KR101564263B1 - Heating system for hot water and water purifier having the same - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a hot water heating system and a water purifier having the same, and more particularly, to a hot water heating system capable of increasing an instantaneous heating capacity without increasing the size of an appearance, .
[0001] The present invention relates to a hot water heating system and a water purifier having the same, and more particularly, to a hot water heating system and a water purifier having the hot water heating system. The hot water heating system includes a case, a cylindrical heating part disposed inside the case, a spiral flow path formed between the case and the heating part, And a tightening spring provided between the cylindrical heating part and the temperature sensing part.

Description

TECHNICAL FIELD [0001] The present invention relates to a hot water heating system and a water purifier having the same,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a hot water heating system and a water purifier having the same, and more particularly, to a hot water heating system capable of increasing an instantaneous heating capacity without increasing the size of an appearance, .

A water purifier is a device that supplies drinking water that can be safely removed by removing foreign matter of water to a certain level or less. The water purifier may be configured to include a main body having a water supply space and a filter for removing foreign matter from the water.

In recent years, in addition to a water supply function, which is a basic function of a water purifier that removes and supplies foreign matter of water, there is further provided a cold / hot water supply function for cooling purified water or heating purified water to supply hot water at a predetermined temperature.

More particularly, to a filter which is a general constitution of a water purifier, and a cooling system using a refrigerant, which is a general constitution of a heater and a water heater, which are general components of a water heater.

1 shows a general shape of a conventional water purifier having a function of supplying cold and hot water. As shown in FIG. 1, the conventional water purifier includes a main body 1 forming an outer appearance, a filter 2 installed at the center of the main body to purify raw water flowing into the main body, A cold water unit 5 including a water reservoir 3 for supplying water, a hot water unit 4 including a heater for heating water from the water reservoir, a cooling system (not shown) for generating cold water, And a hot water intake cock (7) and a cold water intake cock (6) connected to the hot water part and the cold water part and projecting to the outside of the main body so as to receive cold water and hot water, respectively, A hose for forming a hose, and wiring for control and the like.

In the water purifier provided with the conventional hot water supply function, the hot water to be supplied is stored in the hot water tank, and the heating means is operated periodically (or intermittently) so that the hot water can be maintained at a constant temperature. .

Also, in the early stage of the hot water supply, the hot water flowing out of the hot water tank moves along the hot water passage and the temperature is lowered, so that the temperature of the hot water relatively low at the beginning of the hot water supply can be lowered.

In consideration of such a problem, in some water purifiers, a so-called instant heating water supply system is used in which an electric heater is disposed on one side of the flow path so that water is heated by the heater while the water flows along the flow path.

In such a conventional instantaneous water supply system, since the one side of the heater is configured to be used for heating the water, the flow path can be relatively long, so that the size of the hot water supply system can be increased. In addition, since a heater having a relatively large heating value is required, the power consumption can be increased.

In addition, since a heater having a large calorific value due to instantaneous heating is used, there is a risk of damaging the system due to local high temperature. Even if a fuse is installed as a safety device, the plastic water supply system is interposed between the time intervals for blocking by the fuse The problem of melting may occur.

Accordingly, it is an object of the present invention to provide a hot water heating system and a water purifier having the same, which can increase the heating capacity without increasing the outer size.

It is another object of the present invention to provide a hot water heating system capable of quickly preventing breakage due to heating and a water purifier having the same.

Disclosure of Invention Technical Problem [8] The present invention provides the following structure to solve the problems of the conventional art.

The present invention relates to a hot water heating system, which comprises a case, a cylindrical heating part disposed inside the case, a spiral flow path formed between the case and the heating part, a temperature sensing part provided below the case, And a tightening spring provided between the heating part and the temperature sensing part.

The tightening spring is constituted by a cone spring. The initial length of the tightening spring is configured to be longer than the interval between the lower portion of the case and the cylindrical heating portion. So that the cylindrical heating portion can be brought into close contact with the elastic force of the urging spring when the cylindrical heating portion is engaged with the case.

Further, the tightening spring is configured to be thermally conductive. Accordingly, when there is no water in the case and the cylindrical heating part is overheated, heat can be directly transmitted to the temperature sensing part through the tightening spring.

Further, the hot water heating system of the present invention includes a case, a cylindrical heating part disposed inside the case, a spiral flow path formed between the case and the heating part, a flow path forming part forming the spiral flow path, A temperature sensing part provided in the lower part of the case, and a tightening spring provided between the cylindrical heating part and the temperature sensing part.

The flow path forming part is configured to be formed by a flow path, and the case is configured such that a coupling groove to which the flow path spring is coupled is formed in a spiral shape. Further, the above-mentioned flow path is constituted so as to be thermally conductive. So that the flow path spring contacts the inner wall of the case and transfers heat to the safety device to enable the safety device to operate.

The safety device may include a fuse, and the fuse may be operated by heat transfer by the flow path. Accordingly, when there is no water in the case and the cylindrical heating portion is overheated, the heat is directly transmitted to the safety device through the flow path spring to cut the fuse.

According to another aspect of the present invention, there is provided a water purifier including a case, a cylindrical heating unit disposed inside the case, a spiral flow path formed between the case and the heating unit, a temperature sensing unit provided below the case, And a hot-water heating system including a contact spring provided between the heating unit and the temperature sensing unit.

The water purifier of the present invention may further include a case and a cylindrical heating part disposed inside the case, a spiral flow path formed between the case and the heating part, a flow path forming part forming the spiral flow path, And a hot water heating system including a safety device, a temperature sensing part provided at the lower part of the case, and a tightening spring provided between the cylindrical heating part and the temperature sensing part.

The present invention has the following effects with the above-described configuration.

The present invention is configured such that the initial length of the tightening spring is longer than the interval between the lower portion of the case and the cylindrical heating portion so that the cylindrical heating portion and the temperature sensing portion are closely contacted by the elastic force of the close- . So that it is possible to prevent the case where the overheat of the cylindrical heating part is not sensed.

In addition, since the heat is directly transmitted to the temperature sensing part through the thermally conductive contact spring, if the cylindrical heating part is overheated because there is no water in the case, the safety device is activated to prevent damage due to overheating of the heating part Effect.

Also, the flow path forming portion is formed of a thermally conductive flow path spring, and the flow path spring contacts the inner wall of the case to directly transmit heat to the safety device portion so that the safety device can be operated. And thereby the fuse of the stabilizer unit is cut off, thereby preventing the damage caused by overheating of the heating unit in advance.

1 is a schematic view of a conventional water purifier;
2 is a schematic view of a water purifier of the present invention.
3 is a schematic view of a hot water heating system of the present invention.
4 is a cross-sectional view of the hot water heating system of the present invention.
5 is an exploded view of the hot water heating system of the present invention.
6 is a partial cross-sectional view of the hot water heating system of the present invention.

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

Fig. 2 is a schematic view of the water purifier of the present invention, Fig. 3 is a schematic view of the hot water heating system of the present invention, Fig. 4 is a sectional view of the hot water heating system of the present invention, Figure 6 shows a partial cross-sectional view of the hot water heating system of the present invention.

As shown in FIG. 2, the water purifier of the present invention is basically provided with a filter 10 and a water storage tank 20. As shown in FIG. 2, the filter functions to remove suspended solids, rust and various harmful substances contained in raw water such as tap water flowing from water conduction, It is not shown in detail and a detailed description is omitted. A water supply valve (25) may be provided at the entrance of the water storage tank (20) so as to open and close a passage. The purified water passing through the filter 10 can be introduced into the water storage tank 20 when the water supply valve 25 is opened.

The water storage tank 20 temporarily stores the purified water to keep the flow rate of the water purifier sufficiently. In particular, in the case of a water purifier capable of supplying both cold and hot water, it is difficult to generate a sufficient amount of cold water and hot water when necessary unless a sufficient flow rate is ensured through stored water, and sudden cooling or heating is preferable because power consumption is excessively required not. Therefore, it is necessary to secure a sufficient flow rate through these reservoirs.

In order to secure sufficient flow rate, cold water purifier may be equipped with cold water tank and hot water tank. As shown in FIG. 2, the cold water tank 30 functions to generate and temporarily store cold water, and a cooling system is provided to generate cold water.

The cooling system includes a compressor, a condenser connected to the compressor through a pipe, a capillary connected to the condenser through a pipe, and an evaporator connected to the capillary through a pipe and connected to the compressor. In the evaporator (40), refrigerant of high temperature and high pressure, which is derived from the compressor, is heat-exchanged in a state of low temperature and high pressure. In the capillary, refrigerant from the condenser And the refrigerant evaporates due to the heat exchange between the refrigerant and the purified water. With the above arrangement, a cooling cycle is formed. The above components are connected through piping.

2, the evaporator 40 allows heat exchange between the refrigerant and the cold water tank 30 to generate cold water. That is, the evaporator is provided so as to surround the cold water tank 30, so that the refrigerant flowing through the evaporator absorbs heat from the cold water of the cold water tank. In order to maintain the temperature of the cold water tank at about 4.5 캜, it is preferable to select a refrigerant whose vaporization temperature of the refrigerant is 4.5 캜 or lower. Since the kind of the refrigerant does not affect the present invention, a detailed description thereof will be omitted.

2, a cold water outflow pipe may be provided on one side of the cold water tank 30, and a cold water supply valve 35 may be provided on the cold water outflow pipe so as to open and close an internal flow path.

A separate hot water tank (not shown) may be provided for the hot water supply. A heater (not shown) for generating hot water may be provided in the hot water tank. The present invention provides an instantaneous hot water heating system capable of instantly generating hot water instead of a hot water bath. Therefore, the hot water tank is not shown in detail, and only the hot water heating system of the present invention is shown in detail in FIG.

2 and 3, the hot water heating system 60 of the present invention includes a case 61, a cylindrical heating part 62 disposed inside the case, a spiral flow path 62 formed between the case and the heating part, A temperature sensing unit 64 provided at a lower portion of the case, and a tightening spring 65 provided between the cylindrical heating unit and the temperature sensing unit.

The case 61 is configured to have a cylindrical receiving space therein. As shown in FIG. 2, an inlet 51 is formed at one side of the case 61 so that water can flow into the case. The inlet (51) is formed in the upper region of the case.

The inlet (51) is connected to the water reservoir (20). The pipe between the inflow port and the water storage tank may be provided with a hot water supply valve 50 for opening and closing a purified water pipe coming into the inflow port. According to this configuration, the water in the water storage tank 20 can be supplied to the inside of the hot water heating system 60 when the hot water valve 50 is opened.

A cylindrical heating part (62) is housed in the inner space of the case. The cylindrical heating part 62 may be a cylindrical electric heater that generates heat when power is applied.

The cylindrical heating part 62 is formed as a circular pipe so that the internal flow path 68 can be formed. As a result, as shown in Fig. 4, the inner and outer surfaces of the cylindrical heating part 62 all come into contact with water, and the water can be heated. 4, the water introduced through the inlet 51 is heated by the outer surface of the cylindrical heating part while flowing to the lower part of the case through a spiral flow path 63 to be described later, and the water inside the cylindrical heating part And is again heated by the inner surface of the cylindrical heating part while rising through the flow path 68. [ Hot water can be instantly generated by this process.

Meanwhile, the cylindrical heating part 62 may be coupled to the case such that one end thereof is exposed to the outside of the case 61 and the other end thereof is spaced apart from the inner bottom surface of the case by a predetermined distance. Here, the end portion drawn out to the outside of the case may be defined as an outlet 52 of the hot water heating system 60 in that the water flows out to the outside.

A spiral flow path (63) is formed between the case and the cylindrical heating part. As shown in FIG. 3, the spiral flow path 63 is formed in a spiral shape so as to surround the cylindrical heating part.

The spiral passage 63 can increase the mutual heat exchanging area between the water and the cylindrical heating part 62 without increasing the size of the case 61 and the cylindrical heating part 62. That is, a flow path is formed so that water can flow as if it surrounds a cylindrical heating part in a spiral shape, and the heat exchange area is increased rather than just flowing by gravity.

The spiral flow path 63 may be formed at the same pitch. Thus, the speed of the water flowing along the spiral flow path 63 can be made constant. With this configuration, the flow velocity of the water is constant, so that the effect of effectively suppressing the boiling phenomenon in which bubbles are generated in a specific region of the cylindrical heating section 62 is generated.

In the present invention, the spiral flow path is formed by the flow path forming portion 63. The flow path forming portion is a coil spring (hereinafter referred to as a "flow path") as shown in FIG.

As shown in FIG. 6, a spiral coupling groove may be formed around the inner receiving space of the case so that the flow path forming part 62 may be coupled to the flow path forming part 62. So that the case can be spirally rotated and lowered to be engaged with the coupling groove when the flow path spring is engaged with the case.

As described above, when the flow path, which is a flow path forming part, is coupled to the case, the flow path comes into contact with both the cylindrical heating part and the case, thereby forming a flow path between the pitches of the spring.

The flow path spring has a metallic material having thermal conductivity. In addition, the flow channel contacts the inner wall of the case to transmit heat to the safety device to enable the stabilizer to operate.

The safety device 67 is provided with a fuse. So that the fuse can be operated by heat transfer by the flow path. More specifically, since the cylindrical heating portion and the flow path spring are in contact with each other, and the flow path spring is thermally conductive, the heat of the cylindrical heating portion can be directly transmitted to the safety device portion.

Accordingly, in general, water is heated inside the case to prevent overheating of the cylindrical heating part 62. However, when water is insufficient or the cylindrical heating part overheats abnormally, heat is transmitted to the safety device part to break the fuse . Generally, since the case is formed of a synthetic resin material, it melts upon exposure to a high temperature. In the present invention, when abnormally overheating occurs in the cylindrical heating part, the time for sensing the safety device is shortened, There is an effect to be prevented.

As shown in FIG. 4, a temperature sensing unit 64 is provided in a lower portion of the case. The temperature sensing unit 64 may be configured with a thermostat that senses an internal temperature of the case heated by the cylindrical heating unit and suppresses an internal temperature of the case from rising excessively.

Here, the thermostat is configured to shut off the power input of the cylindrical heating unit if the temperature inside the case is detected by the temperature sensing unit 64 to exceed the set temperature.

The temperature sensing part can directly sense the temperature of the cylindrical heating part by the tightening spring 65. [ As shown in FIG. 4, the tightening spring 65 is provided between the cylindrical heating part and the temperature sensing part.

The tightening spring 65 is constituted by a cone spring. As shown in FIG. 4, the initial length of the tightening spring is formed to be longer than the interval L between the lower portion of the case and the cylindrical heating portion. On the other hand, the tightening spring is formed of a metal member having thermal conductivity.

According to the above configuration, the cylindrical heating part can be brought into thermal contact with the temperature sensing part by the elastic force of the tightening spring. Accordingly, when the temperature of the cylindrical heating unit is excessively increased, the temperature sensing unit 64 can quickly detect the temperature of the cylindrical heating unit by the tightening spring 65. Further, the power of the cylindrical heating unit is quickly cut off by the thermostat, thereby preventing the adverse effect due to the overheating from being diffused in advance. On the other hand, in the above configuration, if there is sufficient water inside, the temperature of the cylindrical heating portion does not rise excessively, and the thermostat does not operate.

The present invention configured as above operates as follows.

When the hot water valve 50 is opened, hot water is supplied and power is applied to the cylindrical heating part 62. The water (purified water) of the water storage tank flows into the spiral flow path 63 formed on the outside of the cylindrical heating part 62 through the inlet port 51.

The water spirally downward flowing along the spiral flow path is heated in contact with the outer surface of the cylindrical heating part 62. The water that has reached the bottom of the case flows upward along the inner flow path 68 of the cylindrical heating part and is heated again when it comes into contact with the inner surface of the cylindrical heating part and the temperature rises as required.

The water reaching the upper part of the cylindrical heating section flows out through the outlet port 52 and is supplied with water.

On the other hand, when the water supplied through the water storage tank is insufficient, the spiral flow path and the flow path inside the cylindrical heating unit become insufficient, and the cylindrical heating unit abnormally overheats and the temperature rises.

Such a temperature rise causes heat transfer to the safety device through the flow path of the flow path forming part 66 so that the fuse of the safety device is cut off and the power supplied to the cylindrical heating part is cut off. At the same time, the temperature rise causes the thermostat to operate by causing the thermostat to transmit to the temperature sensing part through the tightening spring, so that the power supplied to the cylindrical heating part is cut off.

The cutoff of the power supplied to the cylindrical heating unit may be performed by a safety device or a thermostat of the temperature sensing unit. Accordingly, the present invention can cut off the power supplied to the cylindrical heating unit as quickly as possible, and thus has the effect of preventing double damage of the hot water heating system due to overheating of the heating unit.

The present invention also relates to a water purifier equipped with the hot water heating system as described above. The water purifier includes a case 61, a cylindrical heating part 62 disposed inside the case, a spiral flow path 63 formed between the case and the heating part, a temperature sensing part And a hot water heating system including a contact spring 65 provided between the cylindrical heating part and the temperature sensing part.

The water purifier of the present invention may be configured to include a hot water heating system further including a safety device 67 provided outside the case.

The descriptions of these water purifiers overlap with those of the hot water heating system described above, so that a detailed description thereof will be omitted.

While the preferred embodiments of the present invention have been described with reference to the accompanying drawings, it is to be understood that the scope of the present invention should not be construed as being limited to the embodiments and / or drawings, do. It is to be expressly understood that improvements, changes and modifications apparent to those skilled in the art are also within the scope of the present invention.

10: filter 20: water tank
30: cold water tank 40: evaporator
50: hot water valve 51: inlet
52: outlet 60: hot water heating system
61: Case 62: Cylindrical heating part
63: Spiral flow path 64: Temperature sensing part
65: tight contact spring 66:
67: safety device part 68: inner flow path
69: Coupling groove

Claims (12)

case;
A cylindrical heating part disposed inside the case;
A spiral flow path formed between the case and the cylindrical heating part;
A temperature sensing unit provided in a lower portion of the case; And
A tightening spring provided between the cylindrical heating part and the temperature sensing part;
The hot water heating system.
The method according to claim 1,
Characterized in that the tightening spring is a cone spring.
Hot water heating system.
3. The method of claim 2,
Wherein the initial length of the tightening spring is longer than the distance between the lower portion of the case interior and the cylindrical heating portion.
4. The method according to any one of claims 1 to 3,
The tightening spring is a thermally conductive, hot water heating system
case;
A cylindrical heating part disposed inside the case;
A spiral flow path formed between the case and the heating unit;
A temperature sensing unit provided in a lower portion of the case; And
And a tightening spring provided between the cylindrical heating part and the temperature sensing part.
A water purifier with a hot water heating system.
case;
A cylindrical heating part disposed inside the case;
A spiral flow path formed between the case and the heating unit;
A flow path forming part forming the spiral flow path;
A safety device provided outside the case;
A temperature sensing unit provided in a lower portion of the case; And
A tightening spring provided between the cylindrical heating part and the temperature sensing part;
The hot water heating system.
The method according to claim 6,
Wherein the flow path forming portion is a flow path spring.
8. The method of claim 7,
Wherein the coupling groove in which the flow path spring is coupled is formed in a spiral shape inside the case.
8. The method of claim 7,
The flow path is a thermally conductive, hot water heating system.
10. The method of claim 9,
Wherein the channel is in contact with an inner wall of the case to transmit heat to the safety device to enable the stabilizer to operate.
11. The method of claim 10,
Wherein the safety device comprises a fuse,
Wherein said fuse can be operated by heat transfer by said flow path spring.
case;
A cylindrical heating part disposed inside the case;
A spiral flow path formed between the case and the heating unit;
A flow path forming part forming the spiral flow path;
A safety device provided outside the case;
A temperature sensing unit provided in a lower portion of the case; And
And a tightening spring provided between the cylindrical heating part and the temperature sensing part.
A water purifier with a hot water heating system.

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