KR20150055522A - Drop Tube Furnace Capable of Ash Deposition Analysis - Google Patents

Abstract

The present invention relates to a coal ignition reactor capable of analyzing an ash deposition characteristic in the coal ignition reactor which is an experimental device and can simulate ignition / firing characteristics of pulverized coal. According to the present invention, the coal ignition reactor comprises: a fuel supply device continuously supplying pulverized coal of a predetermined amount; a reactor having a burner igniting pulverized coal fuel supplied through the fuel supply device and a combustion chamber wherein the pulverized coal fuel ignited by the burner is burned; a probroad installed to be inserted into the inside of the combustion chamber through a lower end portion of the reactor; a holder installed in an upper portion of the probroad; a sampling prob inserted into the holder to be attached and detached and having a prob tube fused as ash burned in an upper surface is accumulated.

Description

[0001] The present invention relates to a coal ignition reactor,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a drop tube furnace (DTF), and more particularly, to an apparatus for simulating the ignition / ignition characteristics of pulverized coal, Lt; / RTI >

Recently, in the power industry, the environment of a competitive power market has been established amid the changes in the power system operation structure represented by the opening of a power generation company due to the opening of the electric power market. Thus, economic power plant operation is becoming a very important issue in the competitive power market. Currently, there are hydro power, thermal power, nuclear power plant, and so on. In particular, thermal power plants should continuously supply fuel from foreign countries to operate power generation facilities. Thus, coal-fired power plants are costly in various forms, from unloading to by-products and exhaust gas treatment, which is a large part of operating a power plant, If you manage it reasonably, you can greatly reduce the operating cost of the power plant and operate the power plant economically.

In order to reduce the cost required for such thermal power generation, a technique of supplying and burning a low-calorific coal mixed with high-calorific coal in a boiler (hereinafter referred to as a "reactor") has been developed and used.

The coal-fired reactor (DTF) is an experimental device capable of simulating the ignition / ignition characteristics of pulverized coal of such a coal-fired power plant.

In the conventional coal ignition reactor (DTF), a probe is installed in the reactor to analyze the cyclic characteristics of the high temperature, and the characteristics of the fusion bonded to the probe are analyzed.

However, since the conventional coal-fired reactor (DTF) equipped with the probe is difficult to reuse after the use of the probe, the entire sampling probe must be discarded, or it is difficult to use due to its structural complexity.

In order to obtain an accurate analysis of the buckling characteristics in the coal ignition reactor (DTF), the precise amount of pulverized coal must be supplied into the reactor. However, in the conventional coal ignition reactor (DTF), a method of continuously supplying pulverized coal using a vibrator and a carrier gas is used. However, this method is problematic in that it is difficult to supply precisely with a minute amount of about 10 mg / min .

1. Korea Registered Patent No. 0544237 (Registered Date Jan. 11, 2006) "Fueling Measurement Apparatus for Thermal Power Plant Boiler" 2. Korean Registered Patent No. 0945375 (registered on Feb. 24, 2010) "Continuous collection device of fly ash and method for grasping fusing characteristics of fouling"

It is an object of the present invention to solve the above-mentioned problems of the prior art, and it is an object of the present invention to provide a method of efficiently fusing ash in a reactor, , And a cohesive property analysis with a sampling probe which is easy to use.

Another object of the present invention is to provide a coal ignition reactor capable of analyzing cyclic adhesion characteristics by continuously supplying pulverized coal fuel to an inside of a reactor in an accurate amount to improve the accuracy of combustion test and analysis of ash deposition characteristics have.

According to an aspect of the present invention, there is provided a coal-ignition reactor including: a fuel supplier for continuously supplying a predetermined amount of pulverized coal; A burner for igniting the pulverized coal fuel supplied through the fuel supplier, and a combustion chamber for burning the pulverized coal fuel ignited by the burner; A pro- blob inserted into the combustion chamber through a lower end of the reactor, a holder installed at an upper end of the pro-rod, and an ash fused to the upper surface of the pro- And a sampling probe provided with a probe tube to which the probe tube is attached.

According to the present invention, since the probe tube of the sampling probe can be easily attached to and detached from the holder, it is possible to use the probe tube simply by replacing the probe tube with a new one without discarding the entire sampling probe after completion of the analysis test.

In addition, temperature control is easily performed by the cooling jacket formed inside the sampling probe, so that smooth rotatability can be obtained.

According to another aspect of the present invention, since the pulverized coal can be continuously supplied in a predetermined minute amount through the agitating screw and the carrier gas of the fuel supplier, it is possible to carry out an accurate combustion test and a tacky characteristic analysis.

FIG. 1 is a front view showing a coal ignition reactor (DTF) capable of analyzing cyclic adhesion characteristics according to an embodiment of the present invention.
Fig. 2 is a longitudinal sectional view showing the configuration of the fuel supplier of the coal-ignition reactor of Fig. 1;
Fig. 3 is a view for explaining the operation of supplying the fuel at a minute quantity in the fuel supply system of Fig. 2; Fig.
FIG. 4 is a longitudinal sectional view showing the configuration of a sampling probe of the coal-ignition reactor of FIG. 1; FIG.
5 is an exploded cross-sectional view showing an enlarged main part of the sampling probe of FIG.
FIG. 6 is a cross-sectional view of a coupled state in which the main part of the sampling probe of FIG. 4 is enlarged.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the coal-ignition reactor according to the present invention will be described in detail with reference to the accompanying drawings.

1 to 6, a coal-ignition reactor according to an embodiment of the present invention includes a fuel supplier 10 for continuously supplying a predetermined amount of pulverized coal; A reactor 30 having a burner 20 for igniting the pulverized coal fuel supplied through the fuel supplier 10 and a combustion chamber 32 for burning the pulverized coal fuel ignited by the burner 20; And a sampling probe 40 inserted into the combustion chamber 32 through a lower end of the reactor 30.

2 and 3, the fuel supplier 10 includes a hopper 11 in which a pulverized coal fuel is stored, and a carrier gas (not shown) provided inside the hopper 11 at an upper end of the hopper 11 And one end connected to the hopper 11 to communicate with the discharge passage 15 through which the carrier gas and the pulverized coal fuel are introduced from the hopper 11 and the other end is connected to the burner 20, And a pair of stirring screws 14 installed inside the mixer housing 13 to rotate at a constant speed.

The agitation screw 14 has a pair of agitating blades 14a, each pair of which is rotated at the same speed and has a predetermined phase difference with each other and meshed with each other (three in this embodiment). The stirring vane 14a has a dome shape having a rounded tip.

The burner 20 is installed at the upper end of the reactor 30 so as to communicate with the reactor 30 and has an upper end connected to a discharge passage 15 connected to the mixer housing 13 of the fuel supplier 10, . The burner 20 serves to ignite and burn the pulverized coal fuel supplied through the fuel supplier 10.

The reactor 30 has a chamber 31 surrounded by a heat insulating material and a combustion chamber 32 in which pulverized coal is burned is provided inside the chamber 31. The chamber 31 is provided with a heater 33 for maintaining the temperature thereof.

The sampling probe 40 is installed on the lower side of the combustion chamber 32 through a lower end of the reactor 30. As shown in FIGS. 4 to 6, the sampling probe 40 has a long bar shape and is inserted into the combustion chamber 32 through a lower end of the reactor 30, A holder 42 provided at the upper end of the pro-broad 41 and a probe tube 43 detachably fitted in the holder 42 and welded to the upper surface while being deposited with ash burned.

The probe tube 43 is in the form of an open box, and is slidably coupled to or separated from the holder 42. The holder 42 may be made of a metal such as stainless steel, and the probe tube 43 may be made of a material having excellent heat resistance such as alumina.

A cooling jacket 44 through which the cooling fluid flows is provided inside the pro-rod 41 and the holder 42 of the sampling probe 40. The cooling jacket 44 is connected to a fluid supply source (not shown) to form a flow path through which cooling fluid flows. The cooling jacket 44 has a double pipe structure of a supply pipe 44a for supplying fluid to the inside of the holder 42 and a return pipe 44b for enclosing the outside of the supply pipe 44a, The fluid that has been supplied through the holder 42 flows into the holder 42 to perform a cooling action, and then is discharged to the outside of the holder 42 through the return pipe 44b.

The coal ignition reactor of the present invention constructed as above operates as follows.

A carrier gas such as nitrogen (N 2) gas is supplied through the gas supply unit 12 at the upper end of the hopper 11 in a state where the pulverized coal fuel is stored in the hopper 11. The carrier gas is introduced into the mixer housing 13 through the inlet 13a of the mixer housing 13 together with the pulverized coal fuel and then mixed by a pair of rotating stirring screws 14, And discharged through a discharge port 13b of the mixer housing 13 by a predetermined amount. The pulverized coal fuel discharged through the mixer housing (13) is supplied to the burner (20) through the discharge flow path (15).

The pulverized coal fuel supplied to the burner 20 is ignited in the burner 20 and burned in the combustion chamber 32.

The ash powder burnt in the combustion chamber 32 is lowered down to be deposited on the probe tube 43 of the sampling probe 40 and fused. At this time, the cooling fluid flows through the cooling jacket (44) of the sampling probe (40), so that fusion bonding is smoothly performed.

When the combustion test is completed, the sampling probe 40 is separated from the lower end of the combustion chamber 32 of the reactor 30, the probe tube 43 is separated from the holder 42, Ash deposition characteristics, sintering, and / or slagging mechanisms.

The probe tube 43 of the sampling probe 40 is replaced with a new probe tube 43 and inserted into the holder 42. Then the sampling probe 40 is inserted into the holder 42, May be inserted through the lower end of the combustion chamber 32 of the reactor 30. [

As described above, since the probe tube 43 of the sampling probe 40 can be easily attached to and detached from the holder 42, the entirety of the sampling probe 40 is not discarded but the probe tube 43 ) Can be simply replaced with a new one, thereby reducing the cost.

In addition, temperature control can be easily performed by the cooling jacket 44 formed inside the sampling probe 40, so that there is an advantage in that smooth rotatability can be obtained.

In addition, since the pulverized coal can be continuously supplied in a predetermined minute amount through the agitating screw 14 and the carrier gas of the fuel supplier 10, there is an advantage that an accurate combustion test and a tack-and-adhesion characteristic analysis can be performed.

While the present invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not limited to the disclosed embodiments. It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the scope of the present invention.

10: Reactor 11: Hopper
12: gas supply part 13: mixer housing
14: stirring screw 14a: stirring blade
20: burner 30: reactor
32: combustion chamber 40: sampling probe
41: Pro-broad 42: Holder
43: probe tube 44: cooling jacket

Claims (8)

A fuel supplier (10) for continuously supplying a predetermined amount of pulverized coal;
A reactor 30 having a burner 20 for igniting the pulverized coal fuel supplied through the fuel supplier 10 and a combustion chamber 32 for burning the pulverized coal fuel ignited by the burner 20;
A prober 41 inserted into the combustion chamber 32 through a lower end of the reactor 30, a holder 42 installed at an upper end of the probr 41, And a sampling probe (40) having a probe tube (43) which is detachably fitted and fused while deposited ash is burned on the upper surface. The coal ignition reactor as set forth in claim 1, wherein a cooling jacket (44) through which a cooling fluid flows is provided inside the pro-rod (41) and the holder (42) of the sampling probe (40). The refrigerator according to claim 2, wherein the cooling jacket (44) comprises a supply pipe (44a) for supplying a fluid to the inside of the holder (42) And a return pipe (44b) for discharging the coal. 2. The coal ignition reactor according to claim 1, wherein the probe tube (43) is in the form of an open box and is slidably coupled to or separated from the holder (42). The coal ignition reactor according to claim 1, wherein the holder (42) is made of stainless steel, and the probe tube (43) is made of alumina. 2. The fuel supply system according to claim 1, wherein the fuel supplier (10)
A hopper 11 in which the pulverized coal fuel is stored;
A gas supply unit 12 for supplying a carrier gas into the hopper 11;
A mixer housing 13 having one end connected to the hopper 11 and communicating with a discharge passage 15 through which the carrier gas and the pulverized coal fuel are introduced from the hopper 11 and the other end is connected to the burner 20;
And a pair of stirring screws (14) installed inside the mixer housing (13) so as to rotate at a constant speed and having a plurality of stirring vanes (14a) with a constant phase difference from each other. Reactor. The coal-ignition reactor according to claim 6, wherein the carrier gas is nitrogen (N2) gas. 8. The coal-ignition reactor according to claim 7, wherein the stirring blade (14a) of the stirring screw (14) has a dome shape with a rounded tip.

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