JPH066706B2 - Simple gas generator - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to a simple gas generation furnace, and in particular, in a thermal power boiler for exclusive use of pulverized coal combustion, kerosene gas oil and heavy oil for auxiliary combustion are omitted, and boiler startup fuel is used. The present invention relates to a simple gas generating furnace for supplying.

(Prior Art) In a commercial thermal power boiler for coal mining areas, it is convenient if the oil for auxiliary combustion or the oil at startup is omitted and it is possible to ignite with pulverized coal from startup. However, with the current technology, it is not possible to directly ignite the pulverized coal burner, and it always starts up under the supply of auxiliary fuel for light and light oil. From such a background, if there is a simple and compact coal gasifier, it is possible to use a boiler that does not require oil fuel by using the generated gas as an auxiliary fuel at the start-up of the boiler.

(Problems to be solved by the invention) An object of the present invention is to use pulverized coal as a raw fuel in order to completely burn coal without burning oil fuel for burner ignition auxiliary combustion at startup in a coal burning boiler. The purpose of the present invention is to provide a simple gas generating furnace for generating water gas as a fuel for ignition.

(Means for Solving Problems) The present invention has been achieved as a result of earnest research, focusing on the fact that a burner can be ignited even with a low-calorie gas such as water gas by using a catalytic burner. . That is,
The present invention is directed to a taper type cyclone furnace in which pulverized coal burners and pulverized coal spray nozzles are alternately arranged toward the tangential direction along the inner wall of the furnace, and a cylindrical water gas reactor connected continuously to the lower part of the cyclone furnace. A means for injecting water or steam tangentially into a lower throat portion provided between the cyclone furnace and the water gas reactor, a quench chamber provided below the water gas reactor, and the quench chamber. And a dust removal tower for gas that has passed through the chamber.

Calorific value of coal-generated gas due to air oxidation is 1000 kcal / N
Although it is m ³ or less and has relatively low calorie, the catalytic combustion method can generate combustion gas of sufficiently high temperature even with low calorie gas of 300 to 1000 kcal / Nm ³ . Since hydrogen is most effective for ignition and combustion in catalytic combustion, it is desirable that the combustible component of the gas produced in the gasification furnace contains hydrogen.

FIG. 7 is a system diagram of a boiler system that uses the combustible gas generated in the simple gasification furnace 40 as the ignition fuel as the auxiliary fuel. The hydrogen-containing gas 42 generated in the gasification furnace 40 is pressurized by the compressor 43, and a part of the hydrogen-containing gas 42 is supplied as a boiler supply gas 44 to a catalyst burner 45 having a function as a starter burner for each pulverized coal burner of the boiler 46. Supplied, while surplus gas 47
Is stored in the gas holder 48 and used as fuel 49 for starting the next gasification furnace. The present invention relates to pulverized coal 4
The present invention relates to a gasification furnace 42 which supplies a gas fuel for igniting a starter burner of a boiler 46 using 1 as a raw fuel.

Hereinafter, the present invention will be described in more detail with reference to the embodiments shown in the drawings.

(Embodiment) FIG. 1 is a sectional view of a simple gas generating furnace showing an embodiment of the present invention, FIG. 2 is a sectional view taken along the line II-II in FIG. The drawing is a cross-sectional view taken along the line II-II in FIG. As shown in FIG. 2, this apparatus comprises a taper type cyclone furnace (partial oxidation gasification chamber) 5 in which pulverized coal burners 2 and pulverized coal spray nozzles 3 are alternately arranged in a tangential direction along the inner wall of the furnace, and A cylindrical water-gas reaction furnace (aqueous reaction chamber) 15 connected to the lower part of the cyclone furnace 5;
The steam nozzle 13 provided in the lower throat portion 12 of the cyclone furnace 5, the quench chamber 16 provided in the lower portion of the water gas reaction furnace 15, and the gas that has passed through the quench chamber 16 is removed to generate a produced gas. It is mainly composed of a dust removal tower 18 for obtaining. A start-up burner 4 is provided on the upper ceiling of the partial oxidation gasification chamber 5. Fuel for this start-up burner 9
As the oil, a normal oil or LPG may be used, but as shown in FIG. 7, it is convenient to use the one in which the surplus gas generated in the gas generating furnace of the present invention is stored in the gas holder 48. The burner 4 may be a normal burner in the case of normal fuel, but needs to be a catalytic burner in the case of using gasifier excess gas. The entire inner surface of the gasification furnace main body 1 forms a refractory lining wall 11 lined with refractory material. The water gasification chamber 15 is sufficiently high and long, a slit 17 is provided in the lower portion thereof, and the water gasification chamber 15 is submerged in the water 23 of the quench chamber 16. Slit 17 is water 2
It is arranged at the position of the water surface 24 of No. 3 and prevents the water from bumping and blowing up. Further, a dedusting tower 18 provided in the quench chamber is provided with a filling material 19, and a supply means for the spray water 25 and a demister 20 are provided above the degassing tower 18 to perform dehydration and dedusting, and then a generated gas. 21 is taken out. A discharge pipe for the waste water 22 is provided to maintain the water surface of the water 23 in the quench chamber 16.

Next, the operation and effect of the gas generating furnace will be described with reference to FIGS. First, a burner fire 30 is formed by the start-up burner 4, and the refractory lining wall 11 is entirely heated so that pulverized coal can be ignited. Next, when the pulverized coal burner 2 is started, and the pulverized coal is burned with a slight excess of air, the pulverized coal easily forms a fire due to the heat from the start-up burner flame 30 and the heating lining wall 11, and gas A pulverized coal fire 32 is formed along the inner wall of the chemical conversion chamber 5.
The fire 32 is accelerated as it goes down the taper portion of the furnace body 1, and further descends while turning while being more closely attached to the lining wall 11. In such a state, the start-up burner 3 can be stopped. When the pulverized coal 6 is similarly tangentially injected from the nozzle 3 with the pulverized coal fire layer formed on the lining wall 11, the pulverized coal fire 32 in the gasification chamber 15
While being mixed with the water, it forms a turning orbit 33 and descends. The injected pulverized coal 6 takes in an excess amount of the combustion air 7 of the pulverized coal burner 2 and is partially combusted and partially oxidized. At this time, since there is a strong pulverized coal fire 32, the volatile matter in the injected pulverized coal 6 is promptly released and burns prior to the carbon content. Therefore, carbon (charified) particles in a red heat state left after that and CO generated by partial oxidation
Will remain.

The red hot carbon particles mixed in the combustion gas are further strengthened in the swirling force in the process of passing through the throat 12,
It is momentarily mixed with the injected steam 14 from the throat. In this case, since the swirling force is intensified, the red hot carbon particles maintain the swirling force along the inner wall of the water gasification chamber, form a long flow path of the swirling trajectory, and descend, while carbon particles and steam And generate a water gasification reaction as shown in the following formula to generate H ₂ .

The reason why the C + H ₂ O → H ₂ + CO partial oxidation gasification chamber 5 is a cyclone type and the lower part thereof has a throat structure is to ensure a sufficient reaction time (reaction chamber residence time) of the water gasification reaction chamber 15. . Since the red hot carbon flows down while rotating in the cylindrical portion of the water gasification reaction chamber 15, the gas layer thickness becomes thicker at the inner wall surface portion and the gas density becomes leaner at the central portion. Therefore, a low-pressure cylinder portion is generated in the central portion, and as a result, an upward steam 37 of steam is generated with respect to the reaction product gas 36 that rushes into the water in the quench chamber 16. This is sequentially absorbed by the swirling flow 35 of the diffusion gas, and partly contributes to the cooling of the reaction gas 36 while contributing to the water gasification reaction. Sludge 39 is deposited on the bottom of the quench chamber 16, but this is successively taken out of the system together with the wastewater 22.

Since the gasification furnace according to the present invention is used only at the time of starting the boiler, the gasification efficiency and the like are not so much a problem, and the calorific value of the produced gas is not so problematic because the catalyst burner is used. The simple gas generating furnace of the present invention can be operated safely and reliably, and is therefore extremely suitable as a boiler starting furnace.

(Effect of the invention) According to the present invention, since it is preferably used as a gasifier for igniting pulverized coal burner at startup of a boiler, oil for auxiliary combustion becomes unnecessary, and it is extremely useful as an auxiliary device of a coal-fired boiler. It is valid.

[Brief description of drawings]

FIG. 1 is a sectional view of a simple gas generating furnace showing an embodiment of the present invention, FIG. 2 is a sectional view taken along the line II-II of FIG. 1 in the direction of the arrow, and FIG. 3 is FIG. Is a sectional view taken along the line III-III in the direction of the arrow, FIG. 4 is a view for explaining the operation of the simple gas generation furnace of the present invention, and FIG. 5 is a combustion state of the burner section of the partial oxidation gasification chamber. FIG. 6 is a cross-sectional view showing a blown state of steam in the throat portion, and FIG. 7 is a view showing a system of a coal-fired boiler equipped with the simple gasification furnace of the present invention. 1 ... Gasification furnace main body, 2 ... Pulverized coal burner, 3 ... Pulverized coal nozzle, 4 ... Startup burner, 5 ... Tapered cyclone furnace (partial oxidation gasification chamber), 6, 8 ... Pulverized coal, 7, 10
... Air, 9 ... Fuel, 11 ... Fireproof lining wall, 12 ... Slot, 13 ... Steam nozzle, 14 ... Steam, 15 ... Water gas reactor (water gasification reaction chamber), 16 ... Quench chamber, 17 ... Slit, 18 ... Dedusting tower, 19 ... Packing material, 20 ... Demister, 21 ... Product gas, 22 ... Waste water, 2
3 ... water, 24 ... water surface, 25 ... spray water.

Claims (1)

[Claims] 1. A taper type cyclone furnace in which pulverized coal burners and pulverized coal spray nozzles are alternately arranged in a tangential direction along an inner wall of the furnace, and a cylindrical water gas reaction continuously provided in a lower portion of the cyclone furnace. A furnace, means for injecting water or steam tangentially into the lower throat provided between the cyclone furnace and the water gas reactor, and a quench chamber provided below the water gas reactor, A simple gas generating furnace having a dust removal tower for gas that has passed through a quench chamber.