JP2012110875A - Nozzle device, and burner in which the nozzle device is installed - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a nozzle device by which complete burning can be achieved without generating unburned grains.SOLUTION: The nozzle device (10) is provided with: a double fluid spray nozzle (12) having a liquid spray part (14) which is disposed on a central axis line and has a jet orifice on the tip thereof, and a gas spray part (16) disposed around the liquid spray part; and a cap (18) which is disposed at a jet orifice side on the central axis line and is formed in a cylindrical shape by a peripheral wall. In the cap, an opening (18c1) is provided at a center opposite the side at which the double fluid spray nozzle is positioned. A partition wall (18c) is provided, which is formed in a cone or polygonal pyramid shape in which its diameter enlarges as it gets away from the double fluid spray nozzle, and one or plural air-intakes are provided on the peripheral wall of the cap.

Description

  The present invention relates to a nozzle device and a burner device in which the nozzle device is installed. The nozzle device of the present invention can be used not only for combustion, but also in a wide range of fields in which a liquid is used as a mist, such as ozone mist generation, coating application, and water spray cooling.

  2. Description of the Related Art A two-fluid spray nozzle is known in which a liquid is mixed with a gas and sprayed in a fine mist form (see, for example, Patent Document 1). The two-fluid spray nozzle has various features such as that the liquid can be ejected with a fine particle diameter as compared with the one-fluid nozzle. FIG. 5 is a view showing a liquid mist sprayed from a two-fluid spray nozzle and having a conical shape.

JP 2005-313049 A

However, the conventional two-fluid spray nozzle has the following problems.
(1) In order to burn the liquid fuel ejected from the nozzle, when air necessary for combustion is supplied from the outside toward the liquid mist, the outer periphery of the liquid mist is mixed and burned, but the vicinity of the center of the liquid mist cone is air Insufficient combustion, not complete combustion.
(2) Since the fuel ejection speed from the nozzle is fast, it is difficult to hold a flame near the nozzle.
(3) When water oxygen gas instead of air is used for spraying the nozzle, if the supply pressure of water oxygen gas is higher than the pressure required for spraying, the oil can be atomized but burned I can't.
(4) When water oxygen gas instead of air is used for spraying the nozzle, if the supply pressure of water oxygen gas is less than the pressure required for spraying, oil and fat will be atomized even if supplied to the nozzle. I can't.

  The present invention has been developed in view of such a situation, and provides a nozzle device capable of complete combustion without generating unburned particles and a burner device in which the nozzle device is installed. It is aimed.

  The nozzle device according to claim 1 of the present application is a two-fluid spray nozzle having a liquid ejecting section disposed on a central axis and having a spray port provided at a tip thereof, and a gas ejecting section disposed around the liquid ejecting section, And a cap disposed on the central axis on the side of the injection port and formed in a cylindrical shape by a peripheral wall, and the cap has a center opposite to the side where the two-fluid spray nozzle is located. An opening is provided, and a partition wall is formed so as to form a conical shape or a polygonal pyramid shape whose diameter gradually increases as the distance from the two-fluid spray nozzle increases. One or more airflows are provided on the peripheral wall of the cap. An entrance is provided.

  A nozzle device according to a second aspect of the present invention is the nozzle device according to the first aspect, wherein the frame holder is disposed on a central axis at a predetermined distance on the side of the cap opposite to the side where the two-fluid spray nozzle is located. The frame holder is formed in a dome shape or a conical shape whose diameter increases toward the side away from the cap, and an opening is provided in the center. is there.

  A burner device according to a third aspect of the present invention is characterized in that the nozzle device according to the second aspect is installed in an air guide tube opened toward a combustion furnace.

  A burner device according to a fourth aspect of the present invention is a two-fluid spray nozzle having a liquid ejecting section disposed on a central axis and having an ejection port provided at a tip thereof and a gas ejecting section disposed around the liquid ejecting section, A nozzle device having a frame holder arranged on a central axis at a predetermined interval from an injection port of a two-fluid spray nozzle is installed in an air guide tube opened toward a combustion furnace. Is.

  In the nozzle device of the present invention, since air is supplied through the cap by attaching the cap, it is possible to replenish air necessary for combustion and slow down the flow rate of the liquid mist. Mixing of the liquid mist and air can be facilitated, whereby complete combustion can be achieved without generating unburned particles. Moreover, in the nozzle device of the present invention, the flame holder is arranged, so that a flame can be held during combustion and blow-off can be prevented. Furthermore, fuel consumption can be reduced by using water oxygen gas instead of secondary air or instead of atomizing air.

  Next, a nozzle device according to a preferred embodiment of the present invention will be described in detail with reference to the drawings. FIG. 1 is a sectional view schematically showing a nozzle device according to a preferred embodiment of the present invention, and FIG. 2 is an exploded sectional view of the nozzle device of FIG. A nozzle device according to a preferred embodiment of the present invention, indicated as a whole by the reference numeral 10 in FIG. 1, includes a two-fluid spray nozzle 12.

  The two-fluid spray nozzle 12 includes a liquid ejecting unit 14 disposed on the central axis XX, and a gas ejecting unit 16 disposed around the liquid ejecting unit 14.

  The liquid ejecting section 14 is formed in a hollow duct shape as a whole, and is provided with a liquid ejecting opening 14a at one end and a liquid supply opening 14b at the other end. The gas injection unit 16 is formed in a hollow duct shape so as to cover the periphery of the liquid injection unit 14, and the gas injection port 16a is provided at the end on the side where the liquid injection port 14a is provided. Is provided with a gas supply port 16b.

  The liquid supply port 14b of the liquid ejecting unit 14 is connected to a liquid supply source (not shown) through a conduit (not shown). Moreover, the gas supply port 16b of the gas injection part 16 is connected with the gas supply source (not shown) through the conduit | pipe (not shown). In FIG. 1, one gas supply port 16b is shown, but a plurality of gas supply ports 16b may be provided.

  The nozzle device 10 of the present invention also includes a cap 18 disposed on the central axis line XX on the liquid jet port 14a and gas jet port 16a side of the two-fluid spray nozzle 12.

The cap 18 is formed in a cylindrical shape as a whole by the peripheral wall 18a. The cap 18 is provided with one or more (only one is shown in FIG. 1) secondary air inlets 18b on the peripheral wall 18a. The secondary air inlet 18b is connected to a conduit (not shown). To a secondary air supply source (not shown). The cap 18 is provided with a partition wall 18c having an opening 18c1 at the center on the side opposite to the side where the two-fluid spray nozzle 12 is located. The partition wall 18c is formed so that the side of the two-fluid spray nozzle 12 is substantially orthogonal to the central axis XX, and the diameter of the partition 18c is gradually increased as the side opposite to the two-fluid spray nozzle 12 is away from the opening 18c1. It is formed to have a polygonal pyramid shape. The distance D ₁ (see FIG. 1) between the tip of the two-fluid spray nozzle 12 and the opening 18c1 of the partition wall 18c is preferably about 2 mm to about 15 mm.

The nozzle device 10 of the present invention further includes a frame holder 20 disposed on the center axis XX from the cap 18 at a predetermined distance D ₂ on the tip end side of the cap 18. Spacing D ₂ is preferably set to about 5mm~ about 10 mm.

  The frame holder 20 is formed in a dome shape or a conical shape whose diameter increases from a side adjacent to the cap 18 toward a side away from the cap 18, and an opening 20a is provided in the center. The opening 20 a is preferably formed so as to be larger than the outer diameter of the cap 18.

  FIG. 4 is a schematic view schematically showing the burner device 30 in which the nozzle device 10 is installed. As shown in FIG. 4, the nozzle device 10 is installed at the distal end portion of the air guide tube 32 opened toward the combustion furnace. Fuel oil or combustion gas is supplied to the liquid injection unit 14 of the two-fluid spray nozzle 12, spraying air or oxyhydrogen gas is supplied to the gas injection unit 16 of the two-fluid spray nozzle 12, and secondary air is supplied to the cap 18. Alternatively, oxyhydrogen gas is supplied. In FIG. 4, reference numerals 34 and 36 denote a gas burner and a combustion air blower, respectively.

  Next, the operation of the nozzle device 10 configured as described above will be described. First, fuel oil is injected from the liquid injection port 14a of the liquid injection unit 14 of the two-fluid spray nozzle 12 and spray air is injected from the gas injection port 16a of the gas injection unit 16 of the two-fluid spray nozzle 12 at high speed. Then, the fuel oil is injected in the form of a fine mist. The air contained in the mist thus ejected (hereinafter referred to as “oil mist”) is about 5 to 10% of the amount necessary to completely burn the mist.

  In the nozzle device 10, the cap 18 is disposed at the tip of the two-fluid spray nozzle 12, and therefore, when oil mist is injected, the secondary is introduced into the cap 18 through the secondary air inlet 18 b due to the ejector effect. Air is aspirated. Thereby, since the sucked secondary air is mixed with the oil mist, incomplete combustion of the oil mist is prevented. In addition, it is preferable that the opening 18c1 of the cap 18 has such a dimension that the oil mist sprayed from the two-fluid spray nozzle 12 can pass through without any trouble.

  When the oil mist / secondary air injected from the opening 18a1 of the cap 18 passes through the opening 20a of the frame holder 20, the surrounding air is drawn into the opening 20a due to the flow of the air flow, so that the oil mist / secondary air As the air velocity decreases, the amount of air contained in the oil mist / secondary air increases. Accordingly, when the oil mist / secondary air is ignited at this stage, a high-temperature airflow is generated toward the center of the frame holder 20, and this high-temperature airflow is blown through the opening 20a. To form a combustion flame.

  In the above example, water oxygen gas may be sucked instead of the secondary air. That is, the water oxygen gas is sucked into the cap 18 by connecting the water oxygen gas supply source and the secondary air inlet 18b of the cap 18 through the conduit. Then, immediately after the oil mist mixed with water oxygen gas is injected from the opening 18 c 1 of the cap 18, it burns. And because of the combustion heat, the oil mist is burned at a high temperature and rapidly mixed with air, and the combustion temperature becomes high, so that the effect of reducing the fuel consumption can be obtained.

  In the above example, in addition to using the water oxygen gas instead of the secondary air, the fuel oil may be injected using the water oxygen gas instead of the atomizing air. The oil mist / water oxygen gas injected in this manner does not burn by itself because it does not contain air, but becomes combustible by mixing with the air drawn into the opening 20a of the frame holder 20. . When ignited in this state, the water oxygen gas burns. And because of the heat of combustion, the oil mist / water oxygen gas is burned at a high temperature and rapidly mixed with air, the combustion temperature is further increased, and the fuel consumption can be reduced.

Combustion experiments were conducted with a boiler device that consumed 60 liters of kerosene per hour in the existing equipment. As a result of the test under the same load, when 5,000 liters of water oxygen gas was mixed and burned at the time of kerosene combustion, the consumption of kerosene was 43 liters, so the consumption of 17 liters was reduced. .
That is, the calorific value of water oxygen gas (simply calculated as 1 m ³ = 1000 liters) is
About 2553.4 cal / m ³ × 5 m ³ = 12767 kcal / h,
Kerosene consumption was 43 liters / h (reduction amount 17 liters / h).
If the heat quantity of kerosene is 8500kcal / h,
17 liters x 8500kcal = 144500kcal
Was able to reduce energy.
This phenomenon is because (1) kerosene was gasified by the combustion heat of hydro-oxygen gas, and (2) the mixture ratio with air was improved due to gasification, so that unburned particles were not burned and burned completely. It is estimated that

  The present invention is not limited to the above-described embodiments, and various modifications can be made within the scope of the invention described in the claims, and these are also included in the scope of the present invention. Needless to say, it is something.

  For example, in the above embodiment, oil is used as the fuel to be injected, but gaseous (gas) fuel may be used. In the above embodiment, a two-fluid spray nozzle having a liquid ejecting unit disposed on the central axis and a gas ejecting unit disposed around the liquid ejecting unit is shown. A two-fluid spray nozzle (for example, a nozzle provided with a plurality of gas ejection slits on the outer periphery of the central liquid ejection section) may be used. In addition, a nozzle device combining a two-fluid spray nozzle and a frame holder may be installed on the air guide tube without using a cap and used as a burner device. Furthermore, although the nozzle device has been described in connection with combustion in the above-described embodiment, a wide range of uses other than combustion, such as generation of ozone mist, application of paint, and water spray cooling, are used in a mist. In the field, the nozzle device of the present invention can be applied.

It is sectional drawing which showed typically the nozzle apparatus which concerns on preferable embodiment of this invention. FIG. 2 is an exploded sectional view showing each component of the nozzle device of FIG. 1. 3A is a side view taken along line 3a-3a in FIG. 1, and FIG. 3B is a side view seen along line 3b-3b in FIG. It is the schematic diagram which showed schematically the burner apparatus in which the nozzle apparatus of FIG. 1 was installed. It is the figure which showed the liquid mist which was sprayed from the 2 fluid spray nozzle and became conical.

DESCRIPTION OF SYMBOLS 10 Nozzle apparatus 12 2 fluid spray nozzle 14 Liquid injection part 14a Liquid injection port 14b Liquid supply port 16 Gas injection part 16a Gas injection port 16b Gas supply port 18 Cap 18a Perimeter wall 18b Secondary air inflow port 18c Partition wall 18c1 Opening 20 Frame holder 20a Opening 30 Burner device 32 Air guide tube 34 Gas burner 36 Combustion air blower

The nozzle device according to claim 1 of the present application is a two-fluid spray nozzle having a liquid ejecting section disposed on a central axis and having a spray port provided at a tip thereof, and a gas ejecting section disposed around the liquid ejecting section, A cap arranged on the central axis on the side of the injection port and formed in a cylindrical shape by a peripheral wall, and a central axis at a predetermined interval on the side of the cap opposite to the side where the two-fluid spray nozzle is located A frame holder arranged on a line, and the cap has an opening in the center opposite to the side where the two-fluid spray nozzle is located, and the diameter gradually increases as the distance from the two-fluid spray nozzle increases It is formed partition wall so as to form a conical or pyramid shape is provided to, and one or more air inlet is provided in the peripheral wall of the cap, the frame holder, cap Diameter toward the side away from is formed in a dome shape or conical began to expand, and is characterized in that the central opening is provided.

A burner device according to a second aspect of the present invention is characterized in that the nozzle device according to the first aspect is installed in an air guide tube opened toward a combustion furnace .

Claims (4)

A two-fluid spray nozzle having a liquid ejecting section disposed on the central axis and having a spray port provided at a tip thereof and a gas ejecting section disposed around the liquid ejecting section;
A cap disposed on the central axis on the side of the injection port and formed in a cylindrical shape by a peripheral wall;
The cap has an opening in the center opposite to the side where the two-fluid spray nozzle is located, and has a conical shape or a polygonal pyramid shape whose diameter gradually increases as the distance from the two-fluid spray nozzle increases. A formed partition is provided,
One or more air inlets are provided in the peripheral wall of the said cap, The nozzle apparatus characterized by the above-mentioned. A frame holder disposed on a central axis at a predetermined interval on the side of the cap opposite to the side where the two-fluid spray nozzle is located;
2. The frame holder according to claim 1, wherein the frame holder is formed in a dome shape or a conical shape whose diameter increases toward a side away from the cap, and an opening is provided in the center. Nozzle device. The nozzle device according to claim 2 is installed in an air guide tube opened toward a combustion furnace. A two-fluid spray nozzle having a liquid ejecting section disposed on the central axis and having a spray port provided at a tip thereof, and a gas spray section disposed around the liquid ejecting section; and a predetermined interval from the spray port of the two-fluid spray nozzle A burner device, characterized in that a nozzle device comprising a frame holder arranged on a central axis is installed in an air guide tube opened toward the combustion furnace.

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