KR200402473Y1 - Boiler - Google Patents

Abstract

A boiler is disclosed that diverges water into several branches and heats it. Since the boiler has a small diameter of the tube to be heated in which water is stored and heated, the water stored in the tube to be heated is quickly heated. Therefore, the efficiency of the boiler is improved. Moreover, since a heating part is located in the center part side of a to-be-heated tube group, a to-be-heated tube group is heated uniformly. This is economical because the heat transfer fins installed in conventional boilers are unnecessary.

Description

Boiler {BOILER}

The present invention relates to a boiler for heating water by branching into several branches.

1 is a perspective view of a conventional boiler, which will be described.

As shown in the drawing, the conventional boiler 10 has a heating unit 20 that generates fire by using gas or oil as a fuel and a heating unit 30 that is heated by the heating unit 20.

The to-be-heated part 30 is bent and installed in the case-shaped main body 31, the outer surface and the inside of the main body 31, and the heating tube 33, the heating tube (having an inlet 33a and discharge port 33b) The heat transfer fin 35 is provided in contact with the outer surface of the 33.

Thus, when the heat transfer fin 35 and the heated tube 33 are heated by the fire generated by the heating unit 20, the water introduced into the heated tube 33 through the inlet 33a is discharged ( It warms up during the movement to 33b) side, and is discharged | emitted through the discharge port 33b.

However, the conventional boiler 10 as described above is provided with a relatively large diameter of about 13 mm in order to match the consumption, and to quickly heat the water stored in the heated tube 33. A plurality of heat transfer fins 35 are provided on the outer surface of the tube to be heated 33. Due to this, there is a disadvantage that the cost of the boiler 10 rises.

In addition, due to the heat transfer fins 35, the heating unit 20 may not be installed between the heating tube 33 and the heating tube 33, and one side of the heating unit 30, that is, the heating unit 30 is not provided. The heating unit 20 is installed below the. As a result, the heat of the heating unit 20 is not uniformly transferred to the heating unit 30 has a disadvantage in that the efficiency is lowered.

The present invention was created to solve the problems of the prior art as described above, an object of the present invention is to provide a boiler that can improve the efficiency and at the same time reduce the cost.

The boiler according to the present invention for achieving the above object, the first storage unit is in communication with the inlet pipe communicating with the water source side, the water is stored, the first storage unit and one end side is in communication with the water from the first storage unit Is supplied with a plurality of heating tube group having a smaller diameter than the inlet pipe (群), the other end side of the heating tube group is in communication with the water is stored and larger than the heating tube of the heating tube group A heated portion provided with a diameter and communicating with the first reservoir portion and the second reservoir portion and having a second reservoir portion communicating with a guide tube provided with a faucet of a use place; It is provided on the central side of the portion to be heated is provided with a heating portion for heating the water stored in the portion to be heated.

Hereinafter, with reference to the accompanying drawings will be described in detail a boiler according to an embodiment of the present invention.

2 is a perspective view of a boiler according to an embodiment of the present invention.

As shown, the boiler 100 according to the present embodiment has a heated portion 110 and a heating portion 120. Water is stored in the portion to be heated 110, and the heating portion 120 generates fire to heat the portion to be heated 110. Then, the water stored in the heated portion 110 is heated.

The to-be-heated part 110 has the 1st storage part 111 provided in the sealed case shape, the to-be-heated pipe group 115, and the 2nd storage part 118 provided in the sealed case shape.

An inlet pipe 131 communicating with a water source side communicates with the first storage part 111, and the water of the water source side is stored in the first storage part 111 through the inlet pipe 131.

The heated tube group 115 is composed of a plurality of heated tubes 115a having a diameter of 2 to 3 mm, and one end side thereof communicates with the first storage portion 111. That is, one end side of the heating tube group 115 is installed through one surface of the first storage 111, the diameter of each of the heating tube (115a) is provided smaller than the diameter of the inlet tube (131).

The other end side of the heating tube group 115 communicates with the second storage unit 118, and the second storage unit 118 receives water from the heating tube group 115. That is, the other end side of the heating tube group 115 is penetrated to one surface of the second storage unit 118 facing one surface of the first storage unit 111. Thus, the water of the water source side stored in the first storage unit 111 is stored in the second storage unit 118 through the wave heating tube group 115.

The first storage unit 111 and the second storage unit 118 are communicated with each other by the guide tube 135, the faucet (not shown) of the place of use is installed on one side of the guide tube 135. Thus, when the faucet is opened, water stored in the second storage unit 118 is supplied to the place through the faucet, and when the faucet is locked, the water is stored inside the heated part 110 and the guide tube 135. do. At this time, the diameter of the guide tube 135 is provided with a large diameter of each of the heating tube (115a).

The heating part 120 is installed at the central part side of the to-be-heated part 110. In detail, the protruding pipes 111a and 118a are formed on the other surface of the first storage part 111 and the other surface of the second storage part 118, respectively, and the support pipes 119 are provided on the protruding pipes 111a and 118a. Inserted and supported. Then, the heating unit 120 is installed inside the support tube 119.

The heating unit 120 is installed inside the transparent tube 121 and the transparent tube 121 in a vacuum state in which the discharge gas is injected, and when electricity is applied, generates heat and discharges the discharge gas to generate light. The filament 123 and the transparent tube 121 are provided inside the plurality of support members 125 to prevent sagging of the filament 123. The support member 125 forms a steel wire or the like in a spiral shape. The filament 123 is inserted into the inner circumferential surface and the outer circumferential surface is in contact with the inner circumferential surface of the transparent tube 121 to prevent the filament 123 from sagging.

The heated tube group 115 is installed in a form that uniformly surrounds the outer surface of the support tube 119.

The operation of the boiler 100 according to the present embodiment configured as described above will be described.

The heating unit 120 is turned on while the water on the water source side flows into the first storage unit 111, the heated tube group 115, the second storage unit 118, and the guide tube 119. Let's do it.

Then, since the diameter of the heated tube 115a of the heated tube group 115 installed while enclosing the support tube 119 in which the heating unit 120 is embedded is very small (2-3 mm), the heated tube 115a The water stored inside of is heated quickly. And since the heating part 120 is provided in the center part of the to-be-heated tube group 115, the to-be-heated tube group 115 is heated uniformly and rapidly by the heating part 120. FIG.

When the faucet is opened to use hot water, since the water is quickly heated in the tube to be heated 115, hot water is quickly supplied through the faucet. This can reduce the amount of cold water discharged through the faucet until hot water comes out.

When a lamp of 1.2 kW was used as the heating unit 120 of the boiler according to the present embodiment as described above, the capacity of the conventional late-night boiler adopting a 2.5 kW heating wire was the same.

3 is a perspective view showing a modified use state of the boiler according to an embodiment of the present invention, the boiler 100 according to the present embodiment can be used by connecting a plurality in parallel form according to the capacity of the use.

As described above, the boiler according to the present invention has a small diameter of the tube to be heated to store the water is heated, the water stored in the tube to be heated is quickly heated. Therefore, the efficiency of the boiler is improved.

Moreover, since a heating part is located in the center part side of a to-be-heated tube group, a to-be-heated tube group is heated uniformly. This is economical because the heat transfer fins installed in conventional boilers are unnecessary.

In the above, the present invention has been described in accordance with one embodiment of the present invention, but those skilled in the art to which the present invention belongs without modification and modification within the scope without departing from the technical spirit of the present invention. Of course.

1 is a perspective view of a conventional boiler.

2 is a perspective view of a boiler according to an embodiment of the present invention.

Figure 3 is a perspective view showing a modified state of the boiler according to an embodiment of the present invention.

Explanation of symbols on main parts of drawing

110: heated portion 111,118: first and second storage unit

115: heating tube group 115a: heating tube

120: heating unit

Claims (4)

A first storage part communicating with an inlet pipe communicating with a water source side and storing water; Heated tube group (으로) consisting of a tube to be heated, the other end side of the heated tube group is stored in water and is provided with a larger diameter than the tube to be heated of the tube to be heated, the first storage unit and the second storage A heated portion having a second storage portion communicating with the portion and communicating with a guide tube provided with a faucet at the place of use; The boiler characterized in that it is provided on the central portion side of the portion to be heated is provided with a heating unit for heating the water stored in the portion to be heated. The method of claim 1, Boiler, characterized in that the support tube is installed on the central portion of the portion to be heated is inserted and supported. The method of claim 2, One end side and the other end side of the tube to be heated are respectively penetrated through one surface of the first storage portion and one surface of the second storage portion that face each other, The other surface of the first storage portion and the other surface of the second storage portion is formed with a protrusion tube for the support tube is inserted and supported, respectively The heating tube group is a boiler, characterized in that installed in the form of surrounding the outer surface of the support tube. The method according to any one of claims 1 to 3, The heating unit is installed in a vacuum transparent tube in which the discharge gas is injected, the filament is installed in the interior of the transparent tube to generate heat when the electricity is applied and discharge the discharge gas at the same time, the interior of the transparent tube Boiler, characterized in that having a plurality of supporting members installed in the filament to prevent sag.