JPH08206000A - Liquid heat insulating vessel with water cleaning function - Google Patents

Abstract

PURPOSE: To enable exchange only at desired timing by providing a liquid heat insulating vessel having a water cleaning function with an exchange timing judging means for judging the exchange timing of a water cleaning filter and an alarming means for alarming the exchange timing of the water cleaning filter based on the judgement of the exchange timing judging means. CONSTITUTION: Water cleaning time PT is measured. However, this water cleaning time PT is not directly measured but hot-water boiling time, namely, time for energizing to a heater 3 for hot-water boiling is measured. Thus, even when the time for energizing to the heater 3 for hot-water boiling is measured, water in an inner vessel 2 is circulated from a water-raising pipe 5 and a water cleaning pipe 7 through a water cleaning filter 9 by a water-raising pump 6 during the hot-water boiling time and the hot-water boiling time is decided corresponding to the quantity of water in the inner vessel 2 so that the water cleaning time PT can be measured as a result. The measured water cleaning time PT is added to previous use time FT of the water cleaning filter 9. It is judged whether the total value of the water cleaning time PT exceeds a set value G or not. The set value G is previously decided numerical value to require the exchange of the filter 9.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a liquid heat insulation container with a water purifying function such as an electric pot and a coffee maker.

[0002]

2. Description of the Related Art Conventionally, a liquid heat insulation container such as an electric pot is provided with a water purification filter in a circulation path for circulating the liquid in the inner container while boiling water, as described in JP-A-4-22310. Alternatively, there is one in which a water purification filter is provided in the discharge passage.

In such a liquid heat insulating container with a water purifying function, the period of use of the water purifying filter is determined by the manufacturer assuming the general condition of use, and the user needs to remember the replacement time. is there. However, the usage period is usually as long as about one year, and it is often forgotten to replace it. For this reason, it is generally practiced to attach a sticker or the like on the main body in which the start time of use is entered.

[0004]

However, the water purifying function of the water purifying filter depends on the frequency of use. Therefore, if the period of use is uniformly determined as described above, the problem that the water purification filter is replaced before the water purification function is lost, or conversely, it is not replaced even though the water purification function is already lost Occurs.

In view of the above problems, it is an object of the present invention to provide a liquid heat retaining container with a water purifying function, which appropriately detects and notifies the replacement time of the water purifying filter.

[0006]

In order to achieve the above-mentioned object, the present invention provides a liquid heat retaining container with a water purifying function, wherein water in an inner container is made to flow and purified by a water purifying filter.
There are provided a replacement timing determining means for determining the replacement timing of the water purification filter, and a notifying means for reporting the replacement timing of the water purification filter based on the determination by the replacement timing determination means.

The replacement time determining means determines the replacement time of the water purification filter by comparing the measured value of the amount of water passing through the water purification filter with a set value determined based on the amount of passing water corresponding to the replacement time of the water purification filter. It should be done. In this case, the amount of water passing through the water purification filter may be measured based on the number of circulations of water in the inner container, the cumulative circulation time, the number of boiling waters, the cumulative boiling time, or the like.

Further, the notifying means may be constituted by a display means for turning on or off an LED or a voice means such as a buzzer. In particular, it is preferable to display the remaining life of the water purification filter on a display means such as a display panel. In this case, a value obtained by subtracting the usage time from the set value may be displayed as the remaining life of the water purification filter.

[0009]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Next, embodiments of the present invention will be described with reference to the accompanying drawings.

FIG. 1 shows a liquid heat retaining container with a water purifying function according to the present invention, in which a container body 1 contains an inner container 2.

A heater 3 for boiling water and a heater 4 for keeping heat are provided below the inner container 2. Also, the inner container 2
The lower part of the container and the spout 1a of the container body 1 are connected by a pumping pipe 5. A pumping pump 6 is provided near the lower surface of the inner container 2 in the middle of the pumping pipe 5.

A water purification pipe 7 is connected to the upper side of the pumping pipe 5 so as to branch to communicate with the inside of the inner container 2, and a flow path changing valve 8 is provided at this branch point. Flow path change valve 8
Normally opens on the side of the water purification pipe 7 so that the water in the inner container 2 passes through the water purification pipe 7 from the pumping pipe 5 and circulates again in the inner container 2. And spout 1 only when pumping water
Hot water can be discharged to the outside by switching to the a side. Further, a water purifying filter 9 is provided at the tip of the water purifying pipe 7 so as to be replaceable.

A filter replacement indicator lamp (LED) 10 and a reset switch 11 are provided on the upper part of the container body 1, and a microcomputer 12 is incorporated inside thereof.

FIG. 2 is a control circuit diagram of the liquid heat retaining container with the water purifying function by the microcomputer 12.

In the figure, the heater 3 for boiling water is a relay R.
It is connected to the power supply 13 via y. The relay Ry is connected to a central processing unit (hereinafter, referred to as CPU) 15 of the microcomputer 12 via a relay drive circuit 14.
The contact is opened and closed by the operation signal from the CPU 15.

The heat retaining heater 4 is connected to the power source 13 via a triac Tc. The triac Tc is connected to the CP via the resistor R ₁ and the triac drive circuit 16.
It is connected to U15. When the operation signal issued from the CPU 15 is input to the triac Tc via the triac drive circuit 16, the heat retention heater 4 is heated.

The voltage stabilizing circuit includes capacitors C ₁ , C ₂ ,
Transistor Tr, resistor R ₂ and Zener diode Z
The power source 1 which is composed of D and is connected via a power transformer PT.
Connected to 3. The voltage stabilizing circuit is connected to the backup power source 17 and V _DD and V _SS of the CPU 15, respectively.

The LED 10 and the reset switch 11 are connected to the input / output ports of the CPU 15, respectively.
Further, the motor drive circuit 18 is connected to the output port of the CPU 15.
A pump driving pump driving motor 19 is connected to the pumping pump 6 by rotating the motor 19.
Is designed to drive.

In the liquid heat retaining container having the above-mentioned structure, the flow passage changing valve 8 is normally switched to the water purification pipe 7 side, and when boiling water, the water heater 3 and the heat retaining heater 4 are energized, and the water pump 6 is turned on. It is driving. By driving the water pump 6, the water in the inner container 2 passes from the water pump 5 through the water purification pipe 7 and returns to the inner container 2 for circulation, and passes through the water purification filter 9 of the water purification pipe 7 during circulation. Be purified. When the water in the inner container 2 boils, the energization of the boiling water heater 3 and the heat retention heater 4 is cut off. After that, the heater 4 for heat retention
Is energized each time the water temperature in the inner container 2 drops below a predetermined temperature, whereby the water temperature is maintained constant. here,
When a switch (not shown) is turned on, the flow path changing valve 8 is switched to the spout 1a side, and the pumping pump 6 is driven so that the hot water in the inner container 2 is discharged from the spout 1a through the pumping pipe 5. It is discharged to the outside.

Further, in this liquid heat insulation container, the replacement time of the water purifying filter 9 is detected and notified by the microcomputer 12 having a replacement time determination means.

The operation will be specifically described below with reference to the flowchart of FIG.

In step S1, the water purification time (P _T ) is measured. However, this water purification time (P _T ) is not directly measured, but the boiling time, that is, the energization time to the boiling heater 3 is measured. As described above, even when the energization time to the water heater 3 is measured, the water in the inner container 2 is circulated from the water pump 5 and the water purification pipe 7 through the water purification filter 9 by the water pump 6 during the water boiling time. Since the boiling time is determined according to the amount of water in the inner container 2, as a result, the water purification time (P _T ) can be measured.

In step S2, the water purification time (P _T ) measured in step S1 is added to the previous usage time (F _T ) of the water purification filter 9. Then, in step S3, it is determined whether the usage time (F _T ) of the water purification filter 9, that is, the total value of the water purification time (P _T ) exceeds the set value (G). This set value (G) is set in advance as to how much the total amount of water passing through the water purifying filter 9 estimated from the use time (F _T ) should be changed. is there.

Specifically, this set value (G) is determined as follows. That is, if the heater energization time required to boil 2.2 liters of water is 15 minutes,
6.28 minutes are considered necessary. On the other hand, it has been proved from the experimental result that the water purifying filter 9 loses its water purifying function by passing about 3000 l of water. Therefore, the set value (G) should be 6.82 × 3000 = 20460 (minutes).

Then, in step S3, the operating time (F _T )
If the value exceeds the set value (G), the LED is turned on in step S4.
10 is blinked to instruct the replacement of the water purification filter 9, and the LED 10 is not blinked unless the water purification filter 9 is exceeded.

In step S5, the reset switch 11
Whether or not the water purification filter 9 has been replaced is determined depending on whether or not the switch has been turned on. If it has been replaced, the operating time (F _T ) is reset (F _T = 0) in step S6, and if it has not been replaced, the above steps are repeated. However, instead of the reset switch 11, detection may be performed by a micro switch, a sensor, or the like, and a plurality of switches may be simultaneously pressed to reset so as not to be erroneously operated.

In step S1, the time for energizing the heater 3 for boiling water is measured as the cleaning time, but the pumping pump 6 is operated only while the water temperature in the inner container 2 rises from 40 ° C to 90 ° C, for example. In the case of driving, it is preferable to measure this time as the water purification time.

In step S3, the operating time (F
Although _T) was made to determine the replacement timing of the water purification filter 9 on whether exceeds said set period (G), by subtracting the set time in step S2 (G) from the use time (F _T), in step S3 You may make it determine whether the value is 0.

In the above embodiment, the replacement time of the water purifying filter 9 is estimated from the boiling time, but usually, the boiling is performed after the inner container 2 is filled with water.
You may make it guess by the number of boiling water. According to this, the water purification time (P _T ) can be known from the number of boiling water, and a value that estimates the amount of water passing through the water purification filter 9 can be calculated.
It is possible to estimate the replacement time.

The replacement time of the water purification filter 9 may be estimated from the operating time of the pumping pump 6. In this case, the error is reduced when the operating time of the water pump 6 at the time of boiling water without turning on the discharge switch is the water purification time. That is, at the time of boiling water, the water in the inner container 2 is pumped by the pump 6.
This is because it is circulated in the container body 1 by the drive of and passes through the water purifying filter 9 without fail. Further, in the same manner as the case of the number of times of boiling water, considering that boiling water is usually performed with the inside of the inner container 2 being filled with water, the replacement time of the water purification filter 9 should be estimated by the number of times the pump pump 6 is operated during boiling water. Is also possible.

As shown in FIG. 4, in the liquid heat insulation container having a structure in which the water in the inner container 2 does not circulate in the container body 1, because the water purification filter 9 is provided in the middle of the pump pipe 5, The value obtained by measuring the amount of passing water is estimated based on the operating time or the number of times the pumping pump 6 is operated, but may be estimated based on the boiling time or the number of boiling times as necessary. This is because the amount of water in the inner container 2 can be estimated by the boiling time and the number of boiling times.

Instead of blinking the LED 10, the LED 10 may be simply turned on or may be notified by a sound such as a buzzer, and the informing means is not limited to the above. Further, the notification means may display the remaining life of the water filter 9, but in this case, the microcomputer 12 needs to calculate the remaining life of the water filter 9. That is, by converting the value obtained by subtracting using time (F _T) from the set value (G) to the remaining life of the water purification filter 9 must be made to display that value in informing means such as a display panel.

[0033]

As is apparent from the above description, the liquid heat retaining container with a water purifying function according to the present invention directly
Alternatively, the number of circulation of water in the inner container, cumulative circulation time,
The total amount of water that passes through the water purification filter is indirectly calculated from the number of boiling water, the cumulative time of boiling water, the number of times the pump is operated, the operating time, etc., so that the user can be notified when the water purification filter needs to be replaced. It can be replaced at the most preferable time without being bothered. Therefore, the water purification filter may be replaced before the water purification function is lost, resulting in unnecessary expense for the user, or even after the water purification function is lost, poor water purification or reverse pollution may occur. You can avoid that.

Further, since the remaining life of the water purification filter is displayed, it is possible to clearly judge the replacement time of the water purification filter, and it is possible to take prompt and appropriate measures such as preparing a spare water purification filter in advance. is there.

[Brief description of drawings]

FIG. 1 is a schematic view of a liquid heat insulation container with a water purifying function according to the present embodiment.

FIG. 2 is a control circuit diagram of the CPU shown in FIG.

FIG. 3 is a flowchart of a control operation in the CPU shown in FIG.

FIG. 4 is a schematic view of a liquid heat insulation container with a water purifying function according to another embodiment.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Container main body, 2 ... Inner container, 6 ... Pumping pump, 7 ... Water purification pipe, 9 ... Water purification filter, 10 ... LED, 12 ... Microcomputer.

Claims (6)

[Claims] 1. A liquid heat retaining container with a water purifying function in which water in an inner container is made to flow to be purified by a water purifying filter, and a replacement timing judging means for judging replacement timing of the water purifying filter, and the replacement timing judging means. A liquid heat retaining container with a water purifying function, characterized by being provided with an informing means for informing the user of the replacement time of the water purifying filter based on the above judgment. 2. The replacement time determination unit compares the measured value of the amount of water passing through the water purification filter with a set value determined based on the amount of water passing through the water purification filter at the time of replacement of the water purification filter. The liquid heat insulation container with a water purifying function according to claim 1, wherein 3. The replacement time determining means measures the amount of water passing through the water purification filter based on the number of times of circulation of water in the inner container or the cumulative time of circulation. Liquid heat insulation container with water purification function. 4. The replacement timing determining means measures the amount of water passing through the water purification filter based on the number of times of boiling water or the cumulative time of boiling water.
Liquid heat insulation container with water purification function described in. 5. The water in the inner container is made to flow by a pump, and the replacement timing determining means measures the amount of water passing through the water purification filter based on the operating time or the number of operations of the pump. The liquid heat insulation container with a water purification function according to claim 2. 6. The replacement time determination means determines the remaining life of the water purification filter based on a measured value of the amount of water passing through the water purification filter and a set value determined based on the amount of water passing through corresponding to the time of replacement of the water purification filter. 6. The liquid insulation with water purification function according to any one of claims 1 to 5, wherein the notification means displays the remaining life of the water purification filter calculated by the replacement timing determination means. container.