power supply to the heater 3 is started to warm the float switch 2 from being frozen, the power supply rate to the heater 3 at this time is set to be the same as the power supply rate to the normal heater 3. Then, before the frozen state of the float switch 2 is melted, the apparatus may be broken down due to abnormal heating.
Therefore, from the time when the power of the apparatus is turned on until the time set by the heater energization timer elapses, 10 in FIG.
For example, as shown in FIG.
By performing the energization, it is possible to prevent the device from breaking down before the float switch 2 becomes normal, and it is also possible to prevent empty heating, thereby improving safety.

[0017]

As described above, according to the first aspect of the present invention, a hot water tank, a heater for heating water in the hot water tank, a water level in the hot water tank are detected, and the water level is kept constant. When the water level in the hot water tank is less than a certain level, dry-heating operation is prevented when the water level in the hot water tank is lower than a certain level. The mode is set to turn on the float switch when the power is turned on.
・ After the initial operation mode for energizing the heater for a predetermined time regardless of the OFF state, the float switch
Water supply into the hot water tank is started in the FF state, and when the float switch is in the ON state, the heater is energized to control the water temperature to shift to a normal operation mode in which the water temperature is controlled to a predetermined temperature. When the power of the apparatus is turned on from a state in which the power of the apparatus is not turned on and the surroundings of the apparatus are left in a cold state while the float switch is in the ON state, the water level detection by the float switch is not immediately performed. In addition, by starting energization of the heater, it is possible to prevent empty heating due to erroneous detection of tank fullness due to freezing of the float switch, and also to prevent failure of the apparatus.

According to a second aspect of the present invention, in addition to the effect of the first aspect, the duty ratio of the heater in the initial operation mode is made lower than the duty ratio of the heater in the normal operation mode. When the power of the float switch is frozen by starting to supply power to the float switch, it is possible to prevent the device from malfunctioning due to the heat of the heater before the float switch becomes normal, and at the same time, to prevent empty heating, Performance can be improved.

According to a third aspect of the present invention, in addition to the effect of the first aspect, the temperature in the hot water tank in the initial operation mode is detected, and the power supply to the heater is stopped when the temperature reaches a predetermined temperature or higher. Since the detection means is provided, it is more effective to prevent failure due to abnormal heating of the apparatus.

[Brief description of the drawings]

FIG. 1 is a sectional view of an example of an embodiment of the present invention.

FIG. 2 is a flowchart of a control unit according to the first embodiment.

FIG. 3A is a pulse waveform diagram when 100% current is applied;
(B) is a pulse waveform diagram at the time of 50% energization.

FIG. 4 is a graph showing a relationship between the heater temperature when the fuel tank is empty and the heater temperature when the fuel tank is full.

FIG. 5 is a block diagram when a hot water tank is used for a local cleaning device.

FIG. 6A is a partially cutaway side view of a float switch,
(B) is a bottom view.

FIG. 7 is a flowchart of a conventional control unit.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Hot water tank 2 Float switch 3 Heater 4 Detecting means

Claims (3)

[Claims] 1. A hot water tank, a heater for heating water in the hot water tank, and a water level in the hot water tank are detected, and when the water level is below a certain level, water is supplied into the hot water tank and the water level is adjusted to a certain level. In the hot water tank device provided with a float switch for maintaining the above, an empty fire prevention mode is set to prevent an empty fire operation when the water level in the hot water tank is less than a certain level, and this empty fire prevention mode is set. Starts the water supply into the hot water tank when the float switch is in the OFF state after the initial operation mode for energizing the heater for a predetermined time regardless of the ON / OFF state of the float switch when the device is turned on. When the float switch is in the ON state, the heater is energized to shift to a normal operation mode in which the water temperature is controlled to a predetermined temperature. A hot water tank device characterized by that: 2. The hot water tank device according to claim 1, wherein the duty ratio of the heater in the initial operation mode is lower than the duty ratio of the heater in the normal operation mode. 3. The apparatus according to claim 1, further comprising a detection unit configured to detect a temperature in the hot water tank during the initial operation mode, and to stop energizing the heater when the temperature reaches a predetermined temperature or higher. Hot water tank device.