Method and device for measuring boiler hearth ash fouling coefficient online

A coefficient and fouling technology, which is applied to the indication of boiler working conditions, etc., can solve the problems of large model error, large fluctuation of input parameters, and long measurement lag time.

Active Publication Date: 2018-10-30
ELECTRIC POWER RESEARCH INSTITUTE OF STATE GRID SHANDONG ELECTRIC POWER COMPANY +1
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  • Abstract
  • Description
  • Claims
  • Application Information

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Problems solved by technology

[0006] Therefore, the existing literature on the ash deposition monitoring method on the heating surface of the furnace is mainly based on the flue gas heat balance and heat transfer calculation on the heating surface. This method involves many systems and links, the measurement lag time is long, and the input parameters fluctuate greatly. The furnace thermodynamic calculation model has a large error, and the coal quality data required by the model has not yet been widely measured online, and when the flue gas temperature at the furnace outlet is calculated from the low-temperature flue gas area against the flue gas flow, the heating surfaces at all levels Calculation errors will accumulate on the dirt parameters, resulting in inaccurate monitoring results; currently, the cleaning factor is usually used to represent the relative change of the contamination state of the heating surface, and the resolution of the cleaning fact

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  • Method and device for measuring boiler hearth ash fouling coefficient online
  • Method and device for measuring boiler hearth ash fouling coefficient online
  • Method and device for measuring boiler hearth ash fouling coefficient online

Examples

Experimental program
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Effect test

Embodiment 1

[0077] Such as Figure 1-5 As shown, a method for online measurement of boiler furnace soot coefficient, including the following steps:

[0078] (1) Under the reference operating state of the boiler, the three-variable test of multiple operating conditions is carried out to determine the influence of furnace load, pulverized coal burner commissioning state, burner swing angle and flame radiation temperature, and obtain the boiler reference state. Specific flame radiation temperature variation law;

[0079] (2) Under the actual operating state of the boiler, measure the operating parameters such as furnace load, pulverized coal burner commissioning state, burner swing angle, etc., and use the specific flame radiation temperature variation law under the reference state to determine the specific flame under the actual operating state radiation temperature;

[0080] (3) Measure the flue gas temperature of the furnace cross-section below the folding flame angle, and determine the...

Embodiment 2

[0094] A method for on-line measurement of boiler furnace dust pollution coefficient, specifically comprising the following steps:

[0095] 1) The test of the reference operating state of the boiler in the step (1), including changing the boiler load, the commissioning state of the pulverized coal burner and the swing angle of the burner while burning the designed coal type, maintaining the steam and water supply parameters within the design range Experiments with different working conditions are carried out to determine the influence of these variables on the flame radiation temperature;

[0096] Boiler load, pulverized coal burner commissioning state, burner swing angle, etc. are taken as independent variables, and the feedwater flow at the outlet of the economizer is used as the boiler load, and the specific boiler load τ is expressed as

[0097]

[0098] Among them, D is the feedwater flow rate at the outlet of the economizer, D e is the feedwater flow rate at the outl...

Embodiment 3

[0135] Furnace soot coefficient measurement application is carried out on a 300MW boiler, which is a subcritical, intermediate reheating, single furnace Π-shaped layout, four-corner tangential combustion, natural circulation drum boiler, and a medium-speed coal pulverizer is adopted Pressure direct blowing pulverization system, equipped with five MP212B roller disc coal mills, each pulverizer supplies pulverized coal to four pulverized coal nozzles on the same floor, from bottom to top, the pulverized coal nozzles are A, B, C, Layers D and E, the nozzle height is h in formula (5) i (i=1~5) are 8.31m, 9.91m, 11.51m, 13.11m, 14.71m respectively, the furnace height is h in formula (4) H is 49.41m, and the heating area of ​​the water wall in formula (7) and formula (13) is F l =2758m 2 , the boiler is installed and put into operation with a furnace acoustic wave temperature measurement system, figure 1 It is the furnace acoustic wave temperature measurement system, figure 2 I...

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Abstract

The invention discloses a method and a device for measuring the boiler hearth ash fouling coefficient online. The method comprises the following steps that (1) under a boiler reference operation state, a three-variable test of a plurality of operation conditions is carried out, and the change rule of the specific flame radiation temperature under the boiler reference state is obtained; (2) under the actual operating state of the boiler, operation parameters including the load of a hearth, the feeding state of a pulverized coal burner, a burner swing angle and the like are measured, and the specific flame radiation temperature is determined under the actual operation state; (3) the flue-gas temperature of the section of the hearth below the flame deflection angle is measured, and accordingto the average value of the flue-gas gas temperature in the section of the hearth and the specific flame radiation temperature in the actual operation state, the average radiation temperature of flames in the boiler is determined; (4) according to inlet and outlet working quality parameters of a water cooling wall evaporation system, the radiant heat flow of the heating surface of the water cooling wall of the hearth is determined; and (5) by utilizing the radiant heat flow of the heating surface of the water cooling wall and the average radiation temperature of the flames in the boiler, the ash fouling efficient of the heating surface of the hearth is determined according to the flame radiation law.

Description

technical field [0001] The invention belongs to the field of operation monitoring and diagnosis of ash accumulation in a boiler furnace, and in particular relates to a method and a device for online measuring the ash coefficient of a heating surface of a furnace. Background technique [0002] The ash accumulation and slagging on the water wall of the boiler furnace increase the heat conduction resistance of the heating tube, the temperature of the tube wall increases, the radiant heat projected to the flame by the heating tube in the opposite direction increases, the heat transfer efficiency of the furnace decreases, and the temperature of the flue gas at the furnace outlet increases. The desuperheating water consumption of the superheater or reheater increases, which reduces the economy and safety of boiler operation. [0003] At present, soot blowers are usually used to remove soot and slagging in the furnace, but soot blowers consume a lot of steam and heat, and frequent ...

Claims

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Application Information

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IPC IPC(8): F22B37/38
CPCF22B37/38
Inventor 刘福国崔福兴王守恩
Owner ELECTRIC POWER RESEARCH INSTITUTE OF STATE GRID SHANDONG ELECTRIC POWER COMPANY
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