This application is a national stage of International Application No. PCT/KR2013/003120, filed Apr. 15, 2013, which claims the benefit of priority to Korean Application No. 10-2012-0042067, filed Apr. 23, 2012, in the Korean Patent Office. All disclosures of the documents named above are incorporated herein by reference.
1. Field of the Invention
The present invention relates to a combustion device for improving a turndown ratio, and more particularly, to a combustion device for improving a turndown ratio, in which a venturi structure is designed into multiple stages, and the venturi configuration varies to improve a turndown ratio, as well as, when the air and gas are premixed with each other in a premixing chamber, a passage of gas and air is formed so that the gas is discharged in the same direction as a flow direction of the air to stably implement a combustion state even at a low-output load region.
2. Description of the Related Art
In general, a turndown ratio (TDR) of a burner is set for gas combustion devices such as gas boilers or gas water heaters. The TDR refers to a ‘ratio of the maximum gas consumption to the minimum gas consumption’ in a gas combustion device in which a gas amount is variably regulated. For example, when the maximum gas consumption is 30,000 kcal/h, and the minimum gas consumption is 6,000 kcal/h, the TDR becomes 5:1. The TDR may be limited according to the lowest adjustable level of the minimum gas consumption in order to maintain stable flame.
In the case of the gas combustion device, convenience in use during a heating and hot-water operation increases as the TDR increases. That is, initial combustion is performed with a maximum thermal power to reach a desired heating temperature within a short time. However, when the heating temperature reaches close to the desired heating temperature, an amount of gas supplied into a burner may be reduced to perform the combustion. Here, when the TDR is less due to the high minimum gas consumption, it is difficult to control the reduction of the gas amount so as to reduce the output of the burner.
In particular, when the burner operates in low heating and hot-water load region, the combustion device may be frequently turned on/off, and thus the combustion state may be unstable. As a result, a variation in a temperature control increases to deteriorate durability of the device. Therefore, methods for improving the TDR of the burner that are applied to combustion devices have been proposed.
As the related prior art, Korean Patent Registration No. 10-0805630 discloses a combustion device for a gas boiler that includes a blower for supplying air required for combustion, a proportional control valve for regulating a flow rate of supplied gas, a nozzle unit connected to the proportional control valve to supply a gas through an opening/closing of an auxiliary valve, the nozzle unit including a plurality of nozzles that are connected in parallel to each other, a mixing chamber in which the air supplied from the blower and the gas passing through the nozzle unit are mixed with each other to supply the mixture onto a surface of the burner, and a control unit for controlling the number of revolution of the blower through an opening/closing of the proportional control valve and the auxiliary valve to supply only a required amount of air for combustion.
According to the above-described constitutions, there is an advantage in that the nozzles of the nozzle unit into which the gas is supplied are parallely disposed in multiple stages, and the opening/closing of each of the nozzles is controlled to correspond to an output of the burner to improve a turndown ratio, thereby enhancing combustion stability in a low-output load region.
However, in conventional combustion devices in addition to the prior art, a relationship between flow directions of air and gas when the air and gas are mixed with each other in the mixing chamber (premixing chamber) and combustion efficiency have not been considered. In the conventional combustion devices, the flow direction of the air and the discharge direction of the gas in the premixing chamber are different from each other to mix the air and the gas with each other. Thus, when the gas is discharged in a direction different from the flow direction of the air to mix the gas with the air, the gas discharge is effected by the air flow. As a result, it may be difficult to obtain a desired air/gas ratio, and thus unstable combustion may occur to deteriorate low combustion efficiency.
Also, since the premixing chamber of the conventional combustion device has a single venturi structure, the TDR is limited to a ratio of 5:1 or less. Thus, when burned in a low-output load region, the burner may be frequently turned on/off to deteriorate the combustion efficiency, thereby deteriorating the performance of the combustion device.
To solve the above-described problem, an object of the present invention is to provide a combustion device for improving a turndown ratio, which is capable of stably implementing a combustion state in a low-output load region to improve a turndown ratio of a burner.
It is another object of the present invention is to provide a combustion device which is capable of minimizing a variation in mixing ratio of air and gas when a flow rate of a mixed gas is regulated according to load intensity to improve combustion efficiency.
It is further another object of the present invention is to provide a combustion device for improving a turndown ratio, which is capable of simplifying a structure in a device for controlling a flow rate of a mixed gas according to a heating or hot-water load.
To implement the above-described objects, a combustion device for improving a turndown ratio includes a premixing chamber 300 communicating with an air supply tube 100 and a gas supply tube 200, the premixing chamber 300 having a space in which air and gas for combustion are mixed with each other, wherein the inner space of the premixing chamber 300, in which the air and gas supplied through the air supply tube 100 and the gas supply tube 200 are mixed with each other is divided into a multiple-stage venturi structure, and the gas discharged into the premixing chamber 300 through the gas supply tube 200 is discharged in parallel to a flow direction of the air supplied into the premixing chamber 300 through the air supply tube 100.
In this case, the combustion device may further include a mixed gas regulation unit 400 that opens or closes a portion of the premixing chamber 300 divided into the multiple stages to regulate a flow rate of a mixed gas of the air and gas.
Also, the premixing chamber 300 may be divided into two stages to form a first premixing chamber 310 and a second premixing chamber 320 in both sides of a partition member 301, and the mixed gas regulation unit 400 may open or close the second premixing chamber 320 through/into which the air passes and the gas is discharged.
Also, the gas supply tube 200 may be branched into a first gas discharge tube 210 supplying the gas into the first premixing chamber 310 and a second gas discharge tube 220 supplying the gas into the second premixing chamber 320, and a first discharge hole 211 of the first gas discharge tube 210 and a second discharge hole 221 of the second gas discharge tube 220 may be formed so that the gas is discharged toward outlets 312 and 322 of the first premixing chamber 310 and the second premixing chamber 320.
Also, the first and second gas discharge tubes 210 and 220 may be disposed to transversely cross a middle portion of the first premixing chamber 310 and the second premixing chamber 320, respectively, and a flow path of the air may be formed around each of the first gas discharge tube 210 and the second gas discharge tube 220.
Also, the mixed gas regulation unit 400 may include a moving block 420 reciprocated by a driving unit 410 to open or close a flow path of the air passing through the second discharge hole 221 of the second gas discharge tube 220 and the second premixing chamber 320.
Also, the driving unit 410 may include a step motor or a solenoid.
Also, the first discharge hole 211 of the first gas discharge tube 210 and the second discharge hole 221 of the second gas discharge tube (220) may be formed in throat portions in the first premixing chamber 310 and the second premixing chamber 320, respectively.
In the combustion device for improving the turndown ratio according to the present invention, the inside of the premixing chamber may be partitioned into the multiple-stage venturi structure, and the gas may be discharged in the same direction as the flow direction of the air to realize the turndown ratio of 10:1 or more, thereby implementing the stable combustion state even in the low heating or hot-water load region. In addition, when the flow rate of the mixed gas is regulated, the variation in mixing ratio of the air and gas may be minimized to improve the combustion efficiency and minimize the generation of the pollutants.
Also, according to the present invention, a portion of the premixing chamber may be opened or closed by the moving block that is reciprocated by the driving unit to regulate the flow rate of the mixed gas air and gas according to the output of the burner, thereby simplifying the device for regulating the flow rate of the mixed gas.
Additional aspects and/or advantages of the invention will be set forth in part in the description which follows and, in part, will be obvious from the description, or may be learned by practice of the invention.
These and/or other aspects and advantages of the invention will become apparent and more readily appreciated from the following description of the embodiments, taken in conjunction with the accompanying drawings of which:
Hereinafter, a constitution and operation of preferable embodiments according to the present invention will be described in detail with reference to the accompanying drawings.
A combustion device according to the present invention includes a premixing chamber 300 in which air and gas for combustion are premixed, an air supply tube 100 connected to a lower portion of the premixing chamber 300, a gas supply tube 200, through which the gas for combustion is supplied, connected at one side of the premixing chamber 300, and a mixed gas regulation unit 400, which regulates flow rates of the air and gas that flows into the premixing chamber 300 to a flow rate in a mixed gas, disposed at the other side of the premixing chamber 300.
The air supply tube 100 transfers external air that is sucked by rotation of a blower (not shown) into the premixing chamber 300.
The premixing chamber 300 has a space having a venturi structure, in which air introduced along the air supply tube 100 and gas supplied from the gas supply tube 200 and then discharged are premixed, i.e, has a structure partitioned into multiple stages.
In the present embodiment, the premixing chamber 300 is partitioned into two stages by a partition member 301 that is vertically disposed at a central portion of the premixing chamber 300 in parallel to a flow direction of the mixed gas. Here, a first premixing chamber 310 and a second premixing chamber 320 are disposed at both sides with respect to the partition member 301. Each of the first premixing chamber 310 and the second premixing chamber 320 has the venturi structure. In addition, as illustrated in
The combustion gas introduced into the premixing chamber 300 may be regulated in supply amount by a gas control valve (not shown) and then be introduced into the gas supply tube 200. The gas introduced into the gas supply tube 200 is branched into the first gas discharge tube (refer 210 of
As a constitution for branching the supplied gas, an orifice 240 having a first nozzle hole 241 for supplying a portion of the gas introduced into the gas supply tube 200 into the first gas discharge tube 210 and a second nozzle hole 242 for supplying the remaining gas into the second gas discharge tube 220 is disposed between the gas supply tube 200 and the premixing chamber 300. An O-ring 230 for maintaining sealing is mounted between the gas supply tube 200 and the orifice 240, and packings 250 having holes 251 and 252 corresponding to the first and second nozzle holes 241 and 242 are inserted between the orifice 240, the first gas discharge tube 210, and the second discharge tube 220. In addition, an O-ring for maintaining sealing is mounted on an end of the second gas discharge tube 220.
The gas introduced into the first gas discharge tube 210 is discharged into a first mixing chamber 310 through a discharge hole 211 formed in the first gas discharge tube 210, and the gas is introduced into the second gas discharge tube 220 is discharged into a second mixing chamber 320 through a second discharge hole 221 formed in the second gas discharge tube 220. In this case, the first discharge hole 211 of the first gas discharge tube 210 and the second discharge hole 221 of the second gas discharge tube 220 may have gas discharge directions toward the outlet 312 of the first mixing chamber 310 and the outlet 322 of the second mixing chamber 320, respectively. Therefore, the flow direction of the air passing through the first and second mixing chambers 310 and 320 and the discharge direction of the gas discharged through the first and second discharge holes 211 and 221 are the same. Accordingly, the gas discharged into the first and second premixing chambers 310 and 320 may not be affected by the air flow to obtain a mixed gas having a precise flow rate at a preset ratio of air and gas.
The first and second gas discharge tubes 210 and 220 are vertically disposed to transversely cross the middle portions of the first and second premixing chambers 310 and 320, respectively. In addition, flow paths of the air passing through the first and second premixing chambers 310 and 320 are defined around the first and second gas discharge tubes 210 and 220, respectively.
Additionally, it is preferable that the first discharge hole 211 of the first gas discharge tube 210 and the second discharge hole 221 of the second gas discharge tube 220 are disposed on the throat portions each of which has the relatively lowest pressure within the first and second premixing chambers 310 and 320 to allow the gas to be smoothly discharged through the first and second discharge holes 211 and 221.
The mixed gas regulation unit 400 may open or close the flow path of the air passing through the second premixing chamber 320 and the discharge path of the gas discharged into the second premixing chamber 320 to regulate a flow rate of the mixed gas. and the mixed gas regulation unit 400 includes a moving block that is reciprocated by a driving unit 410 to open or close the second discharge hole 221 of the second gas discharge tube 220 and the flow path of the air passing through the second premixing chamber 320.
The driving unit 410 supplies a driving force for a forward/backward movement of the moving block. The driving unit may include a step motor or a solenoid. Therefore, the forward/backward movement of the moving block 420 is performed by controlling the number of revolution that is set to the step motor or a signal applied to the solenoid Thus, the forward/backward movement of the moving block 420 may be easily controlled by a simple apparatus.
The moving block 420 include a body 421 having a cross-section corresponding to that of the second premixing chamber 320. A support rod 430 connected to the driving unit 410 is coupled to a support rod insertion hole 422 formed in the body 421 to transmit the driving force of the driving unit 410 into the body 421 of the moving block 420. In addition, a second gas discharge tube insertion hole 423 having a diameter corresponding to an outer circumference of the second gas discharge tube 220 is formed in a central portion of the body 421. Also, a moving block guide unit 330 for guiding the body 421 of the moving block 420 to move forward/backward is disposed in the premixing chamber 300.
Hereinafter, an operation of regulating the flow rate of the mixed gas according to the heating or hot-water load in the combustion device including the above-described constitutions will be described.
When high thermal energy at which the heating or hot-water load is relatively large is used, both of the first and second premixing chambers 310 and 320 are opened to mix the air and gas in the first and second premixing chambers 310, 320. In this case, the driving unit 410 of the mixed gas regulation unit 400 is driven so that the moving block 420 moves away from a mixing flow path of the second premixing chamber 320 and is pulled to an inner side of the moving block guide unit 330. Thus, the air introduced into the first premixing chamber 310 and the gas discharged through the first discharge hole 211 are mixed in the first premixing chamber 310, and air introduced into the second premixing chamber 320 and the gas discharged through the second discharge hole 221 are mixed in the second premixing chamber 320. Then, the mixed gas of the air and gas is supplied to a burner (not shown) disposed above the premixing chamber 300. Here, each of flow rates of the air and gas introduced into the air supply tube 100 and the gas supply tube 200 is regulated by controlling the number of revolution of a blower (not shown) and an opening degree of a gas supply valve (not shown) in proportional to the preset heating or hot-water load.
When low thermal energy at which the heating or hot-water load is relatively small is used, the air flow and gas discharges in the second premixing chamber 320 are blocked, and thus the air and gas are mixed only in the first premixing chamber 310. In this case, the driving unit 410 of the mixed gas regulation unit 400 is driven so that the moving block 420 moves to the mixing flow path of the second premixing chamber 320, and the body 421 of the moving block 420 blocks the second discharge hole 221 of the second gas discharge tube 220 and simultaneously blocks the flow path of the air passing through the second premixing chamber 320.
Accordingly, the air and gas are mixed in only the first premixing chamber 310 in a low load region in which a burner output is low. Also, the flow rate of the air and gas supplied to the air supply tube 100 and the gas supply tube 200 is regulated by controlling the number of revolution of the blower (not shown) and an opening degree of the gas supply valve (not shown) in proportional to the preset load.
As described above, according to the present invention, the premixing chamber 300 is provided in a double structure including the first and second premixing chambers 310 and 320 each of which has the venturi structure. In addition, in the relatively high-output load region, the premixing may be performed in both of the first and second premixing chambers 310 and 320 in consideration of the heating or hot-water load. On the other hand, in the relatively low-output load region, the premixing may be performed in only the first premixing chambers 310, but not be performed in the second premixing chamber 320 to improve the turndown ratio (TDR).
Although the two-staged venturi structure in the premixing chamber 300 is exemplified in the present embodiment, the present invention is not limited thereto. For example, when the premixing chamber 300 is provided with a structure that is designed into two or more multi-stages, the TDR of about 10:1 or more may be obtained.
Also, according to the present invention, the flow direction of the air and the discharge direction of the gas may be the same to minimize a variation in mixing ratio of the air and gas while the second premixing chamber 320 is opened or closed by the movement of the moving block 420, thereby realizing the stable combustion state. Also, since the gas discharge hole is disposed to discharge the gas from the throat portion, the mixed gas having the desired ratio of the air to gas may be generated to improve the combustion efficiency through the complete combustion of the air and gas and to reduce the emission of pollutants.
Although a few embodiments of the present invention have been shown and described, it would be appreciated by those skilled in the art that changes may be made in this embodiment without departing from the principles and spirit of the invention, the scope of which is defined in the claims and their equivalents.
Number | Date | Country | Kind |
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10-2012-0042067 | Apr 2012 | KR | national |
Filing Document | Filing Date | Country | Kind |
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PCT/KR2013/003120 | 4/15/2013 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2013/162197 | 10/31/2013 | WO | A |
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20110139045 | Zatti et al. | Jun 2011 | A1 |
20130213378 | Schultz | Aug 2013 | A1 |
Number | Date | Country |
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1497211 | May 2004 | CN |
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0 896 192 | Feb 1999 | EP |
S 59-200118 | Nov 1984 | JP |
10-2004-0035369 | Apr 2004 | KR |
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10-2010-0020084 | Feb 2010 | KR |
10-2010-0050769 | May 2010 | KR |
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WO 2012007823 | Jan 2012 | WO |
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Number | Date | Country | |
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20150086931 A1 | Mar 2015 | US |