KR20190121528A - Water purifier having differential heater and method of controlling the heater - Google Patents

Abstract

The present invention provides a water purifier having a differential heater and a control method thereof, which are possible to innovatively reduce electricity reaching hot water of high temperature and take the initial hot water of the high temperature. The apparatus includes a heater unit having a first heater embedded in a hot water tank in which an inner cylindrical cover, a lower cover and an inner cylinder are sealed and continuously heating raw water or purified water stored in the hot water tank with first electricity and a second heater heated by second electricity only when the raw water or the purified water is discharged, wherein the second electricity is higher than the first electricity.

Description

Water purifier having differential heater and method of controlling the same

The present invention relates to a water purifying apparatus, and more particularly, to a water purifying apparatus having a differential heater which is employed in water purifying apparatuses such as a water purifier, a cold / hot water purifier, a refrigerator, and which can adjust the temperature of hot water differentially, and a method of controlling the heater. .

Water purifier is a device that converts safe and sanitary drinking water by filtering various harmful ingredients harmful to human body contained in raw water such as tap water and ground water by filter, filter material and the like. Water purifiers are representative of water purifiers such as cold and hot water machines, and water purifiers are divided into hot water tanks and direct water tanks, depending on whether the water purifier has a water tank. The direct type water purifier does not have a water tank, and immediately filters the raw water to provide purified water when the user operates the water outlet. Direct type water purifiers are more hygienic and water-saving than water tank type water purifiers, and in recent years, preference for direct type water purifiers has been increasing. Such a direct type water purifier is disclosed in detail in Korean Patent No. 10-1409894. Direct water purifiers have adopted a method of making hot water instantaneously by a heater.

Conventional direct type water purifiers provide high-temperature drinking water in a manner of instantaneous heating by a heater 51, as in Korean Patent Application Publication No. 2017-0092076. By the way, the conventional heating method requires a relatively very high power, approximately 2,500W ~ 2,800W. Since the electric power causes an overload of indoor wiring and causes power interruption or instability, it is difficult to handle in a general home or office. In order to compensate for this, power cords and lead wires constituting the water purifier must be strengthened. However, even with the strengthening, the problem due to the high power is not fundamentally solved.

In addition, in the conventional heating method, the initial hot water discharged initially due to latent heat of water does not reach a desired high temperature (about 80 ° C). Initial hot water is an integer of a temperature lower than the high temperature (eg 50 ° C.). Thus, the user discards the initial hot water and takes hot water after the initial time at which the desired high temperature is reached. This heating method is a waste of water and power. Accordingly, there is a demand for a heating method in which the initial hot water also has a desired high temperature.

SUMMARY OF THE INVENTION The present invention has been made in an effort to provide a water purifier having a differential heater and a control method thereof, which can drastically reduce electric power leading to high temperature hot water and take initial hot water at high temperature.

Water purifier having a differential heater for solving the problem of the present invention is connected to the hot water tank and the hot water tank for heating the raw water or purified water, and receiving the filtered raw water heated from the hot water tank to generate purified water or the hot water tank And a filter for filtering the raw water to supply the purified water to generate the purified water. At this time, the hot water tank is built in a hot water tank formed by sealing the inner cylinder cover, the lower cover and the inner cylinder, and the primary heater and the raw water or purified water continuously to heat the raw water or purified water stored in the hot water tank to be discharged. And a heater section having a secondary heater that is heated only when secondary power, wherein the secondary power is higher than the primary power.

In the apparatus of the present invention, the primary heater and the secondary heater have a height difference H, and the size of the secondary heater is larger than the primary heater. The primary heater may be located inside the secondary heater. The primary heater and the secondary heater may be arranged in a cross shape in plan view without contacting each other. The primary heater and the secondary heater may be U-shaped. The secondary heater may be convexly rounded in the direction of the outlet pipe from which the raw water or the purified water is discharged. The hot water tank may include a temperature sensor for adjusting the amount of power applied to the secondary heater.

In the preferred apparatus of the present invention, there may be a cumulative space of the interval (D) between the end of the discharge pipe extending and protruding into the hot water tank and the end of the air discharge pipe communicating with the inside of the hot water tank. The air discharge pipe may be connected to a pressure reducing valve. The inner cylinder is wrapped by a heat insulating material, a space is provided between the inner cylinder and the heat insulating material, the space may be vacuumed.

Differential heater control method of the water purifying device having a differential heater for solving the other problem of the present invention, first, the inner cylinder cover, the lower cover and the inner cylinder is built in a hot water tank is sealed, the raw water or purified water stored in the hot water tank Continue heating to the primary power of the heater. Thereafter, when the user presses the water exit button, the secondary heater is turned on with the secondary power larger than the primary power and the first heater is turned off. When the water extraction by the water extraction button is completed, the secondary heater is turned off and the primary heater is turned on.

In the method of the present invention, the secondary heater may be maintained in an ON state at the time of recognition or time delay.

According to the water purifying device having the differential heater and the control method of the present invention, by applying the differential heater to the hot water tank, it is possible to drastically reduce the electric power leading to the high temperature hot water and take the initial high temperature hot water.

1 is a block diagram schematically showing a water purifier according to the present invention.
2 is an exploded perspective view showing a hot water tank according to the present invention.
3 is a perspective view showing a hot water tank according to the present invention.
4 is a cross-sectional view taken along line IV-IV of FIG. 3.
5 is a cross-sectional view taken along the line VV of FIG. 3.
FIG. 6 is a cross-sectional view taken along line VI-VI of FIG. 3.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. The embodiments described below may be modified in various other forms, and the scope of the present invention is not limited to the embodiments described below. The embodiments of the present invention are provided to more completely explain the present invention to those skilled in the art. On the other hand, terms indicating the location, such as top, bottom, front, etc., are only related to those shown in the drawings. In practice, the water purifier can be used in any optional direction, and in actual use the spatial direction changes with the direction and rotation of the water purifier.

An embodiment of the present invention by applying a differential heater to the hot water tank, to reduce the power leading to high temperature hot water dramatically, and to provide an excitation purifier and a control method that can take the initial high temperature hot water. To this end, the water purifying apparatus to which the differential heater is applied will be described in detail and a method of controlling the hot water to be produced by the differential heater will be described in detail. Differential heaters are applied to water purifiers, and water purifiers include water purifiers, cold and hot water dispensers, and refrigerators. On the other hand, the hot water tank may be installed in any one of before or after the filter based on the flow of water. If the filter is installed before the filter, raw water is supplied to the hot water tank. If the filter is installed after the filter, the hot water tank is purified. Here, the case where the hot water tank is installed before the filter will be described as an example.

1 is a block diagram schematically showing a water purifier having a differential heater according to an embodiment of the present invention. However, the drawings are not strictly expressed and may have components that are not shown in the drawings for the convenience of description.

According to Figure 1, the raw water flowing into the water purification apparatus (WP) through the external water supply is converted into purified water through the hot water tank 100 and the filter 200. The configuration of the filter 200 may be variously modified, and generally, the filter 200 is composed of a plurality of filters. The filter 200 may include a pre carbon filter, an UF filter, and a post carbon filter. In some cases, other types of filters may be added. A water supply valve 301 is provided between the external water supply source and the front end of the hot water tank 100. The water supply valve 301 is connected to the water supply passage 303, and when the water supply valve 301 is opened, raw water is supplied through the water supply passage 303. That is, when the water supply valve 301 is opened, the raw water is supplied to the hot water tank 100 of the present invention.

The hot water tank 100 is named to explain the technical idea of the present invention, and may also substantially flow room temperature or cold water. Therefore, the hot water tank 100 is preferably expressed as a tank through which hot water, cold water or hot water can flow, but in view of the purpose of the present invention will be referred to as a hot water tank 100. The flow path between the hot water tank 100 and the filter 200 is called a purified water flow path 304. In the purified water flow path 304, raw water heated toward the filter 200 flows. The purified water generated by filtering the raw water is discharged to the outside of the water purification device WP through the water discharge passage 306 and the water discharge valve 302.

The water purifier applied to the embodiment of the present invention is preferably a direct type water purifier. That is, the water purifier may be purified water is extracted to the outside by using the water pressure of the external water supply. In this case, the water supply valve 301 together with the water outlet valve 302 may be opened together while the water is being extracted, so that the filtering may be performed together with the water extraction. In addition, in the direct type water purifier, continuous flow of raw water and purified water occurs from the water supply valve 301 to the water discharge valve 302. Substantially all of the flow rate flowing from the water supply valve 301 is discharged through the water outlet valve 302. Accordingly, a process for removing air generated in the flow path is required for smooth and continuous flow.

Here, the hot water tank 100 may be said to be one of the flow paths that directly receive the water pressure of the external water supply source. The hot water tank 100 is completely filled with raw water based on the continuous flow. To this end, the hot water tank 100 is preferably a closed tank in which the external water source is pressurized to the internal pressure. The structure and function of the hot water tank 100 will be described in detail later. On the other hand, the flow rate sensor 305 is provided between the hot water tank 100 and the filter 200 to detect the flow rate. The controller 300 controls the operation of the water supply valve 301, the water discharge valve 302, the temperature of the hot water tank 100, and the flow rate sensor 305 by using an already set algorithm.

2 is an exploded perspective view showing a hot water tank 100 according to an embodiment of the present invention. At this time, the structure of the hot water tank 100 may further include elements that add other functions within the scope of the present invention.

2, the hot water tank 100 includes a heater unit 20 and a discharge unit 30, and the heater unit 20 is built in the lower cover 10, the inner cylinder 13, and the upper cover 15. do. The inner cylinder 13 substantially provides a hot water tank a in which raw water supplied to the hot water tank 100 is stored. The hot water tank a of the direct type water purifier is distinguished from the water tank of the conventional water tank type water purifier. Hot water tank (a) is a very small storage capacity, unlike the above water tank, where the raw water is stored for the hot water. The heater unit 20 includes a heater support plate 21, a separator plate 22, a primary heater 23, a secondary heater 24, a water supply pipe 25, a bimetal 26, and a temperature sensor 27. . The heater support plate 21 fixes the primary heater 23 and the secondary heater 24, and the water supply pipe 25 is connected. Although not shown, the primary and secondary heaters 23 and 24 are connected to a printed circuit board or the like for controlling the temperature.

The separation plate 22 collides with the raw water flowing from the water supply pipe 25, and thus, the raw water is ejected toward the primary and secondary heaters 23 and 24, thereby preventing the raw water and hot water from mixing directly. Specifically, the raw water collides with the separator 22 to flow in the opposite direction to the jetting direction. In this case, the jetting speed of the raw water decreases rapidly and is not directly mixed with the hot water heated by the primary and secondary heaters 23 and 24. If there is no separation plate 22, the raw water, which is room temperature water, is directly mixed with the raw water being heated, and it is difficult to adjust the temperature of the hot water of the heater unit 20. That is, the separating plate 22 guides the raw water introduced from the water supply pipe 25 to flow statically without forming a vortex in the hot water tank a. One side of the separation plate 22 has a separation plate support 22a which is connected to the heater support plate 21 to give a predetermined distance to the heater support plate 21. At this time, the bimetal 26 for on / off is applied, the temperature sensor 27 measures the temperature of the hot water stored in the heater unit 20.

The discharge part 30 includes an inner cylinder cover 31, a water discharge pipe 32, an air discharge pipe 33, a pressure reducing valve 34, and an elbow 35. The inner cylinder cover 31 is positioned opposite to the heater support plate 21 with respect to the inner cylinder 13, and seals the inner cylinder 13 together with the heater support plate 21. The water outlet pipe 32 and the air discharge pipe 33 are inserted into the inner cylinder cover 31 and fixed. Elbow 35 is the discharge pipe 32 and the air discharge pipe 33, respectively, to redirect the flow of fluid (raw water, air). A pressure reducing valve 34 is added to the air discharge pipe 33 via the elbow 35.

Between the lower cover 10 and the heater unit 20 may include a first heat insulating material 11, a second heat insulating material 12 surrounding the inner cylinder 13, and a third heat insulating material 14 embedded in the upper cover 15. Can be. The first to third heat insulating materials 11, 12, and 14 may use glass fibers, concrete, gypsum, heat resistant plastics, heat resistant ceramics, heat resistant paper or stone powder, and mixtures thereof, but are not limited thereto. The inner cylinder 13 is preferably made of a metal material such as stainless steel, and constitutes a side wall of the heater unit 20 for storing heated hot water. The first heat insulating material 11 has a through hole into which the primary and secondary heaters 23 and 24 and the water supply pipe 25 are inserted, and the third heat insulating material 14 has a water discharge pipe 32, an air discharge pipe 33, There is a through hole for receiving the bimetal 26 and the temperature sensor 27.

3 is a perspective view showing a hot water tank 100 according to an embodiment of the present invention. At this time, a portion of the hot water tank 100 was cut for convenience of description. 4 is a cross-sectional view taken along line IV-IV of FIG. 3, FIG. 5 is a cross-sectional view taken along line V-V of FIG. 3, and FIG. 6 is a cross-sectional view taken along line VI-VI of FIG. 4. . At this time, a detailed description of each component constituting the hot water tank 100 will be referred to FIG.

3 to 6, the heater support plate 21, the inner cylinder cover 31, and the inner cylinder 13 are sealed to provide a hot water tank a in which warm water is stored. The primary and secondary heaters 23 and 24 have a height difference H and are fixed to the heater support plate 21. At this time, the height difference H is determined based on the heater support plate 21. The primary and secondary heaters 23 and 24 are each U-shaped and arranged in a cross shape in plan view (FIG. 6). The primary and secondary heaters 23 and 24 may be applied with known sheath heaters, band heaters, ceramic heaters, and the like. The primary and secondary heaters 23 and 24 do not contact each other in the form of rods. In other words, the primary and secondary heaters 23 and 24 have a height difference H and are arranged in a cross shape in a plane without being in contact with each other. At this time, the secondary heater 24 occupies a higher position than the primary heater 23, and thus, the primary heater 23 is installed inside the secondary heater 24.

The primary heater 23 is a heater for preheating. Preheating is to ensure that the raw water stored in the hot water tank (a) is always maintained at a constant temperature regardless of the water discharge. That is, even if the user does not operate the water purifier WP to withdraw hot water, the raw water is continuously heated to maintain a constant temperature, for example, 60 ° C. To this end, the primary heater 23 needs to heat the raw water with minimal power. To this end, the primary heater 23 is a heater of a relatively small size compared to the secondary heater 24 is used, U-shaped is preferable to further extend the range of heating compared to the date form.

Within the scope of the present invention, the primary heater 23 may have other forms of shape, such as a cylindrical form. As another example, the primary heater 23 may have a structure in which a plurality of rod-shaped heaters 23 are erected at regular intervals from each other. In this case, the number of the primary heaters 23 is not one but a plurality. That is, the primary heater 23 according to the embodiment of the present invention has both the secondary heater 24 and the height difference (H) on the basis of the heater support plate 21, all smaller than the secondary heater 24 It will be possible.

The secondary heater 24 is a heater driven when the hot water is withdrawn. The hot water withdrawal means that the user operates the water purifier WP in order to use hot water of high temperature (about 80 ° C). For convenience, the temperature of the hot water heated by the primary heater 23 is called low temperature, and the temperature of the hot water heated by the secondary heater 24 is called high temperature. When the water purifier WP is operated, power is applied to the secondary heater 24. Since the secondary heater 24 must heat the entire raw water in the hot water tank a, the secondary heater 24 should be heated more widely than the primary heater 23. To this end, the secondary heater 24 is a heater of a relatively larger size than the primary heater 24 is used, the U-shaped is preferable to further expand the range of heating compared to the primary form.

Within the scope of the present invention, the primary heater 23 may have other forms of shape, such as a cylindrical form. As another example, the secondary heater 24 may have a structure in which a plurality of rod-shaped heaters 24 are set up at regular intervals from each other. In this case, the number of the secondary heaters 24 is not one but a plurality. That is, the secondary heater 24 according to the embodiment of the present invention has both the primary heater 23 and the height difference (H) on the basis of the heater support plate 21, all larger than the primary heater 23 It will be possible.

Conventional water purifiers apply relatively high power, such as 2,500 W to 2,800 W, to the heaters to withdraw hot water. That is, since the normal temperature water supplied from the water supply pipe 25 needs to be heated until it reaches the said high temperature, high electric power is calculated | required compared with this invention. Since the electric power causes an overload of indoor wiring in a general home or office and causes power interruption or instability, it is difficult to handle it. In order to compensate for this, power cords and lead wires, which constitute water purifiers, are strengthened, but this is not a fundamental solution. In addition, the conventional heating method does not reach the desired high temperature of the initial hot water due to the latent heat of water. Thus, the user discards the initial hot water and takes hot water after the initial time at which the desired high temperature is reached. This heating method is a waste of water and power.

In contrast, the hot water tank 100 of the present invention maintains a heating state at a relatively small power, for example, 700 W to 900 W, by the primary heater 23, and when the hot water is discharged, the secondary heater. By 24, a relatively large electric power, for example, 1000W to 1500W of secondary power is applied to instantaneously generate hot hot water. To this end, when the secondary heater 24 is turned on and driven, the primary heater 23 may be turned off. The secondary heater 24 may operate by using a time or time delay to recognize the operation. Therefore, hot water generation at a high temperature according to an embodiment of the present invention does not require power of more than a secondary power of 1000W to 1500W.

For example, it is assumed that the temperature of the hot water heated by the primary heater 23 is 60 ° C, which is a low temperature, and the temperature of the hot water heated by the secondary heater 24, is 80 ° C, which is a high temperature. At this time, the temperature of the hot water discharged from the water purifier WP is 80 deg. The conventional water purifier must raise the temperature of normal temperature water by 55 degreeC so that it may become high temperature 80 degreeC in normal temperature water of 25 degreeC. In contrast, the water purifying apparatus of the embodiment of the present invention may be raised by 20 ° C from 60 ° C at low temperature to 80 ° C at high temperature. Accordingly, the conventional heating method requires a relatively high power compared to the present invention. In addition, this temperature rise must occur for a short time, so the instantaneous power consumption is large. The embodiment of the present invention can solve the problems of the conventional heating method to instantaneously obtain high temperature hot water with relatively low power.

On the other hand, the power applied to the primary and secondary heaters (23, 24) is the size of the hot water tank 100, the size and arrangement of the primary and secondary heaters (23, 24) according to an embodiment of the present invention Can be set in consideration. In this way, the primary and secondary heaters 23 and 24 that differ in power applied from each other are referred to as differential heaters. Although two heaters (primary and secondary) are shown in the drawings, it is obvious that more heaters (eg, a plurality of rod-shaped heaters) can be disposed within a range that satisfies the technical spirit of the present invention. However, only the best cases are presented here.

When the secondary heater 24 is made larger than the primary heater 14 and the height difference H is placed, the temperature of the hot water can be varied according to the position in the hot water tank a. Although the upper temperature is high due to convection of the hot water, by arranging the secondary heater 24 near the water discharge pipe 24, the temperature of the hot water near the water discharge pipe 32 can be further increased artificially. Accordingly, when the secondary heater 24 is driven to withdraw hot water, the temperature of the hot water near the water discharge pipe 32 has a relatively high temperature as compared with other parts. In other words, the temperature of the hot water in the portion adjacent to the outlet pipe 32 has a higher temperature than the hot water with the side farther from the outlet pipe 32. Preferably, the secondary heater 24 may be convexly rounded in the direction of the outlet pipe 32 so that the secondary heater 24 may be disposed close to the outlet pipe 32.

When the differential heater is applied to the hot water tank 100 such as the primary and secondary heaters 23 and 24 according to the embodiment of the present invention, high power is not required unlike in the prior art. Accordingly, the indoor wiring is not overloaded in a general home or office. Accordingly, unlike the related art, a power cord, a lead wire, or the like constituting the water purifying device is unnecessary. In addition, since the initial hot water of the water purifying apparatus according to the embodiment of the present invention corresponds to a desired high temperature (about 80 ° C.), it is not necessary to discard the initial hot water, thereby preventing waste of water and power. That is, in the embodiment of the present invention, by utilizing a relatively low power, hot water of high temperature can be continuously discharged.

On the other hand, the air is accumulated in the hot water tank (a), the cause of the air is various. For example, the air flowing into the hot water tank (a) is introduced through the water supply pipe (25), and the air is accumulated in the upper portion of the hot water tank (a). In addition, air generated in the water treatment process inside the hot water tank (a) may also accumulate on the upper portion of the hot water tank (a). In particular, as the raw water is heated, the raw water is boiled, and the air dissolved in the raw water may be accumulated in the upper portion of the hot water tank (a) from the raw water. Air accumulated in the upper portion of the hot water tank (a) should be discharged to the outside of the hot water tank 100 through the air discharge pipe (33).

Embodiment of the present invention is the cumulative space of the gap (D) between the end of the water discharge pipe (32) protruding and extending into the hot water tank (a) and the end of the air discharge pipe 33 in communication with the inside of the hot water tank (a) (b) is given. At this time, the air discharge pipe 33 does not protrude into the hot water tank (a), the end is good to match the inner cylinder cover (31). Accumulation space (b) is present in the upper portion of the hot water tank (a), and is a place to temporarily fill the air due to the various causes described above. If there is no cumulative space (b), air continues to stay in the hot water, so that the flow of hot water flowing into the outlet pipe 32 does not occur smoothly. By the way, the cumulative space (b) according to an embodiment of the present invention by leaving a space where the air gathers, the outlet pipe 32 can smoothly flow the raw water without interference of the air. In this case, the hot water of hot water with little air is discharged | emitted by the water extraction pipe 32.

Pressure reducing valve (34) is to reduce the pressure by the air, it serves to reduce the pressure of the air. In general, a pressure reducing valve is a valve for depressurizing a fluid when the pressure of the fluid is high and maintaining a constant pressure after depressurizing. The pressure reducing valve is used to maintain high pressure steam, air, gas and the like at a constant pressure. A force is applied to the valve by a spring, a diaphragm, or the like, and when the pressure reducing side is smaller than a predetermined pressure, the valve is pushed in and the fluid flows in. In the opposite case, the pressure of the fluid overcomes the opening force of the valve to close the valve so that the fluid does not flow. If the pressure reducing valve 34 is installed on the outlet pipe 32 side, the hot water vapor and hot water are discharged in a mixed state without being separated, and the user may be burned by a so-called steam splashing phenomenon. Accordingly, the pressure reducing valve 34 is preferably installed in the air discharge pipe (33).

Although not shown, the hot water tank a may provide a space between the second heat insulating material 12 and the inner cylinder 13 and vacuum the space. At this time, the second heat insulating material 12 may be attached to a new cylinder (not shown) of the same shape and material as the inner cylinder 13. When the vacuum treatment, the heat loss of the hot water stored in the hot water tank (a) to the maximum by the heat insulating effect by the vacuum. By reducing the heat loss, the power applied to the secondary heater 24 can be lowered. Power and time applied to the secondary heater 24 are set based on the temperature measured by the temperature sensor 27.

Hereinafter will be described a method for controlling the hot water temperature of the hot water tank (a) according to an embodiment of the present invention. First, the primary heater 23 is turned on to apply primary power to maintain the temperature of the hot water tank a at a low temperature at all times. Then, the user pushes the water discharge button to withdraw hot water of high temperature. When the user presses the water discharge button, the primary heater 23 is turned off and the secondary heater 24 is turned on to heat the temperature of the hot water tank a to a high temperature to generate hot hot water. Discharges through the outlet pipe 32. When the discharge of the high temperature hot water is completed, the secondary heater 24 is turned off and the primary heater 23 is turned on. In this case, the OFF of the primary and secondary heaters 23 and 24 may be implemented by a recognition time or a time delay method.

As mentioned above, although the present invention has been described in detail with reference to preferred embodiments, the present invention is not limited to the above embodiments, and various modifications may be made by those skilled in the art within the scope of the technical idea of the present invention. It is possible.

100; Hot water tank 200; filter
10; Lower cover
11, 13, 14; 1st to 3rd heat insulating material
12; Inner tube 15; Top cover
20; Heater 21; Heater support plate
22; Separator
23, 24; Primary and secondary heaters
25; Water pipe 26; Bimetal
27; temperature Senser
30; Outlet 31; Inner tube cover
32; Outlet 33; Air exhaust pipe
34; Pressure reducing valve 35; Elbow
a; Hot water tank b; Cumulative space

Claims (16)

Hot water tank for heating raw water or purified water; And
A filter connected to the hot water tank and generating purified water by receiving the filtered raw water heated from the hot water tank or filtering the raw water to supply the hot water tank,
The hot water tank
The inner tube cover, the lower cover, and the inner cylinder are sealed in a hot water tank, and the primary heater for continuously heating the raw water or purified water stored in the hot water tank with primary power and only when the raw water or purified water is discharged to secondary power And a heater having a secondary heater to be heated, wherein the secondary power is higher than the primary power. The water purifying apparatus according to claim 1, wherein the primary heater and the secondary heater have a height difference (H), and the size of the secondary heater is larger than that of the primary heater. The water purifier having a differential heater according to claim 1, wherein the primary heater is located inside the secondary heater. The water purifier having a differential heater according to claim 1, wherein the primary heater and the secondary heater are arranged in a cross shape in plan view without contacting each other. The water purifier having a differential heater according to claim 1, wherein the primary heater and the secondary heater have a U shape. The water purifier having a differential heater according to claim 1, wherein the secondary heater is convexly rounded in the direction of the outlet pipe through which the raw water or the purified water is discharged. The water purifier having a differential heater according to claim 1, wherein the hot water tank includes a temperature sensor for adjusting an amount of power applied to the secondary heater. According to claim 1, wherein the differential heater, characterized in that the accumulated space of the gap (D) is present between the end of the discharge pipe extending into the hot water tank and the end of the air discharge pipe communicating with the inside of the hot water tank. Water purifier. The water purifying device according to claim 8, wherein the air discharge pipe is connected to a pressure reducing valve. The water purifying apparatus according to claim 1, wherein the inner cylinder is surrounded by a heat insulating material, and a space is provided between the inner cylinder and the heat insulating material, and the space is vacuumed. Continuously heating the raw water or the purified water stored in the hot water tank in which the inner cylinder cover, the lower cover and the inner cylinder are sealed, and stored in the hot water tank by primary power of a primary heater;
When the user presses the water exit button, turning on the secondary heater with the secondary power greater than the primary power and turning off the first heater; And
And when the water extraction by the water extraction button is completed, turning off the secondary heater and turning on the primary heater to an on state. 12. The method of claim 11, wherein the secondary heater maintains the ON state by a recognition time or a time delay method. 12. The differential heater of claim 11, wherein the primary heater and the secondary heater have a height difference H, and the size of the secondary heater is larger than that of the primary heater. Control method. 12. The method of claim 11, wherein the primary heater is located inside the secondary heater. 12. The method of claim 11, wherein the primary heater and the secondary heater are arranged in a cross shape in plan view without contacting each other. 12. The differential heater control method of claim 11, wherein the hot water tank includes a temperature sensor for adjusting an amount of power applied to the secondary heater.

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