KR101199743B1 - Instantaneous hot water producing device - Google Patents

Abstract

PURPOSE: An instant hot water generation device is provided to reduce the volume of a heating module because the heating module has a simple two-piece structure composed of first and second water tub plates. CONSTITUTION: An instant hot water generation device comprises a heating module and an electric heater(150). The heating module comprises first and second water tub plates(110,130), an inlet port(131), and an outlet port(133). The second water tub plate is arranged in parallel to the first water tub plate and joined to be faced to the first water tub plate. A flow path(132) is formed in between the inner surface of the first water tub plate and the second water tub plate. Tap water having flown into the inlet port flows through the flow path. The electric heater is attached on a side of the heating module and heats the tap water while the tap water flows through the flow path.

Description

Instantaneous hot water producing device

The present invention relates to an instantaneous hot water generating device, and more particularly, to an instantaneous hot water generating device which is provided in a cold / hot water purifier or an instant hot water heater to heat raw water introduced from the outside to provide hot water.

Recently, as the function of the water purifier becomes more advanced and diversified, in addition to simply providing purified water, a cold and hot water supply function capable of immediately providing cold water below 10 ° C. and hot water above 90 ° C. is being added to the water purifier. In general, a water purifier having a cold / hot water supply function purifies water supplied from the outside through various filters and stores it in a purified water tank, and supplies the water stored in the purified water tank to a separate hot water tank and a cold water tank to provide a heater in the hot water tank. The water is heated through, and the cold water tank uses a cooler to cool.

Typically, the water stored in the hot water tank is heated by a heater installed in the hot water tank to maintain a predetermined temperature or more. A heater installed in the hot water tank and heating the water so as to maintain the temperature of the water stored in the hot water tank at a constant temperature is generally called a siege heater. The water stored in the hot water tank by the sheath heater is maintained at a constant temperature, and when the high temperature water is required by the user, the water temperature is increased and discharged.

Such a conventional hot water heating device uses a sheath heater to maintain the temperature of the hot water in the hot water tank even if the user does not use hot water, so there is a problem in the amount of electricity used. In addition, since the size of the hot water tank is large, there is a problem in that the size of the water purifier in which the hot water heating device is installed increases.

Korea Patent Registration No. 10-0852511

The present invention provides a simple hot water generating device that is simple in structure and small in volume, and increases the flow time of the raw water supplied from the outside without storing the hot water so that the raw water can be instantaneously heated and supplied as hot water while the raw water flows. It aims to provide.

The present invention, the inlet is formed on one side, the outlet is formed on the other side, the heating module has a flow path through which the raw water introduced through the inlet flows; And an electric heater attached to one side of the heating module and heating the raw water while the raw water flows through the flow path, wherein the heating module comprises: the first water tank plate; And a second tank plate disposed in parallel with the first tank plate and coupled to face the first tank plate to form the flow path between the inner surface of the first tank plate. Provide a device.

Instantaneous hot water generating device according to the present invention has the following effects.

Since the heating module has a simple and simple structure of 2 pieces consisting of only the first and second tank plates, the heating module may be reduced in volume, and thus, the heating module may be provided in a small sized cold / hot water purifier or instantaneous water heater.

And as the structure is simplified, it can have the effect of reducing the cost and time required to manufacture the heating module.

In addition, unlike the conventional method in which the raw water is stored and heated, since the raw water is instantaneously heated and discharged while being introduced into the heating module and flowed and discharged, there is no need to maintain the temperature of the stored hot water unnecessarily. Therefore, not only can the hot water be supplied quickly, but the electricity consumption is greatly reduced.

Since the heating module has a zigzag-shaped flow path, even if the size of the heating module is small, the raw water flows for a long time, so that the raw water can be heated for a long time to provide heated raw water of a desired temperature.

Air in the heating module, that is, steam generated during heating moves along the zigzag-shaped flow path upward and is discharged to the outside through the air vent hole, so that the outside of the steam is easily discharged.

1 is an exploded perspective view of an instantaneous hot water generating device according to an embodiment of the present invention.
2 is a perspective view of the instantaneous hot water generating device according to FIG.
3 is a cross-sectional view of the instantaneous hot water generating device according to FIG.
4 is a front view of the electric heater of the instantaneous hot water generating device according to FIG. 1.

Hereinafter, the present invention will be described in more detail. In interpreting the terms or words used in the present specification and claims below, the inventors must be conventional or not based on the principle that the inventors can appropriately define the concept of terms in order to best explain their invention. It should not be construed as being limited only to a dictionary meaning, but it should be understood that it should be interpreted as meanings and concepts corresponding to the technical spirit of the present invention as described herein.

1 is an exploded perspective view of the instantaneous hot water generating device according to an embodiment of the present invention, FIG. 2 is a perspective view of the instantaneous hot water generating device according to FIG. 1, and FIG. 3 is an instantaneous hot water generating device according to FIG. 1. 4 is a cross-sectional view of the electric heater of the instantaneous hot water generating device according to FIG. 1.

1 to 4, another instant hot water generating device according to an exemplary embodiment of the present invention includes heating modules 110 and 130 and an electric heater 150. The heating module 110, 130 is formed with an inlet 131 on one side and an outlet 133 is formed on the other side, a flow path 132 through which the raw water introduced through the inlet 131 flows is formed therein. do.

Looking at the heating module (110, 130) in more detail, the heating module (110, 130) includes a first tank plate 110, and a second tank plate 130. As shown in FIG. 1, the first tank plate 110 and the second tank plate 130 are formed in the form of a rectangle. However, the first bath plate 110 and the second tank plate 130 are limited to the present embodiment. It may be formed in the form.

As shown in FIG. 1, the first bath plate 110 is formed in a rectangular shape and has a predetermined depth to allow the raw water to flow. The depth of the first tank plate 110 is formed to the same depth as the thickness of the protruding partition 135 formed in the second tank plate 130 to be described later. This will be described later, when the first tank plate 110 and the second tank plate 130 is assembled, the protruding partition 135 is in close contact with the inner surface of the first tank plate 110 while the flow path ( 132 is formed.

In the present embodiment, the second tank plate 130 assembled with the first tank plate 110 is formed in the same rectangular shape as the first tank plate 110. The second tank plate 130 is formed in a plane unlike the first tank plate 110, and as described above, a protruding partition 135 is formed toward an inner surface of the first tank plate 110. When the first tank plate 110 and the second tank plate 130 are assembled, the protruding partition 135 is in close contact with the inner side surface of the first tank plate 110, and the first tank plate 110. The flow path 132 is formed by a spaced space between an inner side surface of the c) and an inner side surface of the second tank plate 130 in which the protruding partition 135 is not formed.

The first tank plate 110 and the second tank plate 130 is formed of a metal plate, it can be produced at a low cost by using a pressing process. However, the first tank plate 110 and the second tank plate 130 need not be limited to the metal plate, and may be formed by injecting plastic.

1 and 2, the plurality of protruding partitions 135 formed on the second tank plate 130 are spaced apart from each other along the longitudinal direction of the second tank plate 130. The protruding partition 135 is formed in a direction crossing the length direction of the second tank plate 130. The protruding partition 135 is formed by extending from one side of the second tank plate 130 toward the other side of the first barrier rib 135a and the other side of the second tank plate 130. It includes a second protrusion partition 135b extending toward the side edge.

Meanwhile, in the present exemplary embodiment, the protruding partition wall 135 is formed only on the second tank plate 130, but the protruding partition wall may be formed on each of the first bath plate 110 and the second bath plate 130. .

Referring to the drawings, it can be seen that the protruding partition 135 is inclined upward in a direction from the lower side of the second tank plate 130 to the upper side. When the protruding partition 135 is formed to be inclined as described above, the speed at which the raw water flows into the heating modules 110 and 130 may be slowed down, thereby increasing the time for the raw water to be heated. On the other hand, the protruding partition 135 is formed in this manner is not limited to the present embodiment, it is not always to be formed in this way, the protruding partition 135 is the lower side of the second tank plate 130 or It may be formed in a direction parallel to the upper side.

As described above, as shown in FIGS. 1 and 2, the protruding partition 135 may be formed by alternately interposing the first protruding partition 135a and the second protruding partition 135b. Therefore, the flow path 132 is formed in a zigzag form by the first protrusion barrier rib 135a and the second protrusion barrier rib 135b. As the flow path 132 is formed in a zigzag shape, the raw water flowing along the flow path 132 may increase the time that flows from the inlet 131 to the outlet 133.

1 and 2, the inlet 131 through which the raw water can be introduced from the outside into the second tank plate 130, and the outlet 133 through which the raw water can be discharged. Is formed. However, the inlet 131 and the outlet 133 may be formed in the first tank plate 110 instead of the second tank plate 130. The raw water is introduced into the heating modules 110 and 130 through the inlet 131 and heated while being flowed toward the outlet 133 and discharged through the outlet 133.

The heating module (110, 130) is formed with an air vent hole 137 that can discharge bubbles generated in the raw water flowing through the heating module (110, 130). More specifically, the air vent hole 137 is formed in the second tank plate 130 and is formed adjacent to the outlet port 133 formed in the second tank plate 130.

Since the air vent hole 137 is formed adjacent to the outlet port 133, bubbles generated while the raw water flows may disappear before being discharged through the outlet port 133. The air vent hole 137 may be formed at any position of the second water tank plate 130, but is not formed adjacent to the water outlet 133 as in this embodiment, the water inlet 131 and the water outlet When the air vent hole 137 is formed at an intermediate position of the air vent hole 137, bubbles may be generated again while the raw water passing through the air vent hole 137 flows toward the outlet port 133. It is good to form adjacent to 133.

The heating module 110, 130 as described above may be installed in the longitudinal direction, the inlet 131 is located at the bottom and the outlet 133 is located at the top so that the raw water from the inlet 131 As it is heated, it naturally rises toward the water outlet 133 along the zigzag-shaped flow path 132. In this case, since the specific gravity of bubbles generated in the raw water is smaller than the raw water, the bubbles are raised upward along the zigzag-shaped flow path 132 together with the raw water and discharged to the outside by the air vent hole 137.

 The electric heater 150 is attached to one side of the heating modules 110 and 130, and serves to heat the raw water while the raw water flows through the flow path 132. In the present embodiment, the electric heater 150 is attached to the outer surface of the first tank plate 110. The electric heater 150 may be attached to the second bath plate 130, but in the present embodiment, the first bath plate 110 may be connected to the electric heater 150 rather than the second bath plate 130. Since the contact area is wide, the raw water flowing through the inside of the heating module 110 and 130 may be heated more quickly when attached to the first bath plate 110.

The electric heater 150 is formed in the form of a printed circuit board (PCB). Referring to the structure of the electric heater 150 formed in the form of a PCB in more detail, the circuit 151 that can generate heat between the two film is formed by being printed, one film is a heat insulation film, the other The film may be made of an insulating film.

The heat insulation film serves to prevent the heat generated by the electric heater 150 from being transmitted to other components other than the heating modules 110 and 130 when the electric heater 150 is heated. The insulating film is generated when the electric heater 150 is in contact with the heating module (110, 130) when the electric heater 150 is attached to the heating module (110, 130) Due to this serves to prevent the heating module (110, 130) formed of a metal plate and a tourmaline short is generated.

When the electric heater 150 is supplied with power from the outside, the circuit 151 starts to generate heat, and heat generated by the electric heater 150 is transferred to the heating modules 110 and 130 to heat the raw water. have. In the present embodiment, as described above, the electric heater 150 in the form of a PCB is applied, but this is only an example and need not be limited thereto.

The instant hot water generating device may further include a bimetal unit 170. The bimetal unit 170 is mounted to the heating modules 110 and 130, and detects that the raw water of the heating modules 110 and 130 is overheated, or decreases below a set temperature when the raw water that has been heated cools down. Detect if In this embodiment, the bimetal unit 170 is mounted on the outer surface of the second tank plate 130. If the above-described electric heater 150 is attached to the second bath plate 130, the bimetal unit 170 may be mounted on the first bath plate 110.

The bimetal unit 170 includes an overheat prevention bimetal 171, a water temperature reduction bimetal 173, and a bimetal bracket 175. The overheat prevention bimetal 171 serves to sense that the raw water is not heated above a set temperature when the raw water flowing in the heating modules 110 and 130 is heated. In addition, the water temperature reduction prevention bimetal 173 serves to detect whether the raw water, which has been heated inside the heating modules 110 and 130, cools down when the temperature of the raw water falls below a preset temperature. As described above, the overheat prevention bimetal 171 and the water temperature reducing bimetal 173 are mounted to the heating modules 110 and 130, that is, the second tank plate 130 by the bimetal bracket 175. .

The overheat prevention bimetal 171 senses the temperature of the raw water being heated and stops the operation of the electric heater 150 when the temperature of the raw water is detected to be higher than a set temperature. After the operation of the electric heater 150 is stopped, the water temperature reduction prevention bimetal 173 senses the temperature of the raw water that the equation is heated, and when the temperature of the raw water is detected below the set temperature, the electric heater 150 is turned off. Restart

Looking at the operation method of the instant hot water generating device as described above are as follows. First, external raw water is introduced into the heating modules 110 and 130 through the inlets 131 of the heating modules 110 and 130. The introduced raw water flows toward the water outlet 133 through the flow path 132 formed in the heating modules 110 and 130. The raw water is heated by the electric heater 150 attached to the outside of the heating module 110, 130 while flowing toward the outlet 133.

Bubbles may occur while the raw water flows toward the outlet 133 while being heated. Therefore, when the air flows toward the outlet 133, air bubbles generated in the raw water are removed by the air vent hole 135 formed at a position adjacent to the outlet 133, and the heated air is discharged through the outlet 133. Raw water is discharged.

On the other hand, the raw water temperature is sensed by the bimetal unit 170 mounted to the outside of the heating module (110, 130). The overheat prevention bimetal 171 of the bimetal unit 170 detects whether the raw water is heated above a set temperature when the raw water is heated. The overheat prevention bimetal 171 stops the operation of the electric heater 150 when the raw water is heated above the set temperature so that the raw water is no longer heated. When the operation of the electric heater 150 is stopped, the raw water that has been heated is cooled, and at this time, the water temperature preventing bimetal 173 of the bimetal unit 170 senses whether the temperature of the raw water falls below a set temperature. The water temperature reduction prevention bimetal 173 re-heats the raw water by restarting the electric heater 150 when the temperature of the raw water falls below a predetermined temperature.

Instantaneous hot water generating device according to an embodiment of the present invention has a simple and simple structure of the heating module is composed of two pieces consisting of only the first tank plate and the second tank plate, the volume of the heating module is reduced, so the cold / On water purifier or instantaneous water heater may be provided.

And as the structure is simplified, it can have the effect of reducing the cost and time required to manufacture the heating module.

In addition, unlike the conventional method in which the raw water is stored and heated, since the raw water is instantaneously heated and discharged while being introduced into the heating module and flowed and discharged, there is no need to maintain the temperature of the stored hot water unnecessarily. Therefore, not only can the hot water be supplied quickly, but the electricity consumption is greatly reduced.

Since the heating module has a zigzag-shaped flow path, even if the size of the heating module is small, the raw water flows for a long time, so that the raw water can be heated for a long time to provide heated raw water of a desired temperature.

Air in the heating module, that is, steam generated during heating moves along the zigzag-shaped flow path upward and is discharged to the outside through the air vent hole, so that the outside of the steam is easily discharged.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

110: first tank plate 130: second tank plate
131: inlet 132: euro
133: outlet 135: air vent hole
150: electric heater 170: bimetal unit
171: overheat prevention bimetal 173: water temperature reduction bimetal
175: bimetal bracket

Claims (10)

A second tank plate disposed in parallel with the first tank plate and the first tank plate and coupled to face the first tank plate to form a flow path between the first tank plate and the inner surface of the first tank plate; A heating module having a water inlet formed at a lower side thereof, and a water outlet formed at an upper side thereof so that raw water introduced through the water inlet flows through the flow path; And
An electric heater attached to one side of the heating module and heating the raw water while the raw water flows through the flow path,
The first bath plate formed of a metal plate has a predetermined depth so that the raw water can be stored by a pressing process,
The second tank plate formed of a metal plate is formed toward the inner surface of the first tank plate by a pressing process, and is inclined upward in a direction from the lower side to the upper side of the second tank plate, and the second tank plate. It includes a plurality of protrusion partition spaced apart from each other along the longitudinal direction of,
When the first tank plate and the second tank plate are coupled, the protruding partition wall is in contact with the inner surface of the first tank plate to form the flow path,
The protruding partition wall,
Is formed in a direction crossing the longitudinal direction of the second tank plate,
A first protrusion partition wall extending from one side of the second tank plate toward the other side; And
A second protrusion partition wall extending from the other side of the second tank plate toward the one side;
The first protrusion barrier rib and the second protrusion barrier rib are alternated with each other,
The heating module is formed with an air vent hole for discharging bubbles generated in the raw water flowing through the heating module,
The air vent hole is formed closer to the outlet than the inlet, the instantaneous hot water generating device is located above the heating module. delete The method according to claim 1,
The electric heater is instantaneous hot water generating device attached to the outer surface of the first tank plate or the outer surface of the second tank plate. delete delete The method according to claim 1,
The flow path is instantaneous hot water generating device is formed in a zigzag form by the first projection partition and the second projection partition wall. The method according to claim 1,
The electric heater is instantaneous hot water generating device is formed in the form of a printed circuit board (PCB). delete The method according to claim 1,
And a bimetal unit mounted to the heating module and configured to sense that the raw water of the heating module is overheated or to detect the lowest temperature of the raw water.
The bimetal unit,
An overheat prevention bimetal which senses that the raw water is not heated above a set temperature when the raw water in the heating module is heated;
A water temperature reduction prevention bimetal which senses whether the raw water that has been heated inside the heating module cools down when the temperature of the raw water falls below a preset temperature; And
Instantaneous hot water generating device including a bimetal bracket for mounting the overheat prevention bimetal and the water temperature reduction prevention bimetal on the heating module. The method according to claim 1,
The instantaneous hot water generating device,
Instant hot water generator installed in cold / hot water purifier or hot water heater.

Images