KR101045748B1 - Inlet temperature control device of pulverizer in power plant - Google Patents

Abstract

The present invention provides an apparatus for controlling the inlet temperature of the differentiator of a power plant which can control the differentiation inlet temperature relatively accurately by setting the inlet differentiation temperature by using coal total moisture, differentiation outlet temperature, differentiation inlet air quantity, differentiator classifier speed, and the like. As for the method,

Input data for inputting command and data, temperature sensor for sensing and outputting the temperature of differentiator inlet, total water content of coal, differentiation outlet temperature, quantity of differentiation inlet air, speed of differentiator classifier from the input unit And a control unit for outputting a control signal for maintaining the differentiation inlet temperature at the target value after calculating the target value of the differentiation inlet temperature, and a burner unit for heating the coal briquettes in the differentiator according to the control signal of the control unit.

Input section, control section, burner section, ground mill, coal total moisture

Description

Inlet temperature control device of pulverizer in power plant

The present invention relates to a method for controlling the inlet temperature of the differentiation of a power plant. More specifically, the differentiation inlet temperature is relatively set by setting the differentiation inlet temperature using the total coal moisture, the differential outlet temperature, the differential inlet air quantity, and the differential fractionator speed. The present invention relates to an inlet temperature control device and a method of a differentiator of a power plant that can be accurately controlled.

Coal-fired power plants use bituminous coal as power generation fuel, but bituminous coal has poor combustibility compared with fuels such as petroleum and LNG. It is pulverized into fine pulverized coal.

The pulverized powder is supplied with hot air for drying and conveying pulverized coal, and the hot air has its own temperature lowered after raising the temperature of pulverized coal and water to maintain a constant temperature together with pulverized coal and water vapor. Done. As such, the temperature at which the mixture of air, pulverized coal, and submerged water exits the pulverulent is called the pulverulent outlet temperature. When the pulverulent outlet temperature is low, the pulverized coal tube is blocked by the recondensation of evaporated water. As the phenomenon may occur, the above-mentioned differentiator exit temperature should be at least 56 ° C. which is the minimum temperature that can prevent condensation of moisture.

In order to make the above-mentioned grinding mill exit temperature higher than 56 ℃, the grinding mill inlet temperature should be at least 200 ℃ higher, and in the case of unburned coal having a high moisture content, the higher grinding point is used to dry the moisture having a higher specific heat than coal. Inlet temperature is required. For example, in recent years, the use of sub-bituminous coal has been increased for the purpose of reducing fuel costs. Since the sub-bituminous coal has a relatively high water content and volatile matter content, the grinding inlet temperature is further increased to dry the moisture contained in the sub-bituminous coal. It must be elevated.

However, if the above-mentioned grinding inlet temperature is increased at random, it is necessary to control the grinding inlet temperature more precisely because a fire may occur in the grinding when the grinding inlet temperature becomes higher than 250 ° C, which is the ignition temperature of coal. .

An object of the present invention is to solve the conventional problems as described above, by setting the differentiator inlet temperature using the total coal moisture, the differentiator outlet temperature, the differentiator inlet air amount, the differentiator fractionator speed, etc. To provide a control and method for controlling the inlet temperature of the differentiation of a power plant.

As a means for achieving the above object, the configuration of the apparatus of the present invention includes an input unit for the user to input commands and data, a temperature sensor for sensing and outputting the temperature of the grinding inlet, and total coal moisture from the input unit. A control unit which receives data on the differentiation outlet temperature, the differentiation inlet air quantity, and the speed of the differentiator classifier, calculates the target value of the differentiator inlet temperature, and outputs a control signal for maintaining the differentiation inlet temperature at the target value; It comprises a burner unit for heating the coal briquettes in the mill according to the signal.

It is preferable that the configuration of the apparatus of the present invention is such that the above-described differentiator inlet temperature (InletTemp) is calculated by the following equation.

InletTemp =-163.791 + 3.725 OutTemp + 0.288194 ClassifierSpeed

        -11.5184 PAFlow + 11.6591 TM + 0.173182 (OutTemp × PAFlow)

        + 0.631212 (PAFlow × TM)-0.0109091 (OutTemp × PAFlow × TM)

Where OutTemp is the differential exit temperature, ClassifierSpeed is the differential fractionator speed, PAFlow is the differential inlet air volume, and TM is the total moisture in the coal.

As a means for achieving the above object, the configuration of the method of the present invention is configured to obtain data on the differentiator outlet temperature (OutTemp), differentiator classifier speed, differentiator inlet air volume (PAFlow), and total coal (TM) from the user. The step of receiving the input, calculating the target value of the inlet temperature (InletTemp), and operating the burner unit to heat the coal briquettes in the powder, using the signal input from the temperature sensor, the inlet temperature (InletTemp) is set to the target value. And controlling to maintain.

It is preferable that the configuration of the method of the present invention is such that the above-described differentiator inlet temperature InletTemp is calculated by the following equation.

InletTemp =-163.791 + 3.725 OutTemp + 0.288194 ClassifierSpeed

        -11.5184 PAFlow + 11.6591 TM + 0.173182 (OutTemp × PAFlow)

        + 0.631212 (PAFlow × TM)-0.0109091 (OutTemp × PAFlow × TM)

Where OutTemp is the differential exit temperature, ClassifierSpeed is the differential fractionator speed, PAFlow is the differential inlet air volume, and TM is the total moisture in the coal.

This invention has the effect of controlling the grinding inlet temperature relatively accurately by setting the grinding inlet temperature using the coal total moisture, the grinding outlet temperature, the grinding inlet air amount, the grinding mill sorter speed, and the like.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings in order to describe in detail enough to enable those skilled in the art to easily carry out the present invention. . Other objects, features, and operational advantages, including the object, operation, and effect of the present invention will become more apparent from the description of the preferred embodiment.

For reference, the embodiments disclosed herein are only presented by selecting the most preferred embodiment in order to help those skilled in the art from the various possible examples, the technical spirit of the present invention is not necessarily limited or limited only by this embodiment Rather, various changes, additions, and changes are possible within the scope without departing from the spirit of the present invention, as well as other equivalent embodiments.

1 is a block diagram of an inlet temperature control apparatus of a differentiator of a power plant according to an embodiment of the present invention.

As shown in Figure 1, the configuration of the inlet temperature control device of the differentiator of the power plant according to an embodiment of the present invention, the input unit 10 for the user to input commands and data, and senses the temperature of the differentiator inlet The temperature sensor 20 for outputting and the input unit 10 receives data on coal total moisture, differentiation exit temperature, differentiation inlet air quantity, differentiation fractionator speed, calculates the target value of the differentiation inlet temperature, and then inputs the differentiation inlet. And a control unit 30 for outputting a control signal for maintaining the temperature at a target value, and a burner unit 40 for heating the coal briquettes in the grinding mill in accordance with the control signal of the control unit 30.

The differentiator inlet temperature is calculated by the following equation.

InletTemp =-163.791 + 3.725 OutTemp + 0.288194 ClassifierSpeed

        -11.5184 PAFlow + 11.6591 TM + 0.173182 (OutTemp × PAFlow)

        + 0.631212 (PAFlow × TM)-0.0109091 (OutTemp × PAFlow × TM)

Where OutTemp is the differential exit temperature, ClassifierSpeed is the differential fractionator speed, PAFlow is the differential inlet air volume, and TM is the total moisture in the coal.

According to the above configuration, the operation of the inlet temperature control apparatus and method of the differentiator of a power plant according to an embodiment of the present invention is as follows.

The following data sheet was obtained through the differentiator outlet temperature adjustment test, in which the differentiator outlet temperature (OutTemp) was varied while the classifier speed was fixed at 60% and the inlet air flow rate (PAFlow) was fixed at 71 ton / hr. You can get

Differentiation
Outlet temperature
(° C) Coal flow
(ton / hr) Classifier
Speed (%) PA Flow
(ton / hr) Differentiation
Inlet temperature
(℃) MTR
Current
(A) ΔP
(mmH2O) 66

39

60

71   253    42   435 64   243    42   445 62   227    42   445 60   218    44   450 58   210    44   455

In the above data sheet, it can be seen that the inlet temperature of the differentiator decreases considerably with the decrease of the outlet temperature (OutTemp). If the OutTemp OutTemp is lowered by 2 ° C, the inlet temperature is reduced by 8.6 ° C on average. MTR current and ΔP increase slightly with the decrease of OutTemp, but it is negligible.

Then, through the differentiation inlet air volume adjustment test, which sets the OutTemp outlet temperature (OutTemp) to 64 ° C and the differentiator inlet air flow rate (PAFlow) with the classifier Speed at 60% fixed, the following data sheet is obtained. You can get

PAFlow (ton / hr) Coal flow
(ton / hr) Differentiation
Outlet temperature
(℃) Classifier
Speed (%) Differentiation
Inlet temperature
(℃) MTR
Current
(A) ΔP
(mmH2O) ± 0
39
64
60   250   41    475 +5   240   41    465 +10   230   39    455 +15   225   37    455

In the data sheet above, it can be seen that the inlet temperature decreases significantly with the increase of the PAFlow. When the inlet air flow rate (PAFlow) is increased by 5 ton / hr, the inlet temperature of the mill is reduced by about 10 ° C, but the increase is smaller when it is increased by more than 10 ton / hr. MTR current and ΔP decrease slightly but increase only slightly with increasing PAFlow.

In addition, through the differentiator classifier speed adjustment test to vary the classifier speed with the differentiator outlet temperature (OutTemp) set to 64 ° C and the inlet air flow rate (PAFlow) fixed at 71 ton / hr, the following data were obtained: You can get a sheet.

Classifier
Speed (%) Coal flow
(ton / hr) Differentiation
Outlet temperature
(℃) PA Flow
(ton / hr) Differentiation
Inlet temperature
(℃) MTR
Current
(A) ΔP
(mmH2O) 60
39
64
71   257    44   490 50   247    41   445 40   240    38   390

In the data sheet above, we can see that the differentiator inlet temperature, MTR current, and ΔP are all reduced by decreasing the classifier Speed. When the classifier speed is reduced by 10%, the inlet temperature of the mill is lowered by 8.5 ℃, the MTR current is 3A, and ΔP is reduced by 50mmH ₂ O.

In addition, ① two kinds of differentiation outlet temperature (OutTemp) and differentiator classifier speed (2), ② differentiator classifier speed (ClassifierSpeed) and differentiator inlet air volume (PAFlow), ③ differentiator outlet temperature (OutTemp) and differentiator inlet air volume (PAFlow) The following data sheets are obtained for the items and ④ through the integrated adjustment tests of the differentiation operating variables, which are varied for three items: the differential outlet temperature (OutTemp), the differentiator classifier speed, and the differential inlet air flow rate (PAFlow). There is a number.

Adjustment item
Adjustable range
Differentiation
Inlet temperature (℃) MTR current (A) ΔP (mmH ₂ O) Before adjustment After adjustment Before adjustment After adjustment Before adjustment After adjustment
① Differentiation
Outlet temperature
Classifier
Speed
Differentiation
Outlet temperature
63 → 58 ℃

Classifier
Speed
60 → 40%

PAFlow
± 0 → + 15







258


230





44


38





500


420
② Classifier
Speed
PAFlow
227
34
410
③ Differentiation
Outlet temperature
PAFlow
216
41
490
④ Differentiation
Outlet temperature
Classifier
Speed
PAFlow

210

36

420

In the above data sheet, the variation of the differentiation inlet temperature is the smallest in case of ①, the variation of MTR current and ΔP is the largest in case of ②, and the variation of the differentiation inlet temperature is not large in case of ③. However, the change of MTR current and ΔP was the smallest, and in case of ④, the change of the differentiation inlet temperature was the largest and the change of MTR current and ΔP was also relatively large.

Through this adjustment test, the differential inlet temperature (InletTemp) can be calculated by the following equation.

InletTemp =-163.791 + 3.725 OutTemp + 0.288194 ClassifierSpeed

        -11.5184 PAFlow + 11.6591 TM + 0.173182 (OutTemp × PAFlow)

        + 0.631212 (PAFlow × TM)-0.0109091 (OutTemp × PAFlow × TM)

Where OutTemp is the differential exit temperature, ClassifierSpeed is the differential fractionator speed, PAFlow is the differential inlet air volume, and TM is the total moisture in the coal.

The control unit 30 receives data on the differentiation outlet temperature OutTemp, the differentiator classifier Speed, the differentiation inlet air amount PAFlow, and the total coal moisture TM from the input unit 10, by using the above formula. Calculate the target value of the differential inlet temperature (InletTemp).

Next, the control unit 30 operates the burner unit 40 to heat the coal briquettes in the differentiator, and controls the differentiation inlet temperature InletTemp to maintain the target value by using a signal input from the temperature sensor 20.

1 is a block diagram of an inlet temperature control apparatus of a differentiator of a power plant according to an embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

10: input 20: temperature sensor

30 control part 40 burner part

Claims (4)

An input unit for inputting a command and data by a user, The temperature sensor for sensing and outputting the temperature of the differentiation inlet, and inputting the data on coal total moisture, differentiation outlet temperature, differentiation inlet air quantity and differentiation classifier speed from the above input unit, calculate the target value of the differentiation inlet temperature, and then enter the differentiation inlet A control unit for outputting a control signal for maintaining the temperature at a target value; Inlet temperature control device of the differentiator of the power plant characterized in that it comprises a burner unit for heating the coal briquettes in the differentiator according to the control signal of the control unit. The method of claim 1, The differentiator inlet temperature of the differentiator inlet temperature control device, characterized in that calculated by the following formula. InletTemp =-163.791 + 3.725 OutTemp + 0.288194 ClassifierSpeed         -11.5184 PAFlow + 11.6591 TM + 0.173182 (OutTemp × PAFlow)         + 0.631212 (PAFlow × TM)-0.0109091 (OutTemp × PAFlow × TM) Where OutTemp is the differential exit temperature, ClassifierSpeed is the differential fractionator speed, PAFlow is the differential inlet air volume, and TM is the total moisture in the coal. Receiving data about the differential exit temperature (OutTemp), the differential speed of classifier Speed, the differential inlet air flow (PAFlow), and the total coal content (TM) from the user; Calculating a target value of the differential inlet temperature (InletTemp), Inlet temperature of the differentiator of the power plant comprising the step of controlling the inletTemp to maintain the target value by using the signal input from the temperature sensor while heating the coal briquettes in the differentiator by operating the burner unit Control method. The method of claim 3, The differentiator inlet temperature control method of the inlet temperature of the differentiator of the power plant, characterized in that calculated by the following equation. InletTemp =-163.791 + 3.725 OutTemp + 0.288194 ClassifierSpeed         -11.5184 PAFlow + 11.6591 TM + 0.173182 (OutTemp × PAFlow)         + 0.631212 (PAFlow × TM)-0.0109091 (OutTemp × PAFlow × TM) Where OutTemp is the differential exit temperature, ClassifierSpeed is the differential fractionator speed, PAFlow is the differential inlet air volume, and TM is the total moisture in the coal.

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