KR20130085804A - Boiler - Google Patents

Abstract

PURPOSE: A boiler is provided to reduce fuel costs and the emission of toxic gas like carbon dioxide caused by excessive fuel consumption. CONSTITUTION: A boiler comprises a main body (100), a water tank part, a heat exchange part (300), and a heat source feeding part (400). The heat exchange part comprises a coil part (310), an upper connection part (320), and a lower connection part (330). Coils are concentrically wound in the coil part. The top of the coils is connected to the upper connection part. The bottom of the coils is connected to the lower connection part. A front water tank part (210) communicates with a rear water tank part through the upper and lower connection parts.

Description

Boiler {BOILER}

The present invention relates to a boiler which can be used for a house or a building to supply heating water and hot water, and more specifically, to a boiler that can improve heat transfer efficiency regardless of a heat source supply method such as an oil-fired boiler or a gas boiler. It is about.

Recently, as the price of crude oil rises rapidly, researches to reduce energy resources such as oil, electricity, and gas continue to be conducted in various fields. The boiler field for supplying heating water or hot water also consumes a lot of energy, and thus research for energy saving is needed.

A general boiler is configured to heat hot water or heating water by using flame or electric resistance heat generated when burning oil, and thermal efficiency is not good, and hot water or heating water depends solely on oil or gas combustion. In many cases, there is a lot of money, so there is a burden on the household.

In other words, in the case of a general boiler, it is heated by applying combustion heat to a water tank that stores water. Therefore, the heating area is relatively small compared to the amount of water stored. At the same time, there is a problem in that the amount of exhaust gas increases to increase the air pollution.

In addition, in the case of firewood boilers using wood, the heat generation is not enough, so the efficiency of such boilers becomes more problematic.

The present invention is to solve the above problems, and more specifically, to provide a boiler that can utilize the heat generated by the fuel as efficiently as possible.

The present invention, in order to solve the above problems, the main body 100; It is formed on the front surface of the main body 100 and has a front water tank portion 210 having an inlet 211 through which the heating water flows, the water outlet 210 is formed spaced apart from the front water tank portion 210 and the heating water outlet 221 is formed A water tank unit 200 including a rear water tank 220; A heat exchange part 300 formed between the front water tank part 210 and the back water tank part 220; And a heat source supply unit 400 formed below the heat exchange unit 300. The heat exchange unit 300 is installed in a longitudinal direction of the main body 100 and is formed in a shape in which a pipe is wound. A coil axis 310 composed of a plurality of coils 311a and 311b, wherein a coil axis 310 having a larger width wound on the outside of the coil 301a having a smaller width (diameter) is wound therebetween The upper portion 320 is formed to be the same as the coil portion 310, and the upper end of each of the coils (311a, 311b) is connected to communicate with the front water tank 210 and the rear water tank 220 The lower ends of the coils 311a and 311b are connected to each other, and the lower connection part 330 is formed to communicate with the front water tank 210 and the rear water tank 220.

In the boiler of the present invention, a guide hot plate 500 is installed between the heat exchange unit 300 and the heat source supply unit 400 of the main body 100, the guide hot plate 500, the central plate 510 is formed in the center ), And a circumferential plate 520 formed to be inclined downward from the circumference of the central plate 510, and the through-hole 510a is uniformly distributed in the central plate 510. .

In the boiler of the present invention, the boiler further includes a heating water tank 30 connected between the boiler 10 and the room 20, and the heating water tank 30 has a horizontal direction of the T-type connecting portion 31. One first connection part 31a is installed, and a second connection part 31b is formed on the other side in the horizontal direction of the T-type connection part 31 to connect the heating water supply line 33 connected to the first solenoid valve 32. It is connected to the rear water tank 220 through, the vertical connection of the T-shaped connecting portion 31 is formed with a third connecting portion 31c is installed indoor heating water supply pump 34 and the second solenoid valve 34a It is connected to the room 20 through the heating water supply line 35, the heating water of the room 20 is recovered to the heating water tank 30 by the heating water recovery line 36, the heating water tank ( The heating water of 30 is supplied to the front water tank unit 210 through the heating water recovery line 37 in which the heating water recovery pump 38 is installed, and the heating water supply line 33 is rearward. The temperature sensor 33a is installed at a portion adjacent to the jaw portion 220, and when the heating water temperature of the heating water supply line 33 detected by the temperature sensor 33a is equal to or greater than a first predetermined value, The valve 32 is characterized in that the opening.

In the boiler of the present invention, it further comprises a hot water tank 40 connected to the heating water tank 30, the lower portion of the hot water tank 40 is a hot water cold water supply line installed with a cold water supply pump 43 for hot water Is connected to the heating water tank 30 by the 44, the cold water supply line 44 for hot water is locked to the inside of the heating water tank 30, the heat exchanger 45 for hot water having a plurality of bent shapes. It is connected to one end of), the other end of the hot water heat exchanger 45 is characterized in that it is connected to the hot water tank 40 by the hot water supply line 46.

In the boiler of the present invention, the communication unit 510 is formed at the bottom of the main body 100, and the communication unit 510 is connected to an air supply device 520 for supplying external air, and the communication The side portion of the portion 510 is characterized in that the side air inlet 530 is installed to be inclined upwardly so that the introduced external air is introduced into the body 100.

In the boiler of the present invention, in the center of the communication unit 510 is characterized in that the central air inlet 531 is further provided to be inclined upwardly so that the introduced external air is introduced into the body 100. do.

In the boiler of the present invention, the heat source supply unit 400 is characterized in that it is formed to supply heat using any one of wood, pellets, biomass, oil, or gas.

In the boiler of the present invention, the middle plate 540 is formed to have the same width as the width of the coil having the largest width (diameter) of the coil part 310 of the heat exchange part 300, the heat exchange part 300 Characterized in that arranged below.

In the present invention, by maximally securing the heat transfer area of the heat exchanger inserted into the boiler body under the same volume, the heat generated through the heat source can be utilized to the maximum, thereby greatly increasing the thermal efficiency.

In addition, in the present invention, by utilizing a guide hot plate consisting of a circumferential plate formed to be inclined downward on the side surface and a central plate formed with a plurality of through holes in the center of the circumferential plate, heat generated from the heat source is evenly transferred to the heat exchange unit to further improve thermal efficiency. Has the advantage of being improved.

Due to this action, the amount of fuel required for the operation of the boiler is reduced, thereby reducing the fuel consumption cost required for the operation of the boiler and at the same time reducing the emission of harmful gases such as carbon dioxide due to overuse of the fuel.

1 is a view showing a system in which the boiler of the present invention is installed.
Figure 2 is a longitudinal cross-sectional view of the boiler of the present invention.
3 is a view showing a state in which a heat source supply unit of another form is mounted in the boiler of the present invention.
4 is a view showing a heat exchanger in the boiler of the present invention.
5 is a cross-sectional perspective view of the boiler of the present invention.
6 is a longitudinal sectional view of the boiler of the present invention.
7 is a view illustrating the operation of the boiler when the heating switch is not operated indoors.
8 is a view illustrating the operation of the boiler when the heating water temperature at the boiler outlet is less than the predetermined temperature when the heating switch is operated indoors.
8 is a view illustrating the operation of the boiler when the heating water temperature at the boiler outlet is higher than a predetermined temperature when the heating switch is operated indoors.

Hereinafter, the first embodiment of the present invention will be described in detail with reference to the accompanying drawings. 1 is a view of the entire system including the boiler of the present invention.

As shown in FIG. 1, in the entire system including the boiler of the present invention, a boiler 10, a heating water tank 30 connected to the boiler 10 and a room 20, and a heating water tank 30. It consists of a hot water tank 40 is connected to 30.

[Boiler]

Figure 2 is a longitudinal cross-sectional view of the boiler of the present invention. 3 is a view showing a state in which a heat source supply unit of another form is mounted in the boiler of the present invention. 4 is a view showing a heat exchanger in the boiler of the present invention. 5 is a cross-sectional perspective view of the boiler of the present invention. 6 is a longitudinal sectional view of the boiler of the present invention.

The main body 100 may be formed in a substantially rectangular shape or a circular shape, and an exhaust port 101 for discharging the exhaust gas burned in the boiler is formed at an upper end thereof.

In addition, an opening 102 for inserting the heat source supply unit 400 formed of a material which is directly burned, such as wood or pellets, is used in the lower portion of the front of the main body 100 when the firewood is used. The opening 102 can be opened and closed by the rotatable lid 103.

In another embodiment of the present invention, as shown in FIG. 3, a burner 401 using gas or oil may be mounted to the opening 102 to be used.

On the other hand, the tank 200 is composed of the front tank 210, the rear tank 220, the upper tank 230 and a pair of side tank 240.

A heating water inlet 211 is formed at a lower end of the front water tank 210, and a heating water outlet 221 is formed at an upper end of the rear water tank 220.

As shown in FIG. 4, the heat exchange part 300 includes a coil part 310 formed of a plurality of coils 311a, 311b, and 311c installed in the longitudinal direction of the main body 100, and the plurality of coils 301. ) Is connected to the upper end portion and the upper connection portion 320 for connecting the front water tank portion 210 and the rear water tank 220, and the lower ends of the plurality of coils are connected and the front water tank portion 210 and the rear water tank portion It consists of a lower connection portion 330 connecting the 220.

The coil unit 310 includes a plurality of coils 311a, 311b, and 311c formed so as to wind a pipe open at both ends about a rotation center axis. In this embodiment, the shape is formed to be wound in a circular shape, but is not necessarily limited thereto. If the shape is wound around the same central axis, other shapes than the circular shape, such as a rectangular shape, may be used.

The first, second, and third coils 311a, 311b, and 311c have the same height as each other, but are formed to sequentially increase the wound width to diameter of the coil.

Accordingly, the second coil 311b having a wound width (diameter) larger than the wound width (diameter) of the first coil 311a is centered with the first coil 311a outside the first coil 301a. This is installed equally.

In the same manner, the third coil 311c formed to have a width (diameter) larger than the wound width (diameter) of the second coil 311b is centered with the first coil 311a and the second coil 311c. It is provided outside the second coil 311b to coincide.

The heat source supply unit 400 is of a known configuration, but is illustrated as a firewood in this embodiment, but is not limited thereto. Therefore, when wood, pellets, or biomass is used as the heat source supply unit 400 or when gas is used, the gas burner may be a gas burner, and a heat source may be supplied using a combustion unit of other oil boilers.

The air supply unit 500 includes a communication unit 510 formed at the bottom of the main body 100, an air supply unit 520 connected to one side of the communication unit 510 to supply external air, and A side air input part 530 is formed to supply external air, which is formed to communicate with the communication part 510, to the heat source supply part 400.

The air supply device 520 includes a connection pipe 521 communicating with the communication unit 510 from the outside and a supply pump 522 installed in the connection pipe 521.

The side air inlet 530 is formed to be inclined upward, and a central air inlet 531 may be additionally formed at the center of the communication unit 510 of the main body 100.

The central air inlet 531 has a through hole 531a formed thereon, so that air from the communication unit 510 is supplied to the center through the through hole 531a.

Meanwhile, the guide hot plate 540 is installed directly below the heat exchange part 300 to the upper side of the heat source supply part 400.

The guide hot plate 540 has a rectangular flat plate shape and has a center plate 541 having a plurality of through holes 541a and four rectangular flat plate circumferential plates 542 fixed inclined downwardly around the central plate 541. )

The size of the middle plate 541 is preferably equal to the width (diameter) of the third coil 311c formed at the outermost part of the coils of the coil part 310 in the heat exchange part 300.

The operation of the boiler 10 thus formed will be described first.

First, air is introduced into the communication part 510 formed at the bottom of the main body 100 through the connection pipe 521 by the supply pump 522.

Then, due to the side air inlet 530 formed on the side of the communication unit 510 and the central air inlet 531 formed in the center of the communication unit 510, the air necessary for combustion is sufficiently supplied through the side and the center. Combustion efficiency is to be improved compared to the prior art without these inputs (530,531).

On the other hand, the heating water filled in the front water tank unit 210, as shown in Figures 2 and 5, the heat source supply unit while moving the upper water tank unit 230, the side water tank unit 240, and the heat exchange unit 300 It is heated by 400 and then flows to the rear tank 220.

The heat generated from the heat source supply unit 400 first passes through the guide hot plate 540. Since the guide hot plate 540 is formed with a circumferential plate 542 formed to be inclined downward, the generated heat is circumferential plate 542. By naturally collecting the central plate 541 by the heat is generated to be transferred to the heat exchange unit 300 as much as possible.

In addition, in the related art, heat generated in the heat source supply unit 400 is not uniformly distributed with respect to the area of the middle plate 541, so there is a problem in that thermal efficiency is lowered. This problem is solved by the through hole 541a.

That is, in the present invention, since the heat generated from the heat source supply unit 400 is uniformly distributed over the entire area of the middle plate 541 by the through hole 541a of the middle plate 541, heat transfer to the heat exchange unit 300 is uniform. As a result, the heat transfer efficiency is improved.

As described above, in the present invention, heat generated in the heat source supply unit 400 is collected at the center by the circumferential plate 542 and heat is collected at the center, while the heat exchange unit is uniformly formed by the center plate 541 having the through hole 541a formed thereon. Heat transfer to 300 is to maximize the heat transfer efficiency.

The heat passing uniformly through the guide heating plate 500 is transferred to the heat exchange part 300. In the heat exchange part 300, the coil part 310 is formed to be rotated and wound. It will be fully secured.

Furthermore, a plurality of coils having different diameters are transferred to the same boiler volume by forming the same number of coils having the same diameter as the centers of the second coil 311b and the third coil 311c, which are gradually larger from the smaller diameter of the first coil 311a. The maximum area is secured.

Therefore, while the heat supplied from the heat source supply unit 400 passes through the heat exchange unit 300 having the maximum heat transfer area, sufficient heat transfer time and heat transfer efficiency are secured.

This configuration has a significantly improved heat exchange efficiency than conventional boilers compared to the conventional boiler is a heat exchange pipe is formed vertically in the combustion space to ensure sufficient heat transfer time and heat transfer efficiency.

Particularly, in the present invention, the size of the middle plate 541 is formed in the coil part 310 of the heat exchange part 300 to be the same as the third coil 311c having the maximum width (diameter). By installing below, heat generated from the heat source supply unit 400 is transferred to the heat exchange unit 300 without loss as much as possible.

On the other hand, the upper water tank 230 and the side water tank 240 has a role that ensures the case when the heating water flows only by the heat exchange unit 300 when there is a lack of sufficient heating water flow rate due to the bubbles generated in the heating water. Do it.

[Heating tank]

On the other hand, the heating water tank 30 for storing the heating water heated in the boiler 10 is connected to the boiler 10, the T-type connecting portion 31 in the heating water passage formed on the heating water tank 30 The first connection portion 31a of) is connected.

The first solenoid valve 32 is connected to the second connection portion 31b of the T-shaped connection portion 31, and the first solenoid valve 32 is connected to the heating water supply line 33, and the heating water supply line 33 is provided. ) Is connected to the heating water outlet 221 of the boiler 10.

On the other hand, the temperature sensor 33a is installed at a position adjacent to the heating water outlet 221 of the boiler 10 in the heating water supply line 33.

In addition, the third connection portion 31c of the T-shaped connection portion 31 corresponding to the indoor heating water supply portion is vertically formed toward the ground, and the indoor heating water supply pump 34 and the second solenoid valve 34a are installed in the middle. And it is connected to the room 20 through the indoor heating water supply line (35).

In this way, by attaching the T-type connecting portion 31 to the heating water tank 30, it is possible to connect the boiler 10 without a large change to the existing heating water tank (30).

An indoor heating water recovery line 36 is formed at the lower portion of the heating water tank 30 to recover the indoor heating water cooled after being heated in the indoor 20.

On the other hand, the lower part of the heating water tank 30 is provided with a heating water recovery line 37 is installed with a recovery pump 38 is connected to the heating water inlet 211 of the boiler 10 to heat the boiler 10 if necessary It acts to supply water.

[Hot water tank]

In the present invention, the heating water tank 30 may be additionally connected to the hot water tank (40).

An upper part of the hot water tank 40 has an indoor hot water supply line 41 for supplying hot water to a required place such as a room, and a cold water replenishment line 42 for supplying cold water for use as the supplied indoor hot water. have.

When the temperature of the hot water tank 40 is lowered, the hot water cold water supply pump 43 is operated so that the cooled hot water is introduced into the boiler 10 through the hot water cold water supply line 44.

The hot water cold water supply line 44 is connected to one end of the hot water heat exchanger 45 having a plurality of curved portions, and the other end of the hot water heat exchanger 45 is connected to the hot water tank 40 by the hot water supply line 46. Connected to the top of the

The hot water heat exchanger 45 has a shape in which a plurality of U-shaped bent portions are connected for heat exchange.

Hereinafter, the operation of the entire system including the boiler of the present invention will be described with reference to FIGS. 7 to 9. 7 is a view illustrating the operation of the boiler when the heating switch 21 is not operated indoors.

The heating water of the heating water tank 30 is introduced into the front water tank 210 of the boiler 10 through the inlet 211 through the heating water recovery line 37 by the operation of the heating water recovery pump 38. Heated to move to the rear tank 220.

On the other hand, when the heating water temperature in the rear water tank 220 sensed by the temperature sensor 33a is above a predetermined first set value of 80-90 ° C., the heating water recovery pump 38 is operated and the first solenoid valve ( 32 is open.

Therefore, the heating water collected from the rear water tank 220 passes through the outlet 221 and passes through the first solenoid valve 32 through the heating water supply line 33, and then the second connection portion of the T-type connecting portion 31. Passed through the 31b and the first connection portion 31a to the heating water tank 30 is stored in the heat storage state.

8 is a view illustrating the operation of the boiler when the heating water temperature at the boiler outlet is lower than the predetermined temperature when the heating switch 21 is operated indoors.

When the operator operates the heating switch 21 in the room 20, the indoor heating water supply pump 34 is operated and the second solenoid valve 34a is opened to supply the heating water to the room 20. At this time, the portion for supplying the heating water will vary depending on the temperature of the heating water at the outlet of the boiler (10).

That is, when the temperature sensor 33a installed at the outlet of the boiler 10 is less than a predetermined temperature, for example, less than 80 ° C., the heating water stored in the heating water tank 30 as shown in FIG. 7 is connected to the first connection part 31a. And the third connection part 31c is supplied to the room 20 and heated, and the heating water supplied from the boiler 10 is not introduced into the room 20 by maintaining the closed state of the first solenoid valve 32. .

9 is a view illustrating the operation of the boiler when the heating water temperature at the boiler outlet is higher than the predetermined temperature when the heating switch 21 is operated in the room 20.

When the heating water temperature sensed by the temperature sensor 33a is a predetermined temperature, for example, 80 ° C. or higher, as shown in FIG. 8, the first solenoid valve 32 is opened, and the heating water from the boiler 10 is T-type. The second heating unit 31b and the third connecting unit 31c of the connection unit 31 are supplied to the indoor heating water, and the heating water of the heating water tank 30 is not supplied to the room 20.

That is, by this operation, the heating water at a higher temperature among the heating water in the rear water tank 220 of the boiler 10 and the heating water of the heating water tank 30 is supplied to the room, thereby ensuring reliability of the boiler operation. .

Next, the operation of the hot water supply in the embodiment of the present invention will be described.

Cold water supply pump 43 for hot water when the heating water temperature detected by the temperature sensor 33a installed in the heating water supply line 33 when the boiler 10 is in operation is a second set value smaller than the first set value, for example, 70 ° C. or more. ) Works. Accordingly, the hot water heating water flows into the hot water heat exchanger 45 installed in the heating water tank 30.

The hot water in the hot water heat exchanger 45 absorbs heat from the heating water of the heating water tank 30 and is then supplied to the hot water tank 40 by the hot water supply line 46 and stored in the heat storage state.

Therefore, when the user opens the drain (faucet) to use hot water, hot water is supplied through the indoor hot water supply line 41. By this action, the heat generated in the boiler 10 can be used more efficiently.

10: boiler 20: indoor
30: heating water tank 40: hot water tank

Claims (8)

Main body 100;
It is formed on the front surface of the main body 100 and has a front water tank portion 210 having an inlet 211 through which the heating water flows, the water outlet 210 is formed spaced apart from the front water tank portion 210 and the heating water outlet 221 is formed A water tank unit 200 including a rear water tank 220;
A heat exchange part 300 formed between the front water tank part 210 and the back water tank part 220;
It comprises a; heat source supply unit 400 formed below the heat exchange unit 300,
The heat exchange unit 300,
The coil part 310 is formed in the longitudinal direction of the main body 100 and is formed of a plurality of coils (311a, 311b) is formed in the shape of the pipe wound, the outside of the coil (301a) of the small wound (diameter) The coil unit 310 is formed such that the other coil 301b having a larger width wound around the same is the same center axis of the coils,
An upper end portion 320 of the coils 311a and 311b connected to each other and formed to communicate the front water tank 210 and the rear water tank 220;
The lower end of each of the coils (311a, 311b) is connected to the boiler, characterized in that consisting of the lower connection portion 330 is formed to communicate the front water tank 210 and the rear water tank 220. The method according to claim 1,
A guide hot plate 500 is installed between the heat exchange part 300 and the heat source supply part 400 of the main body 100,
The guide hot plate 500 is composed of a central plate 510 formed at the center and a circumferential plate 520 formed to be inclined downward from the circumference of the central plate 510, and penetrates the central plate 510. Boiler characterized in that the ball (510a) is formed to be uniformly distributed. The method according to claim 1 or 2,
Further comprising a heating water tank 30 is connected between the boiler 10 and the room 20,
The heating water tank 30 is provided with a first connecting portion 31a which is one horizontal direction of the T-type connecting portion 31,
The second connection portion 31b is formed at the other side in the horizontal direction of the T-shaped connection portion 31 and is connected to the rear water tank 220 through the heating water supply line 33 connected to the first solenoid valve 32.
The third connection portion 31c is formed below the T-shaped connection portion 31 vertically so that the indoor heating water supply pump 34 and the second solenoid valve 34a are installed through the indoor heating water supply line 35. 20),
The heating water of the room 20 is recovered to the heating water tank 30 by the heating water recovery line 36,
The heating water of the heating water tank 30 is supplied to the front water tank unit 210 through the heating water recovery line 37 in which the heating water recovery pump 38 is installed.
The heating water supply line 33 is provided with a temperature sensor 33a in a portion adjacent to the rear water tank 220,
The boiler characterized in that the first solenoid valve (32) is opened when the heating water temperature of the heating water supply line (33) detected by the temperature sensor (33a) is more than a predetermined first set value. The method of claim 3, wherein
Further comprising a hot water tank 40 connected to the heating water tank 30,
The lower part of the hot water tank 40 is connected to the heating water tank 30 by a cold water supply line 44 for hot water in which a cold water supply pump 43 for hot water is installed.
The hot water cold water supply line 44 is locked to the inside of the heating water tank 30 and is connected to one end of the hot water heat exchanger 45 having a plurality of bent shapes,
The other end of the hot water heat exchanger (45) is characterized in that the boiler is connected to the hot water tank (40) by the hot water supply line (46). The method according to claim 1 or 2,
The communication part 510 is formed in the bottom part of the main body 100,
An air supply device 520 for supplying external air is connected to the communicating part 510, and the inclined upwardly so that external air introduced into the main body 100 is introduced into a side of the communicating part 510. Boiler characterized in that the side air inlet 530 is installed. The method of claim 5,
Boiler, characterized in that the center of the communication unit 510 is further provided with a central air inlet 531 which is installed to be inclined upwardly so that the introduced external air is introduced into the body 100. The method according to claim 1 or 2,
The heat source supply unit 400 is characterized in that the boiler is formed to supply heat using any one of wood, pellets, biomass, oil, or gas. The method according to claim 1 or 2,
The middle plate 540 is formed to have the same width as the width of the coil having the largest width (diameter) among the coil parts 310 of the heat exchange part 300, and is disposed below the heat exchange part 300. Boiler.

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