KR101282116B1 - Combustion-heat exchanger system for boiler or water heater having resonance chambers - Google Patents

Abstract

It is an object of the present invention to provide a combustion-heat exchanger system for a boiler or a water heater having a resonance chamber which enables a quiet operation of the boiler or the water heater by effectively attenuating the noise generated during combustion of the burner by using a resonance action. .
The present invention for implementing this, a burner for burning a mixed fluid of the air supplied from the blower and the gas for combustion supplied from the gas valve, a combustion chamber in which the burner is combusted, and combustion products generated by the combustion of the burner In the combustion-heat exchanger system for a boiler or a water heater, a heat exchanger in which heat is exchanged between a fluid passing through the inside of the heat exchange pipe and an exhaust hood through which the combustion product passing through the heat exchanger is discharged, wherein an outer cover is provided on the outside of the combustion chamber. Is provided; An insulation is provided inside the combustion chamber; The insulation is installed at a position spaced inwardly of the outer cover, and a resonance chamber is provided between the outer cover and the insulation to communicate with the combustion chamber to attenuate noise generated during combustion of the burner; do.

Description

COMBUSTION-HEAT EXCHANGER SYSTEM FOR BOILER OR WATER HEATER HAVING RESONANCE CHAMBERS}

The present invention relates to a combustion-heat exchanger system for a boiler or a water heater provided with a resonance chamber, and more particularly, to provide a resonance chamber between a combustion chamber cover and an insulating material provided therein to absorb noise generated when burning a burner. And a combustion-heat exchanger system for a boiler or water heater with a resonance chamber which enables a quiet operation of the boiler or water heater by attenuation.

In general, a gas boiler or a water heater heats water using combustion heat generated during the combustion of a mixture of gas and air, and circulates the heated water along a pipe so that it can be used for indoor heating or for hot water. to be.

1 is a schematic view showing a conventional boiler or a heat-exchanging combustion heat exchanger system, and FIG. 2 is a cross-sectional view taken along the line A-A of FIG.

Conventional combustion-heat exchanger system, as shown in Figure 1, the burner 20 for burning a mixed fluid of the external air supplied from the blower 10 and the combustion gas supplied from the gas valve 25, The burner 20 is installed inside the combustion chamber 30 and the combustion is carried out, and the heat of combustion of the combustion product generated in the combustion chamber 30 by the combustion of the burner 20 flows along the inside of the heat exchange pipe 50 It comprises a heat exchanger (40) for delivering to the water or hot water, and the exhaust flue (60) through which the combustion product passing through the heat exchanger (40) is discharged to the outside.

When the burner 20 burns, when the high temperature heat energy generated inside the combustion chamber 30 is transferred to the outside of the combustion chamber 30, heat damage is caused to the peripheral devices of the combustion chamber 30. Outside the 30, a left cover 31, a right cover 32, a front cover 33 and a back cover 34 are provided as shown in FIG. 2, and the left side heat insulating material 35 is provided on each inner side thereof. ), The right heat insulating material 36, the front heat insulating material 37 and the rear heat insulating material 38 is provided.

When the load of the burner 20 is increased in order to increase combustion heat in the combustion-heat exchanger system configured as described above, the supply amount of the air supplied from the blower 10 and the gas for combustion supplied from the gas valve 25 is increased. In connection with this, noise is generated due to an increase in pressure fluctuation of air and gas, and the noise generated during combustion of the burner 20 is propagated through the heat exchanger 40 and the exhaust hood 60 to operate the boiler or the water heater. It will emit heavy noise.

In this way, in order to suppress the noise generated by the combustion of the burner 20 in the combustion chamber 30, the combustion product 30 is connected to the heat exchanger 40 and the exhaust hood 60 on the flow path of the combustion product. Although a separate silencer with sound absorbing material may be installed in the air conditioner, the sound absorbing material must meet the requirements of flame retardancy and durability in order to withstand the high temperature and high pressure inside the combustion-heat exchange system. When using a sound absorbing material made of a material because it absorbs only the noise of a specific frequency band has a limit to absorb the noise of various frequency bands.

In addition, the installation of the muffler requires a space for installing the muffler in the combustion-heat exchanger system, which increases the volume of the boiler or the water heater, and causes an increase in the number of processes and an increase in the cost according to the installation of the muffler. There is this.

The present invention has been made to solve the above problems, for the boiler or water heater having a resonance chamber that enables the quiet operation of the boiler or water heater by effectively attenuating the noise generated during combustion of the burner using the resonance action. It is an object to provide a combustion-heat exchanger system.

Another object of the present invention is to provide a combustion-heat exchanger for a boiler or a water heater having a resonance chamber capable of improving the productivity and durability of a product by configuring the means for removing such combustion noise in a simple structure without using a separate sound absorbing material. The purpose is to provide an existing system.

Another object of the present invention is to provide a combustion-heat exchanger system for a boiler or a water heater having a resonance chamber made of a structure capable of effectively removing noise having various frequency bands.

A combustion-heat exchanger system for a boiler or water heater provided with a resonance chamber of the present invention for realizing the object as described above includes: a burner for burning a mixed fluid of air supplied from a blower and combustion gas supplied from a gas valve; And a heat exchanger in which a heat exchange is performed between the combustion chamber in which the burner is combusted, the combustion product generated by combustion of the burner, and a fluid passing through the heat exchange pipe, and an exhaust hood through which the combustion product passing through the heat exchanger is discharged. A combustion-heat exchanger system for a boiler or a water heater, the outer side of which is provided with an outer cover; An insulation is provided inside the combustion chamber; The insulation is installed at a position spaced inwardly of the outer cover, and a resonance chamber is provided between the outer cover and the insulation to communicate with the combustion chamber to attenuate noise generated during combustion of the burner; do.

In this case, the outer cover includes a left cover, a right cover, a front cover, and a rear cover; The heat insulating material may include a left heat insulating material, a right heat insulating material, a front heat insulating material, and a rear heat insulating material installed at positions facing the left cover, the right cover, the front cover, and the back cover, respectively.

In addition, the heat insulating material may be configured to be formed one by one resonant room communication hole perforated in a circular or square.

In addition, the heat insulating material may be composed of a plurality of resonance chamber communication holes perforated in a circular or square.

In addition, the heat insulating material may be formed of a plurality of resonance chamber communication holes perforated side by side in a slit shape.

In addition, a left resonance chamber is located between the left cover and the left insulation, a right resonance chamber is located between the right cover and the right insulation, a front resonance chamber is located between the front cover and the front insulation, and the rear cover and the rear insulation It may consist of a rear resonance chamber located between.

In addition, the left resonance chamber, the right resonance chamber, the front resonance chamber and the rear resonance chamber may be configured to be located independently of each other.

In addition, some or all of the left resonance chamber, the right resonance chamber, the front resonance chamber and the rear resonance chamber may be configured to have different shapes, sizes, and numbers of the volume of the internal space and the resonance chamber communication hole.

According to the combustion-heat exchanger system for a boiler or a water heater provided with a resonance chamber according to the present invention, the burner is burned by providing a resonance chamber between the outer cover and the insulation by installing an insulation at a position spaced inwardly of the combustion chamber outer cover. Noise generated during the operation can be effectively reduced by using resonance, which enables quiet operation of the boiler or water heater.

In addition, according to the present invention, by providing a resonant chamber therebetween through a simple configuration for installing the heat insulating material installed in the combustion chamber at a position spaced inside the outer cover, even if a separate silencer with sound absorbing material is not installed, Since the noise can be effectively attenuated, additional processes and costs required when a separate silencer is provided can be reduced.

In addition, according to the present invention, when the volume of each resonance chamber is configured differently or the size and number of resonance chamber communication holes to be drilled in the insulation material can be effectively removed noise of various frequency bands.

1 is a schematic view showing a conventional boiler or a heat-exchanging combustion heat exchanger system,
FIG. 2 is a cross-sectional view taken along line AA of FIG. 1,
3 is a cross-sectional view showing a combustion chamber structure of a combustion-heat exchanger system for a boiler or a water heater according to the present invention;
Figure 4 is a perspective view showing various embodiments of the heat insulating material provided in the combustion chamber according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Here, the same reference numerals are used for the same constituent elements as those of the conventional art.

3 is a cross-sectional view showing a combustion chamber structure of a combustion-heat exchanger system for a boiler or a water heater according to the present invention, Figure 4 is a perspective view showing various embodiments of the insulation provided in the combustion chamber according to the present invention.

The combustion-heat exchanger system for a boiler or water heater according to the present invention has the same configuration as the conventional combustion-heat exchanger system shown in FIG. 1, and the combustion air supplied from the gas valve 25 and the external air supplied from the blower 10. A burner 20 for combusting the mixed fluid of the gas, a combustion chamber 300 in which the burner 20 is installed and combusted, and combustion generated in the combustion chamber 300 by combustion of the burner 20. It includes a heat exchanger 40 for transmitting the combustion heat of the product to the heating water or hot water flowing along the heat exchange pipe 50, and the exhaust flue 60 discharged to the outside the combustion product passing through the heat exchanger (40). In the present invention, the combustion chamber 300 is characterized in that the resonance chamber (315, 325, 335, 345) for absorbing and attenuating the noise generated during the combustion of the burner 20 is provided.

Hereinafter, an internal configuration of the combustion chamber 300 will be described with reference to FIG. 3.

The outer cover 310, 320, 330, 340 is provided on the outside of the combustion chamber 300, the heat insulating material (350, 360, 370, 380) is installed in the combustion chamber 300 in the position spaced apart inside the outer cover (310, 320, 330, 340), and the outer cover (310, 320, 330, 340) Resonance chambers 315, 325, 335 and 345 are provided in the spaces between the heat insulators 350, 360, 370 and 380.

In the present embodiment, the combustion chamber 300 has a hexahedral structure having a rectangular cross section, and the outer cover 310, 320, 330, 340 includes a left cover 310, a right cover 320, a front cover 330, and a rear cover 340. The heat insulating materials 350, 360, 370, and 380 are composed of a left heat insulating material 350, a right heat insulating material 360, a front heat insulating material 370, and a rear heat insulating material 380.

The left insulation 350, the right insulation 360, the front insulation 370, and the back insulation 380 are the left cover 310, the right cover 320, the front cover 330, and the back cover 340, respectively. It is installed in the position facing the.

Therefore, the left resonance chamber 315 is located between the left cover 310 and the left insulation 350, the right resonance chamber 325 is located between the right cover 320 and the right insulation 360, and the front cover 330 ) And the front resonance chamber 335 is located between the front insulation 370, the rear resonance chamber 345 is located between the rear cover 340 and the rear insulation 380.

In the present embodiment, both ends of the left heat insulating material 350 and the right heat insulating material 360 are coupled to the inner surfaces of the front cover 330 and the rear cover 340, respectively, and the front heat insulating material 370 and the rear heat insulating material 380 are formed. Both ends are coupled to the inner surfaces of the left insulation 350 and the right insulation 360, respectively, the left resonance chamber 315, the right resonance chamber 325, the front resonance chamber 335 and the rear resonance chamber 345 They are located separately from each other.

The internal spaces of the resonance chambers 315, 325, 335, and 345 are preferably formed in different volumes to absorb noise of various frequency bands.

Resonant chamber communication holes (351,361,371,381) are drilled in the heat insulator (350,360,370,380), and the internal space of the combustion chamber (300) and each of the resonance chambers (315,325,335,345) have a structure in communication.

Resonance chamber communication holes (351,361,371,381) perforated in the insulation (350,360,370,380) may be configured in various shapes and sizes and different numbers, as illustrated in Figure 4, (a) one resonance chamber in the insulation (350a) A structure in which the communication hole 351a is formed in a circular shape, (b) a structure in which one resonance chamber communication hole 351b is formed in a rectangle in the heat insulating material 350b, and (c) a plurality of resonance room communication holes 351c in the heat insulating material 350c. ) Is formed in a circular shape, (d) a plurality of resonance chamber communication holes (351d) formed in a rectangular shape in the heat insulating material (350d), (e) a plurality of resonance chamber communication holes (351e) in the heat insulating material (350e) is a slit shape Various configurations such as a structure formed side by side is possible.

The plurality of resonance chamber communication holes 351c, 351d, and 351e may be formed in the same size, but are preferably formed in different sizes to effectively absorb noise of various frequency bands, and the shape and size of the resonance chamber communication holes. And the number is not limited to the embodiment shown in Figure 4, may be variously modified.

Hereinafter, the operation of the present invention will be described.

When the combustion-heat exchanger system is operated, the rotation speed of the blower 10 and the opening amount of the gas valve 25 are adjusted according to the combustion load, and the air supplied from the blower 10 and the combustion supplied from the gas valve 25 are controlled. The mixed fluid of the gas is ignited in the burner 20 to be combusted in the combustion chamber 300. When the burner 20 burns, combustion noise is generated by ignition of the mixed fluid together with noise caused by the flow and pressure change of air and combustion gas, and the combustion noise becomes more severe in proportion to the size of the load.

The noise propagated with the flow of the combustion product generated by the combustion of the burner 20 in the internal space of the combustion chamber 300 surrounded by the insulation 350, 360, 370, 380 is passed through the resonance chamber communication holes 351, 361, 371, 381 bored in the insulation 350, 360, 370, 380. The noise introduced into the resonance chambers 315, 325, 335 and 345 formed between the outer cover 310, 320, 330 and 340 and the heat insulators 350, 360, 370 and 380, and the noise introduced into the resonance chambers 315, 325, 335 and 345 are the volume of the resonance chambers 315, 325, 335 and 345 and the communication chambers of the resonance chambers 351, 361, 372 and 381. It is attenuated by resonance in certain frequency bands determined by magnitude and number.

That is, in the resonance operation in the resonance chambers 315, 325, 335 and 345, the noise generated in the combustion chamber 300 passes through the resonance chamber communication holes 351, 361, 371 and 381 to the resonance chambers 315, 325, 335 and 345 and moves in the interior space of the resonance chambers 315, 325, 335 and 345. The sound wave energy of the noise is converted into thermal energy, so the sound is absorbed and attenuated, and noise can be effectively suppressed without using a separate sound absorbing material installed in a general silencer.

In this case, since the resonance chambers 315, 325, 335 and 345 are separated from each other and are independently located, the resonance chambers 315, 325, 335 and 345 can attenuate the noise of different specific frequency bands and thus suppress the noise of various frequency bands simultaneously. The volume, size, and number of the resonance chamber communication holes 351, 361, 371, and 381 of the resonance chambers 315, 325, 335, and 345 may be variously designed in consideration of the frequency band of noise generated in the combustion chamber 300.

As described above, in the present invention, without installing a separate silencer in the combustion-heat exchanger system, a resonant chamber 350, 360, 370, 380 is installed at positions spaced inwardly of the outer cover 310, 320, 330, 330, and are independently located in a space therebetween. (315, 325, 335, 345) and the heat insulating material (350, 360, 370, 380) and the noise generated in the combustion chamber (300) by a simple structure to form a resonance chamber communication hole (351,361,371,381) communicating the internal space of the combustion chamber 300 and the resonance chamber (315,325,335,345). Effective removal allows for quiet operation regardless of the magnitude of the load of the combustion-heat exchanger system, such as a boiler or water heater.

10: blower 20: burner
25 gas valve 30 combustion chamber
31: left cover 32: right cover
33: front cover 34: rear cover
35: left side insulation 36: right side insulation
37: front insulation 38: rear insulation
40: heat exchanger 50: heat exchange pipe
60: exhaust hood 300: combustion chamber
310: left cover 315: left resonance chamber
320: right cover 325: right resonance chamber
330: front cover 335: front resonance chamber
340: rear cover 345: rear resonance chamber
350: left insulation 351: resonance chamber communication hole
360: right insulation 361: resonance chamber communication hole
370: front insulation 371: resonance chamber communication hole
380: rear insulation 381: resonance chamber communication hole
350a, 350b, 350c, 350d, 350e: Insulation
351a, 351b, 351c, 351d, 351e: resonance room communication hall

Claims (8)

A burner for combusting a mixed fluid of air supplied from a blower and a gas for combustion supplied from a gas valve, a combustion chamber in which the burner is combusted, a combustion product generated by combustion of the burner, and a fluid passing through an inside of a heat exchange pipe In the combustion-heat exchanger system for a boiler or a water heater, comprising a heat exchanger in which heat exchange is performed between and an exhaust hood through which a combustion product passing through the heat exchanger is discharged,
The outer cover is provided on the outside of the combustion chamber,
Insulation is provided inside the combustion chamber,
The heat insulating material is installed at a position spaced inward of the outer cover, the resonance between the outer cover and the heat insulating material is provided in the combustion chamber to attenuate the noise generated during the combustion of the burner,
The outer cover is composed of a left cover, a right cover, a front cover and a rear cover,
The heat insulating material is made of a left heat insulating material, a right heat insulating material, a front heat insulating material and a rear heat insulating material installed at positions facing the left cover, the right cover, the front cover and the back cover, respectively.
A left resonance chamber is located between the left cover and the left insulation,
The right resonance chamber is located between the right cover and the right insulation,
A front resonance chamber is located between the front cover and the front insulation;
The rear resonance chamber is located between the rear cover and the rear insulation,
In the left heat insulating material, right heat insulating material, front heat insulating material and rear heat insulating material, an internal space of the combustion chamber and a resonance chamber communication hole communicating with the left resonance chamber, right resonance chamber, front resonance chamber and rear resonance chamber are formed.
The left resonance chamber, the right resonance chamber, the front resonance chamber and the rear resonance chamber are separated from each other and independently located;
Some or all of the left resonance chamber, the right resonance chamber, the front resonance chamber, and the rear resonance chamber are provided with a resonance chamber, characterized in that the volume of the inner space and the shape, size and number of the resonance chamber communication holes are different. Combustion-heat exchanger system for a boiler or water heater. delete The method of claim 1,
Combustion-heat exchanger system for a boiler or a water heater with a resonance chamber, characterized in that the insulation is formed by a resonance chamber communication hole perforated in a circular or square. The method of claim 1,
The heat insulating material is a combustion-heat exchanger system for a boiler or a water heater having a resonance chamber, characterized in that a plurality of resonant chamber communication holes formed in a circular or square. The method of claim 1,
The heat insulating material is a combustion-heat exchanger system for a boiler or a water heater having a resonance chamber, characterized in that a plurality of resonance chamber communication holes drilled side by side in a slit shape.
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