KR20210017987A - Hybrid Flash Water Heater With Warm-up Heater - Google Patents

Abstract

The present invention relates to an instantaneous hybrid water heating device including a pre-heater, which comprises: a hot water housing (100) having an enclosure shape with the front surface opened, wherein the inside thereof is not divided to be configured as a single space; a cover unit (200) coupled to cover the front surface of the hot water housing (100); a pre-heater (500) which is a heat source mounted in the hot water housing (100), and heats water supplied to the inside of the hot water housing (100) to a first temperature; a main heating heater (600) which is a heat source individually mounted on the hot water housing (100) and the cover unit (200) to be installed within the same space as the pre-heater (500), and heats the water pre-heated at the first temperature to a second temperature which is higher than the first temperature; and a control unit (not shown) which is in a pre-heating mode at normal times to apply power to the pre-heater (500) while cutting off the power of the main heating heater (600) to maintain the water contained in the hot water housing (100) at the first temperature, before, when a hot water key signal of a user is inputted, being converted into an instantaneous heating mode to cut off the power of the pre-heater (500) and apply the power to the main heating heater (600) so as to instantaneously heat the water at the first temperature to the second temperature. Therefore, hot water can be sufficiently and quickly supplied.

Description

Hybrid Flash Water Heater With Warm-up Heater {Hybrid Flash Water Heater With Warm-up Heater}

The present invention relates to an instantaneous hot water device, and more particularly, a hybrid instantaneous heater including a preheating heater capable of quickly supplying hot water of 80°C or higher in a manner in which a plurality of heaters are selectively driven to additionally heat preheated water. It relates to a hot water device.

Hot water supply devices used in water purifiers are largely divided into a water tank type in which a heater is installed in a water tank, and an instant hot water type in which the supplied water is heated using a heater whenever necessary.

The water tank type hot water supply device always maintains the temperature of the water in the water tank at the set temperature regardless of whether or not hot water is used, so it is difficult to form a compact appearance with low home appliance efficiency because standby power is wasted and occupies a lot of space. . Accordingly, in recent years, an instantaneous hot water supply device for supplying hot water by instantaneously heating water according to a user's request for hot water supply has been widely used.

In the case of a conventional instantaneous hot water supply device, when the user wants to take in hot water, the water flowing from the purification tank to the heater tank is heated and provided to the user, so that the temperature of the hot water is low, and the hot water is supplied to the user. It takes a lot of time to reach, and the flow rate is inevitably reduced in order to meet the appropriate level of the water discharge temperature, and there is a problem that the water discharge time becomes longer when a large amount of hot water is required.

Republic of Korea Patent Publication No. 10-0409157 (registration announcement on December 12, 2003, title of invention: water heater and its control method)

Accordingly, a problem to be solved by the present invention is to solve such a conventional problem, and to provide a hybrid instantaneous hot water device including a preheater capable of sufficiently and quickly supplying hot water of 80°C or higher.

In addition, other objects of the present invention can be all achieved by the detailed description of the present invention described with reference to the accompanying drawings.

In order to achieve the above object, a hybrid instantaneous hot water apparatus including a preheating heater of the present invention includes: a hot water housing 100 having an open front housing shape, not partitioned inside, but consisting of one space; A cover part 200 coupled to cover the front surface of the hot water housing 100; A preheater 500 for preheating the water supplied to the inside of the hot water housing 100 to a first temperature as a heat source mounted inside the hot water housing 100; As a heat source installed in each of the hot water housing 100 and the cover part 200 and installed in one space with the preheater 500, a stock price that heats the water preheated at the first temperature to a hotter second temperature Heat heater 600; And in a preheating mode in which the power of the preheating heater 500 is applied and the power of the main heating heater 600 is cut off to maintain the water contained in the hot water housing 100 at the first temperature during normal operation. When the user's hot water key signal is input, the power of the preheating heater 500 is cut off and the power of the main heating heater 600 is applied to instantaneously heat the water of the first temperature to the second temperature. Including, the preheating heater 500 is a sheath heater in which a heating line is installed in a pipe coupled in a spiral shape along the inside of the hot water housing 100, and the main heating heater ( 600) is a Lutenox heater in which a ceramic heating plate is coated on each of the hot water housing 100 and the cover 200, and the first temperature is set to a temperature between 50°C and 75°C. .

In the hybrid instantaneous hot water apparatus including the preheating heater of the present invention, the hot water housing 100 and the cover part 200 may be coupled to each other by a curling compression method in which the ends of the members are formed into a rounded shape. have.

In the hybrid instantaneous hot water apparatus including the preheating heater of the present invention, the water supply pipe 300 is coupled to the upper side of the hot water housing 100 to supply unheated water to the inside of the hot water housing 100; And a discharge pipe 400 which is coupled to a lower side of the hot water housing 100 to discharge water preheated to the first temperature or water heated to the second temperature, wherein the water supply pipe 300 comprises: A first water supply port 301 that penetrates through the cover part 200 and is inserted into the inside of the hot water housing 100, and extends bending toward one side of the hot water housing 100 from an end of the water supply port 301 A second water supply port 302 is provided, and the discharge pipe 400 includes a first discharge port 401 inserted into the hot water housing 100 through the cover part 200, and the first A second discharge port 402 that is bent and extended toward the other side of the hot water housing 100 at an end of the discharge port 401, and the second water supply port 302 and the second discharge port 402 include the The hot water housing 100 may be disposed to correspond to each other in a diagonal direction, so that the water supplied from the second water supply port 302 moves in a diagonal direction toward the second discharge port 402 and is discharged. .

In the hybrid instantaneous hot water apparatus including the preheating heater of the present invention, the flow of water supplied from the water supply pipe 300 and moved in a diagonal direction toward the discharge pipe 400 is supplemented on the rear surface of the hot water housing 100. A plurality of first guide ribs 101 are protruded so as to be guided to, and on the inner side of the cover part 200 facing the rear surface of the hot water housing 100, the same path as the plurality of first guide ribs 101 As a result, a plurality of second guide ribs 201 may be protruded.

According to the hybrid instantaneous hot water device including the preheater of the present invention, the water supplied to the inside of the hot water housing is preheated to a predetermined temperature, and the water is instantaneously heated selectively according to the user's input signal. Water can be continuously supplied, the initial water outlet time required to supply hot water can be shortened by that amount, and an effect of supplying hot water at a sufficient flow rate can be obtained.

In addition, in the present invention, since the water is preheated, the power required for instant heating is relatively reduced, thereby solving the power cut-off problem due to high output, and by applying heat only when hot water is used, it is also energy efficient. Advantageous effects can be obtained.

In addition, the present invention has a non-partition wall structure in which the interior of the hot water housing is not partitioned and consists of one space, thereby minimizing eddy currents generated in the blind spot around the partition wall to prevent scale from accumulating inside the hot water housing. You can get a good effect. This improves the long-term durability of the hot water module and improves use stability.

In addition, according to the present invention, the hot water housing and the cover portion are mutually coupled by a curling compression method, so that scale generation and durability reduction problems due to high temperature thermal corrosion caused by airtight treatment by the conventional welding method can be solved. .

In addition, according to the present invention, by arranging the water supply pipe and the discharge pipe in opposite directions toward the inner wall of the hot water housing, the generation of scale is minimized and heat is evenly transferred from the heat source.

1 is a perspective view of a hybrid instantaneous hot water device including a preheater according to a first embodiment of the present invention.
2 is an exploded perspective view of a hybrid instantaneous hot water device including the preheating heater of FIG. 1.
3 is a view showing a method of coupling a hot water housing and a cover part included in the hybrid instantaneous hot water device including the preheating heater of FIG. 1.
4 is a flowchart schematically showing the control flow of the hybrid instantaneous hot water device including the preheater of FIG. 1.
FIG. 5 is a view for explaining a numerical limit definition of a first temperature set in the hybrid instantaneous hot water device including the preheating heater of FIG. 1;
6 is a perspective view showing a household water purifier equipped with a hybrid instantaneous hot water device including the preheating heater of FIG. 1;
7 is a front view of a hybrid instantaneous hot water device including a preheating heater according to a second embodiment of the present invention.
8 is an exploded perspective view of a hybrid instantaneous hot water device including a preheating heater according to a third embodiment of the present invention.
9 is an enlarged view showing a water supply pipe included in a hybrid instantaneous hot water device including a preheating heater according to a fourth embodiment of the present invention.
10 is a cross-sectional view of a third water supply port provided in the water supply pipe of FIG. 9;

Hereinafter, embodiments of a hybrid instantaneous hot water device including a preheating heater according to the present invention will be described in detail with reference to the accompanying drawings. When it is determined that the description of the known technology in connection with the present invention may obscure the subject matter of the present invention, a detailed description of the known technology will be omitted.

1 is a perspective view of a hybrid instantaneous hot water device including a preheating heater according to a first embodiment of the present invention, FIG. 2 is an exploded perspective view of a hybrid instantaneous hot water device including the preheating heater of FIG. 1, and FIG. It is a view showing the coupling method of the hot water housing and the cover part included in the hybrid instantaneous hot water device including the preheater of Figure 4 is a flow chart schematically showing the control flow of the hybrid instantaneous hot water device including the preheater of Figure 1, FIG. 5 is a diagram illustrating a numerical limit definition of a first temperature set in a hybrid instantaneous hot water device including the preheating heater of FIG. 1.

1 and 2, a hybrid instantaneous hot water device 10 including a preheating heater according to an embodiment of the present invention is a method of additionally heating preheated water by selectively driving a plurality of heaters at 80°C. As a device for rapidly supplying the above hot water, the hot water housing 100, the cover part 200, the water supply pipe 300, the discharge pipe 400, the preheating heater 500, the main heating heater 600, and a control unit (not shown) Consists of including.

As shown in FIG. 2, the hot water housing 100 is manufactured in the shape of a square box with an open front surface. Since water is contained in the hot water housing 100, it is preferable that the hot water housing 100 is made of a material having a low heat transfer coefficient or an insulating material is interposed therebetween.

The cover part 200 is coupled to cover the front surface of the open hot water housing 100. Therefore, the hot water housing 100 is configured as a single space without partitioning the inside. Such a partition-free structure minimizes eddy currents generated in a blind spot around the partition wall, thereby preventing scale from accumulating in the hot water housing.

The coupling of the cover part 200 and the hot water housing 100 may be performed only by laser welding, as shown in FIG. 3A. However, the laser welding method has a disadvantage in that it is vulnerable to the occurrence of high temperature thermal corrosion due to residual stress during high temperature heating bonding.

Therefore, as shown in (b) and (c) of Figure 3, the hot water housing 100 and the cover portion 200 are mutually coupled by a curling compression method in which the end of the member is molded into a rounded shape. It is desirable.

However, as shown in (c) of FIG. 3, by placing the silicon (s) interposed to maintain airtightness on the bent end of the cover part 200, and curing the end of the hot water housing 100, It is more preferable to make the silicon (s) in a structure that does not directly contact drinking water.

The water supply pipe 300 is a pipe that is coupled to the upper side of the hot water housing 100 to supply unheated water to the inside of the hot water housing 100, as shown in FIG. 2.

The discharge pipe 400 is a pipe that is coupled to the lower side of the hot water housing 100 to discharge water preheated to a first temperature or water heated to a second temperature.

The preheater 500 is a heat source mounted inside the hot water housing 100 and serves to preheat the water supplied to the inside of the hot water housing 100 to a first temperature. The preheater 500 is a sheath heater in which a heating line is installed in a pipe coupled in a spiral shape along the inside of the hot water housing 100.

The main heating heater 600 is a heat source mounted on the hot water housing 100 and the cover part 200, respectively, and functions to heat water preheated to a first temperature to a hotter second temperature. The main heating heater 600 is a Lutenox heater in which a ceramic heating plate is coated on the hot water housing 100 and the cover portion 200, respectively.

Sheath heater is applied to the preheating heater 500 because it is a type of heater that is not limited in processing in various shapes such as a spiral shape, and the Lutenox heater can transfer a lot of heat in a face-to-face manner, so the main heating heater 600 ).

Since the preheater 500 is sufficient if it can preheat water to a low first temperature, its output is preferably configured to be relatively low, 200W to 600W, in terms of equipment saving, and the main heating heater 600 uses high water Since it must be heated to the second temperature, it is functionally preferable that the output is configured to be relatively high as 1,500W to 2,500W.

Here, the second temperature is set to 98°C. As is known, water starts to boil from 90°C. If the second temperature, which is the target temperature, is set higher than 98°C, a large amount of water vapor is generated, which may lead to device failure due to moisture loss and increase in internal pressure. You have to take this into account.

The first temperature, which is the preheating temperature, may be set in various ways, but is preferably set to a temperature between 50°C and 75°C. The reason for this is as follows.

As shown in FIG. 5, assuming that the average indoor temperature and the temperature of the water supplied are around 20°C and the second temperature, which is the target temperature, is 98°C, the first curve L1 on the left of the graph is 20°C. It is a diagram showing the time required for heating to the second temperature as the temperature increases from to 98℃, and the second curve (L2) on the right of the graph is the amount of heat required to the second temperature as the first temperature increases from 20℃ to 98℃. It is a diagram showing

The temperature at the point where the two curves meet is approximately 50°C to 75°C (reflecting the difference in indoor temperature by season), and if the first temperature, which is the preheating temperature of water, is lower than the lower limit temperature, the time required for heating to the second temperature becomes longer, When the first temperature is higher than the upper limit temperature, the amount of heat required to the second temperature increases.

Therefore, the first temperature is preferable in terms of thermal energy efficiency and waiting time determined within the numerical range.

As shown in FIG. 4, the control unit (not shown) applies the power of the preheating heater 500 and cuts off the power of the main heating heater 600 at a first temperature. It is in the preheating mode to keep the range of.

While measuring the water temperature in real time through a temperature sensor (70, see Fig. 2), if the water temperature is lower than 50°C, the power of the preheater 500 is applied to increase the water temperature, and if the water temperature is higher than 75°C , The preheater 500 is shut off to maintain the water temperature.

In this state, when the user's hot water key signal is input, the power of the preheating heater 500 is cut off and the power of the main heating heater 600 is applied to instantaneously heat the water of the first temperature to the second temperature. Switch to

The water is quickly heated by applying the power of the main heating heater 600 until the water temperature reaches 98°C. When the water temperature reaches 98°C, the power of the main heating heater 600 is cut off and the water temperature Will be maintained.

In the present invention configured as described above, a preheater 500 is added to the inside of the hot water housing 100 to maintain the first temperature of the water in advance, for example 60°C, and when the user presses the hot water key button, preheating As the operation of the heater 500 is stopped and the main heating heater 600 is operated, hot water having a second temperature, for example, 80° C. or higher may be quickly discharged.

When the user presses the hot water key button and then presses the water outlet button, the water outlet valve is opened, and hot water at 80°C to 98°C can be continuously supplied.

In the case of a conventional instantaneous hot water supply device, when a user wants to intake hot water, the water in the heater tank and the water in the hot water outlet passage are drained, and the water flowing from the purification tank to the heater tank is heated and provided to the user. The temperature of the hot water to be discharged is low, it takes a long time to supply the hot water to the user, and there is a problem that the extraction flow rate is relatively low.

In other words, this conventional non-preheated instantaneous hot water supply method has to perform the first water outflow operation of first discharging unpreheated water due to its characteristics, resulting in water loss, as well as time required for discharging water. Accordingly, there was a problem that the time until the hot water outlet was also delayed.

In addition, since the conventional non-preheated instantaneous hot water supply method generates a high output to heat the water inside the heater tank within a short time, there is a problem in that the domestic circuit breaker operates according to the usage environment and the input power is cut off.

On the other hand, the present invention preheats the water supplied to the inside of the hot water housing to a certain temperature in advance, and instantaneously heats the water selectively according to the user's input signal, thereby continuously supplying high temperature water of 80°C or higher. The time required to supply the can be shortened that much, and the effect of supplying hot water at a sufficient flow rate can be obtained.

In addition, in the present invention, since the water is preheated, the power required for instant heating is relatively reduced, thereby solving the power cut-off problem due to high output, and by applying heat only when hot water is used, it is also energy efficient. Advantageous effects can be obtained.

Reference numeral 50, which is not described in FIG. 1, is a bracket mounted to fix the hot water housing 100, reference numeral 60 is a bimetal installed on one surface of the hot water housing 100 to control the temperature of water, and the reference numeral 70 It is a temperature sensor that can measure the temperature of water contained in the hot water housing 100 in real time.

From now on, a household water purifier equipped with a hybrid instantaneous hot water device including a preheater will be described. 6 is a perspective view illustrating a household water purifier equipped with a hybrid instantaneous hot water device including the preheating heater of FIG. 1.

Referring to FIGS. 1 and 6, the hybrid instantaneous hot water device 10 is mounted on the water purifier body 3.

The water purifier body (3) has a water outlet pipe (4) installed at a certain height on a base on which a cup is placed, and a first connection pipe (P1) that delivers water cooled by a separate cooling device to the water outlet pipe (4). And, a second connection pipe (P2) for directly transmitting unheated water to the water outlet pipe (4), and a third connection pipe (P3) connecting the discharge pipe (400) and the water outlet pipe (4) are provided.

In addition, the water purifier body 3 includes a first solenoid valve S1 for opening and closing the first connection pipe P1 according to an electrical signal, and a second solenoid valve S1 for opening and closing the second connection pipe P2 according to an electrical signal. A third solenoid valve (S3) for opening and closing S2) and the third connection pipe (P3) according to an electrical signal is further provided, and a cold water button (B1) outputting independent signals to the control unit on the upper portion of the water purifier body (3). ), hot water button (B2, can be called hot water key), heavy water button B3, and direct water button B4, respectively.

In response to a button signal of any one of the cold water button (B1), hot water button (B2), heavy water button (B3), and direct water button (B4), the control unit is configured with a first sole valve (S1), a second sole valve (S2), and The third sole valve S3 is selectively controlled.

For example, when the first signal is input from the cold water button B1, the controller controls only the first sole valve S1 to open while maintaining the preheating mode. Cold cold water comes out through the water outlet pipe (4).

When the second signal is inputted from the hot water button B2, the control unit switches to the instantaneous heating mode and controls only the third sole valve S3 to open when the water is heated to about 80 to 98°C. Hot hot water comes out through the water outlet pipe (4).

When the third signal is input from the heavy water button B3, the control unit controls to open only the third sole valve S3 while maintaining the preheating mode. Warm water preheated to 50℃ ~ 75℃ comes out.

When the fourth signal is input from the direct button B4, the control unit controls to open only the second sole valve S2 while maintaining the preheating mode. Room temperature water that has not been preheated/heated comes out.

As such, the present invention has an additional effect of selectively supplying water at a temperature desired by the user among the four temperatures, and in particular, 50°C to 75°C is a suitable temperature for riding baby formula, and the existing milk powder pot function and You can get a unique effect that the water purifier functions are combined into one.

Hereinafter, a hybrid instantaneous hot water device including a preheater according to a second embodiment of the present invention will be described. Configurations overlapping with the previous embodiment are given the same reference numerals, and descriptions thereof are omitted.

7 is a front view of a hybrid instantaneous hot water device including a preheater according to a second embodiment of the present invention.

Referring to FIG. 7, in this embodiment, the water supply pipe 300 passes through the cover part 200 and is inserted into the interior of the hot water housing 100, and at the end of the water supply port 301. A second water supply port 302 that is bent and extended toward one side of the hot water housing 100 is provided. The direction of the second water supply port 302 is disposed toward an upper sidewall of the hot water housing 100 so that the water introduced from the first water supply port once collides toward the upper sidewall and then disperses and moves.

On the contrary, the discharge pipe 400 passes through the cover part 200 and is inserted into the inside of the hot water housing 100, and at the end of the first discharge port 401, the other It has a second outlet 402 that is bent and extended toward the side. The second discharge port 402 is disposed toward a lower sidewall opposite to the second water supply port 302, and is configured to receive water impinging on the upper sidewall and dispersing in a diagonal direction.

In this way, the second water supply port 302 and the second discharge port 402 are disposed to correspond to each other in a diagonal direction inside the hot water housing 100, so that the water supplied from the second water supply port 302 is the second discharge port. It is configured to be discharged by moving in a diagonal direction toward (402).

In other words, the water initially supplied from the second water supply port 302 proceeds toward the inner wall of the hot water housing 100, collides against the inner wall, and is dispersed, moving to the center of the hot water housing 100, and moving to the central area. By allowing the water to flow into the second outlet 402 disposed on the opposite side, water can be distributed and flowed evenly in every corner of the hot water housing 100, thereby minimizing the generation of scale and heat from the heat source. You can get the effect that can be delivered to Gorche. In other words, the preheating heater, the water supply pipe 300 and the discharge pipe 400 are installed inside the hot water housing 100 to interfere with the flow of water and there is a high possibility of scale accumulation in a space where the flow of water is not smooth. In the same way, the second water supply port 302 is supplied with water in a collision manner to the side wall and the water induced to move to the side wall is discharged through the second discharge port 402 so that the structures installed inside the hot water housing 100 Accordingly, it is possible to minimize the accumulation of scale by minimizing stagnation of water.

In addition, in this embodiment, when viewed from the front, the location of the main heating heater 600 is coupled to the lower right half of the hot water housing 100 adjacent to the second outlet 402, and the heat around the second outlet 402 By delivering more intensively, it is possible to obtain the effect of accurately discharging the temperature of the discharged water to the desired temperature.

This arrangement is also applied to the preheating heater, so that the spiral twisted part of the preheater is moved to the outlet side and installed, so that the water preheated to a higher temperature than the surrounding (water supply part side) during the water outlet operation is applied to the operation of the main heating heater. It is configured to be rapidly heated and discharged through the outlet.

That is, in an embodiment of the present invention, the preheater 500 is installed between the second water supply port 302 and the second discharge port 402 close to the second discharge port 402 side, and the main heating The heater 600 is arranged to cover the entire area where the preheating heater 600 exists, so that the temperature of water discharged can be instantly converted to a desired temperature.

Hereinafter, a hybrid instantaneous hot water device including a preheater according to a third embodiment of the present invention will be described. Configurations overlapping with the previous embodiment are given the same reference numerals, and descriptions thereof are omitted.

8 is an exploded perspective view of a hybrid instantaneous hot water device including a preheating heater according to a third embodiment of the present invention.

Referring to FIG. 8, in this embodiment, a plurality of first guides are provided on the rear surface of the hot water housing 100 so that the flow of water supplied from the water supply pipe 300 and moved in a diagonal direction toward the discharge pipe 400 is assisted. The rib 101 is protruded.

Correspondingly, a plurality of second guide ribs 201 are protruded on the inner surface of the cover portion 200 facing the rear surface of the hot water housing 100 in the same path as the plurality of first guide ribs 101.

It is supplied to the hot water housing 100 so that the water flowing in the diagonal direction follows the first guide rib 101 and the second guide rib 201 to the lower right half of the hot water housing 100 with the main heating heater attached. It is to make it flow through. As a means for inducing the flow of water in the diagonal direction, the shape and arrangement of the preheater may be considered instead of the guide rib. That is, if the elliptical spiral twist portion of the sheath heater, which is a preheating heater, is arranged in a diagonal direction, the flow of water may be induced to follow the diagonal direction by the shape and arrangement of the heater (see FIG. 7(b)).

As described above, the present invention preheats the water supplied to the inside of the hot water housing to a certain temperature in advance, and instantaneously heats the water selectively according to the user's input signal, thereby continuously supplying water of a high temperature of 80°C or higher. , The time required to supply hot water can be shortened that much, and the effect of supplying hot water at a sufficient flow rate can be obtained.

In addition, in the present invention, since the water is preheated, the power required for instant heating is relatively reduced, thereby solving the power cut-off problem due to high output, and by applying heat only when hot water is used, it is also energy efficient. Advantageous effects can be obtained.

In addition, the present invention has a non-partition wall structure in which the interior of the hot water housing is not partitioned and consists of one space, thereby minimizing eddy currents generated in the blind spot around the partition wall to prevent scale from accumulating inside the hot water housing. You can get a good effect.

In addition, according to the present invention, since the hot water housing and the cover portion are mutually coupled by a curling compression method, it is possible to obtain an effect of solving the problem of scale generation and durability degradation caused by high temperature thermal corrosion.

In addition, according to the present invention, by arranging the water supply pipe and the discharge pipe in opposite directions toward the inner wall of the hot water housing, the generation of scale is minimized and heat is evenly transferred from the heat source.

The scope of the present invention is not limited to the above-described embodiments and modifications, but may be implemented in various forms within the scope of the appended claims. Without departing from the gist of the present invention claimed in the claims, any person of ordinary skill in the art to which the present invention belongs is considered to be within the scope of the description of the claims of the present invention to various ranges that can be modified.

100: hot water housing
200: cover
300: water supply pipe
400: discharge pipe
500: preheating heater
600: main heating heater

Claims (1)

A hot water housing 100 in which the front is opened and the interior is not partitioned and consists of one space;
A cover part 200 coupled to cover the front surface of the hot water housing 100;
A sheath heater installed in a spiral shape inside the hot water housing 100, the preheating heater 500 preheating the water supplied to the inside of the hot water housing 100 to a first temperature;
A Lutenox heater in which a ceramic heating plate is coated on the surfaces of the hot water housing 100 and the cover part 200, respectively, and a main heating heater 600 that heats the water preheated to the first temperature to a hotter second temperature. ; And
Normally, the power of the preheating heater 500 is applied and the power of the main heating heater 600 is cut off to maintain the water contained in the hot water housing 100 at the first temperature. When the hot water key signal is input, the power of the preheating heater 500 is cut off and the power of the main heating heater 600 is applied to convert the instantaneous heating mode to instantaneously heat the water of the first temperature to the second temperature. Includes; a control unit (not shown),
A water supply pipe 300 coupled to an upper side of the hot water housing 100 to supply unheated water to the inside of the hot water housing 100; And
A discharge pipe 400 coupled to the lower side of the hot water housing 100 to discharge water preheated to the first temperature or water heated to the second temperature;
The water supply pipe 300 includes a first water supply port 301 that passes through the cover part 200 and is inserted into the hot water housing 100, and the hot water housing 100 at an end of the water supply port 301. ) And having a second water supply port 302 that is bent and extended toward one side of,
The discharge pipe 400 includes a first discharge port 401 inserted into the hot water housing 100 through the cover part 200, and the hot water housing 100 at an end of the first discharge port 401. ) And having a second outlet 402 that is bent and extended toward the other side of,
The direction of the second water supply port 302 is disposed toward the upper sidewall of the hot water housing 100, and the second outlet port 402 is disposed toward the lower sidewall opposite to the second water supply port 302 Become,
The preheating heater 500 is installed between the second water supply port 302 and the second discharge port 402 close to the second discharge port 402 side, and the main heating heater 600 is the preheating heater ( Hybrid instantaneous hot water device comprising a preheater, characterized in that arranged to cover an area where 600) is present.

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