KR101594337B1 - Hot water tank having heater - Google Patents

Abstract

The present invention relates to a hot water tank having a heater, more specifically, a heater 120 installed at a predetermined height from a bottom of a hot water tank 100 and a shape corresponding to the heater 120 And a tank plate 140 disposed at a lower portion of the heater 120. The tank plate 140 has a groove 142 formed at the back surface thereof to receive water from an inlet of the hot water tank 100, A plurality of water outlet holes 144 are formed in the upper surface of the tank plate 140 to spray the water of the grooves 142 onto the lower surface of the heater 120. The plurality of water outlet holes 144 are formed in the heater 120 And the water sprayed on the lower surface of the heater 120 is directed from the lower surface to the upper surface along the circumferential surface of the heater 120. The heater 120 is disposed at a position directly under the heater 120, And discharged.

According to the present invention, since the high-pressure water is heated in contact with the heater in the state of fine droplets, the continuous hot water performance that instantly and continuously generates hot water can be realized.

Hot water tank, heater, tank plate, groove, head hole

Description

[0001] HOT WATER TANK HAVING HEATER [0002]

The present invention relates to a hot water tank having a heater, and more particularly to a hot water tank used for a bidet.

The bidet is a sanitary washing device that cleans the local area such as the anus by appropriately spraying the water after the user has used the toilet.

Generally, a bidet includes a hot water tank in which a heater is mounted, and the water introduced into the hot water tank is heated by a heater and is sprayed onto a local portion of the user through a nozzle.

Registration Utility Model No. 0415952 discloses a configuration for such a bidet water tank. 3 to 5, the heater 150 is installed at a predetermined distance from the bottom of the water tank 100, and the heater 150 is installed between the bottom of the water tank 100 and the heater 150 A tank plate 120 is provided, and a plurality of water outlet holes 125 are formed in the tank plate 120. When water is introduced through the inflow hole 110 formed at one side of the water tank 100, the water is sent to the lower portion of the tank plate 120, and the water is discharged through the outflow hole 125 of the tank plate 120, (150) and heated by the heater (150).

The outflow holes 125 of the tank plate 120 are uniformly distributed over the entire surface of the tank plate 120 and the diameter of the outflow holes 125 is relatively large as about 2 to 3 mm. Accordingly, the water introduced into the lower portion of the tank plate 120 rises to a weak pressure through the water outlet 125 of the tank plate 120 and is filled from below. ).

However, according to the hot water tank operating in this manner, since the water level of the water rises so as to contact the heater, there is the following problem.

First, the water level rises and it takes time to contact the heater.

Second, even if the water level rises, the heat from the front of the heater can not be completely absorbed until the heater is completely immersed in the water.

Third, even if the heater is completely immersed in water, only the water that is in contact with the heater is directly heated by the heater, and the water that is not in contact with the heater is indirectly heated by the heat flow.

Fourth, since the water in the liquid state directly contacts the heater, the heat transfer efficiency is low.

For the reasons described above, the conventional hot water tank is not suitable for realizing continuous hot water performance that instantly generates hot water.

It is an object of the present invention to provide a hot water tank capable of continuously generating hot water by instantly heating the supplied water without waiting time.

According to a first aspect of the present invention, there is provided a hot water tank including a heater disposed at a predetermined height from a bottom of a hot water tank, a tank disposed at a lower portion of the heater, And a plurality of water outlet holes are formed on the upper surface of the tank plate for spraying the water of the water groove into the lower surface of the heater. Wherein the plurality of water outlet holes are disposed at a position directly under the heater, the heater is formed by a tube having a circular section, and water sprayed on the lower surface of the heater flows from the lower surface to the upper surface along the circumferential surface of the heater A hot water tank having a heater which is discharged to move is provided.

According to the second aspect of the present invention, the plurality of outflow holes are arranged at regular intervals.

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According to a third aspect of the present invention, the diameter of the outflow hole is formed to be small so that sprayed water is injected through the outflow hole.

According to a fourth aspect of the present invention, the heater and the tank plate are formed in a U-shape with a bent portion, and the tank plate is provided with a connecting member connecting both sides of the U-shape.

According to a fifth aspect of the present invention, there is provided, at one side of the tank plate, a guide member for guiding water introduced into an inlet of the hot water tank into the groove, and water guided through the guide member into the groove, And branches to both sides of the part.
According to a sixth aspect of the present invention, the outflow hole is disposed corresponding to the shape of the heater.

According to the present invention, since all the water discharged through the water outlet holes is directly heated by contact with the heater, the temperature rise is faster than the indirect heating by the conventional thermal flow.

Further, since the heated water flows on the circumferential surface of the heater and comes into contact with the whole surface of the heater, it is possible to absorb all of the heat energy emitted from the heater.

Further, since the water in contact with the heater is in a state of fine droplets having a large surface area, effective heat transfer is achieved, and it is possible to realize continuous hot water performance that continuously generates hot water.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 shows a state in which a tank plate 140 is installed in a hot water tank 100 according to the present invention. FIG. 2 is a sectional view of a hot water tank 100 according to the present invention, FIG. 3 is a cross-sectional view taken along line AA of FIG. 2. FIG.

1 to 3, the hot water tank 100 includes a heater 120 and a tank plate 140.

The heater 120 is installed at a predetermined height from the bottom of the hot water tank 100. The heater 120 is formed by a U-shaped tube having an intermediate portion folded. Both ends of the heater 120 are fixedly installed through the side surface of the hot water tank 100. The cross section of the heater 120 is formed in a circular shape. The heater 120 may be made of brass or stainless steel, and a heat coil and a filler may be fixed therein.

The tank plate 140 is installed at the bottom of the hot water tank 100 and is formed in a U shape corresponding to the heater 120 at a lower portion of the heater 120. A groove portion 142 is formed on the back surface of the tank plate 140. When the tank plate 140 is installed at the bottom of the hot water tank 100, the groove portion 142 of the tank plate 140 and the hot water tank 100, Thereby forming a flow path through which water can flow.

On the upper surface of the tank plate 140, an outlet hole 144 is formed which is in fluid communication with the groove portion 142. A plurality of outflow holes 144 are provided at regular intervals along the longitudinal direction of the tank plate 140. A plurality of water outlet holes 144 are formed in the upper surface of the tank plate 140 along the longitudinal direction so that the plurality of water outlet holes 144 are formed in a shape corresponding to the heater 120, (120), and is opened toward the heater (120) directly below the heater (120). The diameter of the water outlet hole 144 is preferably 1.2 mm or less.

A guide member 146, which is in fluid communication with an inlet (not shown) of the hot water tank 100, is installed at one side of the tank plate 140. The guide member 146 is formed in an "a" shape, and serves to guide water flowing through the inlet port into the groove portion 142 of the tank plate 140.

Meanwhile, a connecting member 148 connecting both sides of the U-shaped tank plate 140 may be provided in the middle of the U-shaped tank plate 140 to improve the durability of the tank plate 140. At this time, the connecting member 148 may be formed to protrude and be coupled to an upper cover (not shown) of the hot water tank 100.

A method of heating water in the hot water tank 100 configured as described above will be described.

4 is a rear view of the tank plate 140 according to the present invention showing the flow path of water formed in the groove portion 142. FIG 5 is a sectional view of the tank plate 140 according to the present invention, Fig. 6 is a sectional view taken along the line AA in Fig. 5. Fig.

4, the water flowing through the inlet of the hot water tank 100 flows along the guide member 146 and is supplied into the groove portion 142 of the tank plate 140. When water is supplied into the groove portion 142 of the tank plate 140 from the guide member 146, water flows to both sides of the groove portion 142. [ A protrusion 143 may be provided at a portion where the guide member 146 and the groove portion 142 are connected to each other to help water flow to both sides. It is preferable that the protrusion 143 is formed in a triangular shape in which both sides are curved in a curved line.

5, the water supplied into the groove portion 142 is discharged through the outlet hole 144 formed in the upper surface of the tank plate 140. As shown in FIG. The water discharged through the outlet hole 144 is sprayed on the lower surface of the heater 120 because the outlet hole 144 is opened toward the heater 120 directly below the heater 120. [ The water pressure in the groove portion 142 is high and the high-pressure water can be injected into the heater 120 through the outlet hole 144 because the diameter of the outlet hole 144 is very small, not more than 1.2 mm.

6, high-pressure water sprayed to the lower surface of the heater 120 through the water outlet hole 144 moves on the circumferential surface of the heater 120 from the lower surface of the heater 120 to the upper surface. Therefore, the water discharged through the outlet hole 144 can be heated by receiving heat from the heater 120 while flowing along the circumferential surface of the heater 120. Further, the diameter of the water outlet hole 144 is very small, so that the water discharged through the water outlet hole 144 is almost discharged in a spray state. Since the fine droplets in the sprayed state have a large surface area, the heat transfer can be effectively performed when contacting the heater 120.

The operation and effect of the hot water tank 100 operating as described above will be summarized as follows.

First, since the water discharged through the water outlet hole 144 directly contacts the heater 120 and is heated, the water is heated regardless of the water level.

Second, the water discharged through the water outlet hole 144 flows on the circumferential surface of the heater 120 due to the strong water pressure, so that the water contacts the front surface of the heater 120 and can effectively absorb heat.

Third, all the water discharged through the water outlet hole 144 comes into contact with the heater 120 and is directly heated.

Fourth, since water discharged through the water outlet hole 144 is a fine droplet having a large surface area, effective heat transfer can be achieved by contacting the fine droplet with the heater 120.

That is, according to the hot water tank of the present invention, continuous hot water performance capable of instantly generating hot water can be realized by heating the high-pressure water in contact with the heater in a fine droplet state. The hot water tank of the present invention can be applied to various devices requiring hot water such as a bidet, a water purifier, and the like.

1 shows a state in which a tank plate 140 is installed in a hot water tank 100 according to the present invention.

FIG. 2 shows a state in which the tank plate 140 and the heater 120 are installed in the hot water tank 100 according to the present invention.

3 is a sectional view taken along the line A-A in Fig.

Fig. 4 is a rear view of the tank plate 140 according to the present invention, showing a flow path of water formed in the groove portion 142. Fig.

FIG. 5 shows a flow path of water discharged from the water outlet hole 144 of the tank plate 140 according to the present invention.

6 is a sectional view taken along the line A-A in Fig.

Description of the Related Art [0002]

100 hot water tank 120 heater

140 tank plate 142 groove portion

144 guide hole 146 guide member

148 connecting member

Claims (6)

A heater 120 installed at a predetermined height from the bottom of the hot water tank 100, And a tank plate (140) having a shape corresponding to the heater (120) and disposed at a lower portion of the heater (120) A groove portion 142 for receiving water from an inlet of the hot water tank 100 is formed on the back surface of the tank plate 140, On the upper surface of the tank plate 140 are formed a plurality of water outlet holes 144 for spraying the water of the groove portion 142 onto the lower surface of the heater 120, The plurality of outflow holes 144 are disposed at a position directly below the heater 120, The heater 120 is formed as a tube having a circular section, And a heater that discharges water sprayed on the lower surface of the heater (120) so as to move from the lower surface to the upper surface along the circumferential surface of the heater (120). The method according to claim 1, Wherein the plurality of outflow holes (144) are arranged at regular intervals. The method according to claim 1, Wherein a diameter of the water outlet hole (144) is formed so as to spray water in a sprayed state through the water outlet hole (144). The method according to claim 1, The heater 120 and the tank plate 140 are formed in a U shape having a bent portion, Wherein the tank plate (140) is provided with a connecting member (148) connecting both sides of a U shape. The method according to claim 1, A guide member 146 for guiding the water introduced into the inlet of the hot water tank 100 into the groove 142 is provided at one side of the tank plate 140, Wherein the water guided into the groove portion (142) through the guide member (146) branches off to both sides of the groove portion (142). The method according to claim 1, Wherein the outlet hole (144) is disposed corresponding to the shape of the heater (120).

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