JPH04122320A - Hot water feeder - Google Patents

Abstract

PURPOSE:To obtain a hot water feeder for enabling the transition metal ions such as of iron, manganese, or the like in city water, to be avoided by arranging a hot water storing vessel, and a main body containing the hot water storing vessel and having a hot water feeding port, and by fitting inorganic ion exchanging material in a course for connecting the hot water storing vessel and the hot water feeding port to each other. CONSTITUTION:When water comes to a boiling state, then a temperature detector 21 is worked, and a heater 15 is turned off, and a warming heater only is turned on, and heat is retained. When hot water is fed in this state, then a push button 17 is pushed down, and a starting switch 16 is turned ON, and the button 17 is pushed down further, and the resistance value of a resistor is changed, and a motor 6 is switched on. By operating the motor 6, a pump 7 is worked, and water stored in a hot water storing vessel 2 is sucked from a suction port 8 and is discharged from a discharge port 9. The water discharged from the discharge port 9 passes a discharge pipe 10 and is extracted to an external section from a hot water feeding port 13 via a filter 11 filled up with inorganic ion exchanging material.

Description

DETAILED DESCRIPTION OF THE INVENTION Field of the Invention The present invention relates to a water heater for supplying hot water for drinking in homes, offices, and the like.

Conventional Technology Tap water in recent years contains large amounts of transition metal ions, such as iron and manganese, which are eluted from water pipes. Conventional water heaters do not have a means to remove these transition metal ions. Even using water purifiers could not completely remove these ions contained in tap water.

Problems to be Solved by the Invention Generally speaking, when tea, black tea, coffee, etc. is boiled in hot water containing transition metal ions such as iron or manganese, the taste and aroma of the tea, black tea, and coffee are lost and the color turns black or brown. As mentioned above, conventional water heaters do not have a means to remove these transition metal ions, and even water purifiers cannot completely remove these ions contained in tap water. There wasn't.

The present invention is intended to solve these problems, and its primary purpose is to provide a water heater that can remove transition metal ions such as iron and manganese from tap water. Furthermore, a second object is to provide a water heater that can better achieve the first object.

Means for Solving the Problems A first means of the present invention for achieving the above-mentioned first object comprises: a hot water storage container; a main body accommodating the hot water storage container and having a hot water supply port; This hot water supply device has an inorganic ion exchange material installed in the path connecting the container and the hot water supply opening. A second means of the present invention for achieving the second object includes a hot water storage container having a heater, a pump for pumping water in the hot water storage container ii/i, and a pump for circulating the pumped water. The hot water supply apparatus includes a main body having a circulation path, and an inorganic ion exchange material is installed in the circulation path.

Effect The first means of the present invention is to install an inorganic ion exchange material in the path connecting the hot water storage container and the hot water supply port, and to supply hot water via this inorganic ion exchange material, iron and manganese in the hot water are removed. Transition metal ions such as these are ion-exchanged and replaced with sodium ions, potassium ions, hydrogen ions, etc. As a result, these transition metal ions can be almost completely removed. A second means of the present invention is to provide a circulation path for circulating water in the hot water storage container, and to install an inorganic ion exchange material in this circulation path. Transition metal ions such as iron and manganese can be more effectively ion-exchanged, and the removal rate of these transition metal ions can be further increased.

EXAMPLE Hereinafter, an example of the first means of the present invention will be described based on FIG. 1 is the main body of the water heater (hereinafter simply referred to as the main body),
Internal diameter 150mm and depth 180mm to store water.
It has a hot water storage container 2. Reference numeral 3 denotes an inner stopper attached to seal the mouth of the hot water storage container 2. Reference numeral 4 denotes an upper lid constituting the main body 1, which can be opened and closed. Reference numeral 5 denotes a check valve, one end of which communicates with the atmosphere, and the other end of which passes through the inner stopper 3 and communicates with the inside of the container 2. 6 is a motor provided between the main body 1 and the hot water storage container 2. A pump 7 is driven by a motor 6, and its suction port 8 communicates with the bottom of the hot water storage container 2. 9 is the discharge port of the pump 7, and the discharge pipe 1
0 is connected. Reference numeral 11 denotes a filter packed with an inorganic ion exchange material, and is provided in a path connecting the hot water storage container 2 and the hot water supply port 13. Water is pumped upward through a discharge pipe 10, passes through a filter 11 filled with an inorganic ion exchange material, and is poured into a cup or the like through a hot water supply port 13. Reference numeral 15 denotes a heater, which is attached to the lower side surface of the hot water storage container 2.

Reference numeral 16 denotes a starting switch and a variable resistor for driving the motor 6, which are operated via a rod 18 when a push button 17 is pressed. Reference numeral 19 denotes a compression type spring, and this spring 19 always urges the rod 18 upward. Further, 21 is a temperature detector.

Next, the operation of this embodiment will be explained. When water is stored in the hot water storage container 2 and a switch (not shown) is operated to start energizing the heater 15, the water temperature rises and reaches a boiling state. When the water reaches a boiling state, the temperature detector 21 is activated.
The supply of electricity to the heater 15 is interrupted, and only the heat-retaining heater (not shown) is supplied with electricity to keep it warm. When hot water is to be supplied in this state, the push button 17 is pushed down to turn the start switch 16 to ONL, and the push button 17 is pushed down further to change the resistance value of the resistor and energize the motor 6. The pump 7 is operated by energizing the motor 6, and the water stored in the hot water storage container 2 is sucked in through the suction port 8 and discharged from the discharge port 9. The water discharged from the discharge port 9 is transferred to the discharge pipe 1
The water passes through a filter 11 filled with an inorganic ion exchange material and is extracted to the outside from a hot water supply port 13. Note that the heater 15 can be continuously energized even if the water stored in the hot water storage container 2 has reached a boiling state by pressing a switch (not shown) that continues heating. There is.

Note that the configuration of this embodiment has sufficient effects even when applied to a simple water heater (pot) that does not have a heating means.

Next, experimental results using the apparatus of this example will be explained below. In this experiment, we investigated the removal rate of iron ions for each inorganic ion exchange material used and the color of tea when actually brewed, and further conducted a sensory test. The evaluation criteria for the sensory test is that the tea has excellent taste and aroma.
Those with excellent taste and aroma were rated ○, those with slightly inferior taste and aroma were rated △, and those with bad taste and aroma that were unsuitable for drinking were rated ×. Furthermore, the effect of removing iron ions was measured as follows. First, as a standard test solution, the iron ion concentration of ferric chloride is 1.
ppm, 0.5ppm, 0. 1ppm is prepared, measured using an atomic absorption spectrophotometer, and a calibration curve is prepared. Next, the sample water is passed through an inorganic ion exchange material, and the concentration of iron ions in the water is similarly measured using an atomic absorption spectrophotometer, and the value is determined using the calibration curve. In addition, the evaluation of the color of the tea and the sensory test were carried out after soaking 3 g of tea for 2 minutes in 200 cc of hot water that had passed through an inorganic ion exchange material as described above. As the inorganic ion exchange material, Log having a particle size of 2 to 3 mm was used by filling it in a filter container with a diameter of 2 cm. Moreover, the flow rate of the pump was 50 to 2000 m1/min. The overall evaluation was rated as ◎ for very good, ○ for good, △ for fair, and \ for poor.

The results are shown below.

Table 1゜Effects of inorganic ion exchange materials Notes Types of inorganic ion exchange materials In Table 1, A is pyrobylite, B is talc, C is kaolinite, D is antibolite, E is amethyte, and F is comparative example. The fused silica used as

As is clear from Table 1, inorganic ion exchange material A did not completely remove iron ions and the color of the tea was brown, but iron ion removal was slightly better in inorganic ion exchange material B.

Each of the inorganic ion exchange materials C-D-E has a better ability to remove iron ions, and the color and flavor of the tea is also improved. The removal effect has been recognized, and the color and taste of the tea made from it are also favorable.In addition, various layered clay minerals such as montmorillonite, beidellite, beidellite, illite, and chamosite, or sodium type and
Zeolites such as potassium type are similarly effective in removing iron ions and can be used as inorganic ion exchange materials. These inorganic ion exchange materials have superior heat resistance compared to organic ion exchange materials, and therefore release extremely small amounts of impurities into water. Furthermore, since it has excellent moldability, it is very suitable for use as an ion exchange material in such water heaters. In addition, the fused silica used as a comparative example has no ion exchange ability (as shown in F, no iron ion removal effect was observed, and the color and taste of tea made with it were poor. It has been confirmed using an atomic absorption spectrophotometer that the removed iron ions change into equal amounts of sodium ions, potassium ions, etc. as a result of ion exchange.

Next, an embodiment of the second means of the present invention will be described based on FIG. 2. 1 is the main body of the water heater (hereinafter simply referred to as the main body), which has an inner diameter of 1501 and a depth of 180 mm for storing water.
III11 hot water storage container 2 is provided.

Reference numeral 3 denotes an inner stopper attached to seal the mouth of the hot water storage container 2. Reference numeral 4 denotes an upper lid constituting the main body 1, which is configured to be openable and closable. 5 is a check valve, one end of which communicates with the atmosphere, and the other end of which passes through the inner stopper 3 and communicates with the inside of the container 2.

6 is a motor provided at the bottom between the main body 1 and the hot water storage container 2. Reference numeral 7 denotes a pump driven by the motor 6, whose suction port 8 communicates with the bottom of the container 2, and its discharge port 9.
is connected to the vibrator 10. 12 is a switching valve,
The water pumped up by the operation of the pump 7 is transferred to the circulation vibrator 14.
It is determined whether to follow the circulation route from the water to the hot water storage container 2 again, or to follow the route where the hot water is supplied from the hot water supply port 13 of the main body 1 to a pot or the like. The hot water storage container 2, pump 7, pipe 10, switching valve 12, and circulation pipe 14 constitute a circulation path. In this embodiment, a filter 11 packed with an inorganic ion exchange material is disposed in the circulation path to remove transition metal ions such as iron and manganese from the water. A heater 15 is attached to the lower side surface of the hot water storage container 2. Reference numeral 16 denotes a starting switch and a variable resistor for driving the motor 6, which are operated via a rod 18 when a push button 17 is pressed. Reference numeral 19 denotes a compression type spring, and this spring 19 always urges the rod 18 upward. Reference numeral 20 denotes a changeover valve switch that operates the changeover valve 12, and by operating this changeover valve switch 20, the water path can be freely switched to the circulation path side or the hot water supply port 1 path side. Further, 21 is a temperature detector.

The operation of this embodiment will be explained below. When the water heater is energized, the heater 14 is heated, and the water temperature in the hot water storage container 2 rises. The temperature of the water in the hot water storage container 2 is detected by a temperature detector 20, and when the water temperature reaches a set temperature, the motor 6 is energized and the pump 7 is activated. In this case, by keeping the switching valve 12 open to the circulation path side, the hot water in the container 2 is repeatedly circulated. Each time the circulation is repeated, the hot water in the jar passes through a filter 11 packed with an inorganic ion material. Therefore, according to this embodiment, transition metal ions such as iron and manganese in hot water can be removed more effectively than when filtration is performed only once, as in the first embodiment. It is possible. In this case, some circulating noise is generated as the hot water circulates, but this circulating sound is drowned out by the boiling sound when the water temperature is set to about 80° C., for example. In other words, by setting the temperature near the boiling point of water, the sound of circulating hot water can be drowned out.

Experimental results using this example will be explained below.

This experiment was conducted under the same conditions and in the same manner as the experiment using the apparatus of the first embodiment described above. Table 2 shows the results of this experiment.

Remarks Type of inorganic ion exchange material A: AI (OH) Si OB: Mg (OH)
Si0C:Al(OH)SiOD:M
g (OH)Si 0 In Table 2, A is pyrophyllite, B is talc, C is kaolinite, D is antibolite, E is amesite, and F is fused silica.

As is clear from Table 2, each ion exchange material has a higher iron ion removal effect than the iron ion removal effect in Example 1 (see Table 1), and the hot water is circulated within the water heater. It seems that iron ions were almost completely removed by repeatedly passing through an inorganic ion exchange material filter. Also, the color and taste of the tea made were even more preferable than that of Example 1. In addition, layered clay minerals such as montmorillonite, beidellite, beidellite, illite, and chamosite, as well as zeolites such as sodium and potassium types, are also effective in removing iron ions, and are used as inorganic ion exchange materials. In addition, for comparison, data on fused silica without ion exchange ability was shown in F, but no iron ion removal effect was observed, and as a result, the color and taste of the tea produced were poor. In addition, it was confirmed using an atomic absorption spectrophotometer that iron ions were ion-exchanged and that equal amounts of sodium and potassium ions were eluted into the water.

Effects of the Invention As is clear from the above embodiments, according to the first means of the present invention, the hot water storage container includes a hot water storage container having a heater, and a main body that accommodates the hot water storage container and has a hot water supply port. Transition metal ions such as iron and manganese in tap water can be removed by using a water heater with an inorganic ion exchange material installed in the path connecting the water supply container and the hot water supply opening. According to a second aspect of the present invention, a main body includes a hot water storage container having a heater, a pump for pumping the water in the hot water storage container and the container, and a circulation path for circulating the pumped water. The water heater is equipped with an inorganic ion exchange material in the circulation path, and achieves the effect of the first means more reliably.

[Brief explanation of drawings]

FIG. 1 is a longitudinal cross-sectional view of a water heater showing an embodiment of the first means of the present invention, and FIG. 2 is a longitudinal cross-sectional view of a water heater showing an embodiment of the second means of the present invention. 1...Main body, 2...Hot water storage container, 7...Pump,
11... Inorganic ion exchange material, 12... Switching valve,
13...Hot water inlet, 14...Circulation route pipe, 15
···heater.

Claims (2)

[Claims] (1) A hot water supply device comprising a hot water storage container and a main body that accommodates the hot water storage container and has a hot water supply port, and in which an inorganic ion exchange material is attached in a path connecting the hot water storage container and the hot water supply port. (2) A main body comprising a hot water storage container having a heater, a pump for pumping water in the hot water storage container, and a circulation path for circulating the pumped water, and an inorganic ion exchange material is provided in the circulation path. Installed water heater.