KR101090378B1 - The boiler with excellent combustion efficiency - Google Patents

Abstract

The present invention relates to a boiler using a material such as wood pellets or wood that can generate ashes as a fuel, and more particularly to a boiler having excellent combustion efficiency.

The boiler of the present invention comprises a primary combustion chamber into which fuel is ignited and combusted; The flame of the primary combustion chamber is introduced and propagated to the other side through the opening formed in the upper one side of the primary combustion chamber, and is installed on the flame propagation path to prevent the flame from propagating and forming a vortex in the flame. A plurality of secondary combustion chambers; And a gas outlet connected to the secondary combustion chamber.

In the boiler of the present invention, when the fuel is ignited and combusted in the primary combustion chamber, and the flame introduced into the secondary combustion chamber through the upper one side of the primary combustion chamber is stagnated while being blocked by the plate-like protrusions to form a vortex. The combustion efficiency is good, thereby minimizing the generation of ash.

Combustion, efficiency, rain, wood, resin, waste materials, boiler

Description

Boiler with excellent combustion efficiency {THE BOILER WITH EXCELLENT COMBUSTION EFFICIENCY}

The present invention relates to a boiler using a material such as wood pellets or wood that can generate ashes as a fuel.

In general, boilers use gas or oil such as LPG or LNG as fuel, and some boilers use wood, food waste, and waste synthetic resin as fuel.

Although boilers that use gas or oil as fuels are relatively convenient in terms of management and use, boilers that use wood, food waste, and synthetic resins as fuels are being used to reduce fuel costs and recycle waste materials. .

However, boilers that use wood, food waste, and waste synthetic resins as fuels have a problem in that a significant amount of ash is generated after the fuel is burned, and a large amount of smoke or toxic gas is generated. It was just used.

In addition, there was a problem in that stable and even combustion is not made and heat cannot be stably secured and heat cannot be effectively used.

In addition, there was also a problem that can not supply fuel stably.

The present invention is to solve the above problems, and more particularly, to provide a boiler that can minimize the amount of ash generated while using a fuel that can generate ash after combustion, such as wood.

Moreover, there is also an object to be able to supply heat by combustion effectively and stably.

In the present invention, when the fuel is ignited and combusted in the primary combustion chamber, the flame introduced into the secondary combustion chamber through the upper one side of the primary combustion chamber is stagnated while forming a vortex, which is blocked by the plate-like protrusions, and thus combustion efficiency is increased. Excellent, thereby minimizing the occurrence of ash.

Accordingly, the boiler of the present invention has a primary combustion chamber in which fuel is introduced to ignite and burn.

In addition, the flame of the primary combustion chamber is introduced and propagated to the other side through the opening formed in the upper one side of the primary combustion chamber, and is installed on the flame propagation path to prevent the flame from propagating so that the vortex is formed in the flame. Has a secondary combustion chamber equipped with a plurality of.

It also has a gas outlet connected to the secondary combustion chamber.

In the boiler of the present invention, when the fuel is ignited and combusted in the primary combustion chamber, and the flame introduced into the secondary combustion chamber through the upper one side of the primary combustion chamber is stagnated while being blocked by the plate-like protrusions to form a vortex. The combustion efficiency is good, thereby minimizing the generation of ash.

In addition, when the fuel supply device is provided to supply a small size fuel to the set point through the transfer screw, and moves the fuel located at the set point to the blowing force into the primary combustion chamber, the combustion efficiency is not only better. Stable fuel supply ensures a stable heat source.

In addition, when some of the gas destined for the gas outlet via the secondary combustion chamber is introduced back into the primary combustion chamber, the combustion efficiency is more excellent, and the amount of ash generated can be further reduced.

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

It is to be understood, however, that the appended drawings illustrate only typical embodiments of the present invention and are not to be considered as limiting the scope of the invention.

The present invention relates to a boiler.

Therefore, it has a combustion chamber in which fuel flows and ignites and combusts, and a gas outlet through which gas generated during combustion is discharged.

However, the present invention has an object to provide a boiler in which the amount of ash is minimized while using wood, etc., in which ash may be generated as a fuel.

The better the combustion efficiency, such as wood fueled, the less ash is generated, and if completely burned, no ash is produced.

The boiler of the present invention has a primary combustion chamber 10 in which fuel is introduced to ignite and combust in order to increase combustion efficiency.

In addition, the flame of the primary combustion chamber 10 is introduced through the opening 11 formed at one upper side of the primary combustion chamber 10 to have the secondary combustion chamber 20 which is to propagate to the other side.

In addition, the gas outlet 30 is implemented in the form connected to the secondary combustion chamber (20).

According to this structure, since the injected fuel is not introduced into the secondary combustion chamber 20 until the fuel is combusted to a certain level, the combustion efficiency is located in the secondary combustion chamber 20 because materials that are not completely burned in the primary combustion chamber 10 are located. This is high.

The opening 11 formed on the upper side of the primary combustion chamber 10 may be implemented in the form of a plurality of small holes 12 perforated in the plate as shown in FIG. 1 because the relatively large material is the secondary combustion chamber 20. This is because it can be prevented from flowing into.

By the way, simply by having a configuration having a secondary combustion chamber 20 can not maximize the combustion efficiency.

In the present invention, in order to increase the combustion efficiency in the secondary combustion chamber 20, the flame is to be burned while forming the vortex in the secondary combustion chamber 20.

To this end, vortices can be formed in the flame by preventing the flame from propagating on the propagation path of the flame in the secondary combustion chamber 20 (the flame introduced into the secondary combustion chamber 20 is directed toward the gas outlet 30). A plurality of plate-like protrusions 21 are provided.

In consideration of the combustion efficiency, the plate-shaped protrusion 21 is preferably installed in a form protruding downward from the ceiling of the secondary combustion chamber 20.

The flame in the secondary combustion chamber 20 stays while forming the vortex by the plate-shaped protrusion 21, and when the air is blown toward the propagation path of the vortex, the vortex is more smoothly formed.

Such blowing may be generated by blowing air supplied to the fuel into the secondary combustion chamber 20 in order to ignite and combust fuel injected from the primary combustion chamber 10.

Since vortices are formed in the flame in the secondary combustion chamber 20, heat accumulation occurs in the secondary combustion chamber 2, which causes the secondary combustion chamber 20 to exhibit a very high temperature distribution.

In the present invention, the secondary combustion chamber 20 is located in the upper portion of the primary combustion chamber 10, the heat exchange space 40 is located in the lower portion of the primary combustion chamber 10, the primary combustion chamber 10, It is preferable to increase the combustion efficiency so that the gas passing through the secondary combustion chamber 20 and the heat exchange space 40 is discharged to the gas outlet 30.

In this case, the primary combustion chamber 10, the secondary combustion chamber 20, and the heat exchange space 40 are separated into partitions, but it is preferable that the mutual heat exchange is made of smooth partitions (such as steel plates).

This is because combustion in the primary combustion chamber 10 and combustion efficiency in the secondary combustion chamber 20 can be improved.

The boiler of the present invention may further include hot water supply means 50 for heating and supplying water by using heat generated in the primary combustion chamber 10 or the secondary combustion chamber 20.

That is, the hot water supply is heated by the heat generated in the primary combustion chamber 10 or the secondary combustion chamber 20 in the process of purifying the water to be supplied to the hot water.

Reference numeral 51 is a water inlet and 52 is a hot water outlet.

Since the hot water supply means 50 is also provided in a conventional boiler, a detailed description of the hot water supply means 50 will be omitted.

However, allowing the water circulated in the hot water supply means 50 to pass through the primary combustion chamber 10 or the secondary combustion chamber 20 results in lowering the temperature of the primary combustion chamber 10 or the secondary combustion chamber 20. It is preferable to provide the heat exchange space 40 or the like as described above.

The boiler of the present invention may further include heating water supply means 60 for heating and supplying heating water by using heat generated in the primary combustion chamber 10 or the secondary combustion chamber 20.

That is, the heating water is heated by heat generated in the primary combustion chamber 10 or the secondary combustion chamber 20 in the process of circulating the heating water to be supplied through the heating pipe.

Reference numeral 61 is a heating water inlet, and 62 is a heating water outlet.

Since the heating water supply means 60 is also provided in a conventional boiler, a description of a specific configuration is omitted.

However, allowing the circulating heating water to pass through the primary combustion chamber 10 or the secondary combustion chamber 20 results in lowering the temperature of the primary combustion chamber 10 or the secondary combustion chamber 20. 40) or the like is preferable.

In the above-described hot water supply means 50 or the heating water supply means 60, a structure in which water or heating water circulates a pipe-shaped pipe has a disadvantage in that the heat exchange area is narrow.

In order to solve this problem, the hot water supply means 50 or the heating water supply means 60 allows water or heating water to pass through the inner space of the heat exchange box 70 having a box shape, and the heat exchange box 70 is shown in FIG. As shown in FIG. 2, irregularities may be formed in the internal space such that the contact area with water or heating water is wide.

That is, the heat exchange area is widened through the box shape having irregularities.

In the accompanying drawings, a plurality of heat exchange boxes 70 are provided in the heat exchange space 40, but the ones protruding downward from the ceiling of the heat exchange space 40 and the ones protruding upward from the bottom are alternately arranged. It is.
In the accompanying drawings, a structure (pipe structure) connecting the plurality of heat exchange boxes 40 is not shown, but the implementation of the fluid such as water via the plurality of heat exchange boxes 40 through the plurality of heat exchange boxes ( Considering the state in which 40) is disposed and the installation conditions, a person having ordinary knowledge in the field to which the present invention pertains can easily implement a detailed description thereof.

This is a configuration for preventing heat from quickly exiting the heat exchange space 40.

In the present invention, when a part of the gas directed to the gas outlet 30 via the secondary combustion chamber 20 is introduced again into the primary combustion chamber 10 can increase the temperature of the primary combustion chamber 10 1 The combustion efficiency in the secondary combustion chamber can be further increased.

To this end, a gas circulation path 80 connected to the primary combustion chamber 10 may be formed on a path to the gas discharge port 30.

In the present invention, the fuel supply device for supplying fuel to the primary combustion chamber 10 can be implemented in various ways already known.

However, it is desirable to add a small amount of fuel to increase combustion efficiency.

As a specific example, the wood may be processed into sawdust and compressed into a predetermined size wood pellets.

In addition, wood chips or the like pulverized into small sizes can be supplied.

As such, the fuel having a small size, in particular, a pellet-shaped fuel processed to a constant size may be supplied to a predetermined point through the transfer screw 91, thereby automatically supplying fuel.

However, the structure in which the fuel is directly injected into the primary combustion chamber 10 through the transfer screw 91 has a phenomenon in which heat generated during combustion of the fuel is applied to the transfer screw 91 and the fuel being supplied to ignite at an undesired point. May occur.

In order to solve this problem, the fuel is supplied to the set point through the transfer screw 91, and the fuel placed at the set point is moved to a blowing force such as a blower 92 and injected into the primary combustion chamber 10. The supply device 90 can be made.

That is, the fuel is moved by the blowing force to be introduced into the primary combustion chamber 10 to prevent the transfer screw 91 or the fuel being supplied from being ignited while making a stable input.

1 is a schematic diagram of a boiler having excellent combustion efficiency of the present invention

Figure 2 is a schematic diagram for explaining a heat exchange box that is a component of the present invention

3 is a schematic view for explaining a fuel supply device that is a component of the present invention;

<Explanation of symbols for main parts of drawing>

10. Primary combustion chamber 11. Opening

12. Hall 20. Second combustion chamber

21. Plate protrusion 30. Gas outlet

40. Heat exchange space 50. Hot water supply means

51. Water inlet 52. Hot water outlet

60. Heating water supply means 61. Heating water inlet

62. Heating water outlet 70. Heat exchange box

80. Gas circulation path 90. Fuel supply device

91. Transfer screw 92. Blower

Claims (7)

delete In the boiler, A primary combustion chamber 10 into which fuel is ignited and combusted; The flame of the primary combustion chamber 10 is introduced and propagated to the other side through the opening 11 formed at one upper side of the primary combustion chamber 10, and is installed on the flame propagation path to prevent the flame from propagating. Secondary combustion chamber 20 is provided with a plurality of plate-like projections 21 to form a vortex in the; A gas outlet 30 connected to the secondary combustion chamber 20; And It is configured to include; a fuel supply device 90 for supplying fuel to a set point through the transfer screw 91, and moves the fuel located at the set point to the blowing force into the primary combustion chamber 10; The secondary combustion chamber 20 is located in the upper portion of the primary combustion chamber 10, the heat exchanger can be configured such that the heat of the gas to be exchanged with water or heating water in the lower portion of the primary combustion chamber 10 The space 40 is located, characterized in that the gas passing through the primary combustion chamber 10, the secondary combustion chamber 20, the heat exchange space 40 is discharged to the gas discharge port 30, the combustion efficiency is Excellent boiler. 3. The method of claim 2, Hot water supply means for heating and supplying water by using the heat generated in the primary combustion chamber (10) or the secondary combustion chamber (20), characterized in that the boiler with excellent combustion efficiency. 3. The method of claim 2, Boiler with superior combustion efficiency, characterized in that the heating water supply means for heating and supplying the heating water using the heat generated in the primary combustion chamber (10) or the secondary combustion chamber (20) is further provided. The method of claim 3, In the heat exchange space 40 is a heat exchange box 70 of the box shape, The hot water supply means 50 allows water to pass through the internal space of the heat exchange box 70, and the heat exchange box 70 is a form in which the unevenness is formed in the internal space so that the contact area with the water is wide. Boiler which is excellent in combustion efficiency. The method according to any one of claims 2 to 4, A part of the gas directed to the gas discharge port (30) via the secondary combustion chamber 20 is introduced into the primary combustion chamber (10), the combustion efficiency excellent boiler. The method of claim 4, wherein In the heat exchange space 40 is a heat exchange box 70 of the box shape, The heating water supply means 60 allows the heating water to pass through the inner space of the heat exchange box 70, the heat exchange box 70 is a form in which the unevenness is formed in the inner space so that the contact area with the heating water wide Boiler with excellent combustion efficiency, characterized in that.

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