KR100566967B1 - Boiler - Google Patents

Abstract

The present invention relates to a hot water boiler, in particular, a plurality of tubes having a coil shape inside the cylindrical body to be heated by a burner to install a single firebox and convection chamber, the supply pipe and the discharge pipe branched a large amount It is about a hot water boiler which can heat hot water quickly.

Boiler, supply pipe, tube, fuselage, burner.

Description

Hot Water Boiler {BOILER}

1 is a structural diagram showing the structure of a conventional hot water boiler,

2 is a structural diagram of a hot water boiler according to an embodiment of the present invention;

3 is a plan view of the hot water boiler according to an embodiment of the present invention,

4 is a cross-sectional view taken along line A-A of FIG.

<Description of Symbols for Main Parts of Drawings>

10: fuselage, 15: outlet,

20: burner attachment part, 30: tube,

32: outer tube, 34: intermediate tube,

36: inner tube, 40: supply pipe,

42: first supply pipe, 44: second supply pipe,

46: connector, 50: discharge pipe,

52: first discharge pipe, 54: second discharge pipe,

60: tube support.

The present invention relates to a hot water boiler, in particular, a plurality of tubes having a coil shape inside the cylindrical body to be heated by a burner to install a single firebox and convection chamber, the supply pipe and the discharge pipe branched a large amount It is about a hot water boiler which can heat hot water quickly.

1 is a structural diagram showing the structure of a conventional hot water boiler.

As shown in FIG. 1, in the conventional hot water boiler, the fire chamber 1 and the convection chamber 2 are separated.

In the fire chamber 1, a plurality of tubes 3 are arranged in a vertical shape, and the tubes 3 are joined by welding, respectively, to form an outer wall of the fire chamber 1.

That is, half of the tube 3 faces the inside of the fire chamber 1, and the other half faces the outside.

The cross section of the fire chamber 1 has a rectangular shape, and a burner for heating is mounted in the fire chamber 1.

In addition, a bar type reinforcement 4 is mounted on the outer circumferential surface of the tube 3 to prevent the fire chamber 1 from bursting due to a high pressure during combustion.

The convection chamber 2 communicates with the fire chamber 1, and the tube 3 extends and is disposed in the convection chamber 2.

Therefore, it is heated by the burner in the fire chamber 1, and heat exchange takes place in the convection chamber 2.

However, in the conventional boiler, the fire chamber 1 and the convection chamber 2 are separated from each other, and thus, the boiler and the installation area of the boiler are large.

In addition, in order to prevent the firebox 1 from bursting under pressure during combustion, the reinforcing material 4 should be mounted, and the tubes 3 should be welded and connected to each other. There is a problem that consumes a lot and the production period is long.

In addition, the tube 3 constituting the outer wall of the fire chamber 1 is arranged in a vertical shape, the tube 3 is arranged connected to the convection chamber 2, far away to the convection chamber 2 Water flows toward the adjacent tube 3 rather than the tube 3, which causes a drift phenomenon.

In addition, the tube 3 constituting the outer wall of the fire chamber 1 is half facing inward, and the other half is facing outward, so the area heated by the burner is small, and the heat loss is large.

The present invention has been made to solve the above problems, the firebox and the convection chamber is made of one, the tube is made of a coil shape and the heat is applied to the tube front to increase the thermal efficiency and to reduce the installation area The purpose is to provide a hot water boiler that can reduce manufacturing costs and installation costs.

In order to achieve the above object, the hot water boiler of the present invention is made of a cylindrical shape, the body is formed with a burner attachment portion on the top; An outlet formed at the side of the body; A tube mounted in a coil shape along an inner circumferential surface of the body; A supply pipe for supplying water to the tube; It comprises a discharge pipe for receiving water from the tube and discharged to the outside.

The tube is formed in a plurality of concentric circles, the plurality of tubes are spaced apart from each other, the outermost tube of the tube is spaced apart from the inner peripheral surface of the body.

The supply pipe is branched into both sides of the first supply pipe and the second supply pipe, and the discharge pipe is branched into the first discharge pipe and the second discharge pipe on both sides, and the plurality of tubes respectively have the same channel to the first supply pipe and the second supply pipe. Connected to the first discharge pipe and the second discharge pipe in the same number.

The tube is supported by a support mounted radially inside the body.

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

2 is a structural diagram of a hot water boiler according to an embodiment of the present invention, Figure 3 is a plan view of a hot water boiler according to an embodiment of the present invention, Figure 4 is a cross-sectional view taken on line A-A of FIG.

As shown in Figure 2 to 4, the hot water boiler of the present invention, the body 10, the tube 30, the supply pipe 40, the discharge pipe 50 and the tube support 60.

The body 10 is formed in a cylindrical shape, a burner attachment portion 20 for mounting a burner (not shown) is formed on the upper portion, and a discharge port for discharging the air burned by the burner at the side (15) is formed.

At this time, the outlet 15 may be formed in the upper portion or the lower portion, as well as of course.

The tube 30 is mounted in a coil shape along an inner circumferential surface of the body 10, and a plurality of concentric tubes 30 are mounted in a coil shape around the center line of the body 10.

In addition, the tube 30 is a plurality of tubes 30 are stacked on the same concentric circles.

By mounting the tube 30 in the form of a coil, it is possible to reduce the material and reduce the welding area without the need for a multi-pipe welding structure, and to reduce the overall size of the boiler, as well as to reduce the installation area of the boiler as well Water may uniformly flow at a constant speed in the tube 30, thereby preventing drift.

In addition, when the body 10 is circular and the tube 30 is coiled, combustion gas can flow uniformly, and the pressure generated during combustion because the outer circumferential surface of the body 10 is at the same distance from the center. The body 10 can be prevented from bursting by the pressure by distributing it as a whole without being concentrated on this one part.

As shown in FIG. 2, the tube 30 includes an outer tube 32, an intermediate tube 34, and an inner tube 36, and the outer tube 32, an intermediate tube 34, and an inner side thereof. In the tube 36, a plurality of tubes 30 are stacked in a coil form.

At this time, the plurality of tubes 30 are spaced apart from each other, the outermost tube of the tube 30, that is, the outer tube 32 is spaced apart from the inner peripheral surface of the body 10.

By doing so, between the tubes 30, that is, between the inner tube 36 and the intermediate tube 34, between the intermediate tube 34 and the outer tube 32 and between the outer tube 32 and the body. A space is generated between the inner circumferential surfaces of 10 so that heated air flows through it, so that the heat transfer area of the tube 30 can be the entire outer circumferential surface of the tube 30, thereby increasing thermal efficiency.

That is, as shown in FIG. 2, the air heated by the burner inside the body 10 descends while heating the inner tube 36 along the arrow, and again the inner tube 36 and the intermediate tube 34. Heating the tube while rising between and between the intermediate tube 34 and the outer tube 32, and again heating the tube while descending along the inner surface of the outer tube 32 and the body 10. do.

The supply pipe 40 is to supply water to the tube 30, is mounted on the upper portion of the fuselage 10, the discharge pipe 50 is to receive the water from the tube 30 to discharge to the outside It is mounted to the lower part of the fuselage 10.

The supply pipe 40 is branched to both sides of the first supply pipe 42 and the second supply pipe 44 from the upper portion of the body 10, the first supply pipe 42 and the second supply pipe 44 is a plurality of The same number of tubes 30 are connected.

In addition, the discharge pipe 50 is branched to both sides from the lower portion of the body 10 to the first discharge pipe 52 and the second discharge pipe 54, the first discharge pipe 52 and the second discharge pipe 54 is The same number as the plurality of tubes 30 is connected.

To this end, the first supply pipe 42, the second supply pipe 44, the first discharge pipe 52 and the second discharge pipe 54, a plurality of connecting pipes 46 are connected to the plurality of tubes (30) It is installed.

That is, the connecting pipe 46 is connected to the inlet and the outlet of the plurality of tubes 30, the connecting pipe 46 is the same number of the first supply pipe 42 and the second supply pipe 44 And a first discharge pipe 52 and a second discharge pipe 54.

By doing so, it is possible to increase the amount of water introduced through the supply pipe 40, and the water introduced through the first supply pipe 42 and the second supply pipe 44 are laminated to each other through the tube 30. By passing through the fuselage 10, not only can more water be heated up faster, but more water can be discharged quickly through the first discharge pipe 52 and the second discharge pipe 54. It is possible to minimize the heat loss due to the movement.

As shown in FIG. 4, the support 60 is radially mounted inside the fuselage 10 to support the tube 30.

To this end, it is preferable to form a through hole through which the tube 30 can penetrate through the support 60, and penetrate the tube 30 therebetween.

By mounting the support 60, the tube 30 can be prevented from shaking, thereby making it possible to make the amount of water flowing through the tube 30 uniform.

As described above, the hot water boiler of the present invention may be mounted vertically, that is, it may be mounted in a vertical shape, or may be mounted horizontally, or horizontally, depending on the use, and in some cases, may be mounted upside down. free.

The hot water boiler of the present invention is not limited to the above-described embodiment, and may be variously modified and implemented within the range in which the technical idea of the present invention is permitted.

According to the hot water boiler of the present invention as described above has the following effects.

First, by arranging a coil-shaped tube inside a cylindrical body and installing a burner on the body, a single firebox and convection chamber can be installed to reduce the size of the boiler, and water can flow uniformly at a constant speed in the tube. Drift phenomenon can be prevented, and since the fuselage is circular, the combustion gas can flow uniformly, and the fuselage can be prevented from bursting by pressure during combustion without reinforcement.

In addition, the tube has a coil shape, which reduces the welding area, and the manufacturing period is short.

Second, by taking the structure of a plurality of tubes to be concentrically spaced apart from each other, heat can be applied to the entire surface of the tube can increase the thermal efficiency.

Third, by branching the supply pipe and the discharge pipe, and connecting them to a plurality of tubes, a large amount of water can be supplied and discharged, and the water can be heated up more quickly, thereby increasing the thermal efficiency.

Fourth, by attaching the support, the tube can be supported safely.

Claims (4)

A body formed in a cylindrical shape and having a burner attachment portion formed thereon for mounting a burner; A tube installed to be supported by a support inside the fuselage and mounted in a coil form from top to bottom along an inner circumferential surface of the fuselage; A supply pipe formed at an upper portion of the body and connected to an upper side of the tube to supply water into the tube; A discharge tube formed at a lower portion of the body and connected to a lower side of the tube to discharge water passing through the tube to the outside; Is formed on the lower side of the fuselage outlet for discharging the air burned by the burner in the fuselage to the outside; Hot water boiler, characterized in that configured to be mounted at least one or more tubes in another coil form inside the tube mounted in the coil form. The method of claim 1, The plurality of tubes are spaced apart from each other, the outermost tube of the tube is characterized in that spaced apart from the inner circumferential surface of the body. The method of claim 1, The supply pipe is branched into the first supply pipe and the second supply pipe on both sides, The discharge pipe is branched into the first discharge pipe and the second discharge pipe to both sides, The plurality of tubes, the hot water boiler, characterized in that connected to the first supply pipe and the second supply pipe in the same number, respectively, the first discharge pipe and the second discharge pipe in the same number. delete

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