DE102009015736B4 - Adjustment of the gasification parameters for high-flow entrainment gasifiers - Google Patents

Abstract

A method for controlling and monitoring of Flugstromreaktoren with cooled reaction space structure in the form of a cooling water-flowed cooling screen, the amount of cooling water and their input and output temperatures are measured and used to determine the amount of heat transferred and used for process control, characterized in that the heat transfer amounts with each Compare expected values and, depending on their deviations, the amounts of oxygen supplied are changed until the re-adjusting amounts of heat equal the expected values without the temperature at the end of the cooling of the cooling screen substantially changing.

Description

The invention relates to a system for operating a gasification reactor having the features of claim 1.

The reaction space temperature in the gasification reactor is to be adjusted so that a sufficient flow of the forming liquid slag on a solidified slag layer is possible on the inner surface of the cooling screen. This flow is essentially dependent on the slag composition, thus on the fuel composition and its inerts, and primarily on the strength of the solid, solidified slag layer, as well as on the current load case of the plant. No influence can be exerted on the constantly changing compositions of the fuel and its inerts. Only the strength of the solid, solidified slag layer can be regulated by adjusting the reaction space temperature in the gasification reactor via the oxygen supply.

So far, the reaction chamber temperature in the gasification reactor has been adjusted on the basis of empirical values by the individual operator. The operator orientation has the disadvantage that it can come next to human error especially by carelessness and lack of experience of the operator to shut down the system through the security system, which means corresponding loss of production and what the projected availability of the system lowers.

From the DE 2935771 C2 is a method for monitoring and control of high-temperature gasification processes on the basis of prevailing in the reaction chamber temperature is known, in which the product of per unit time guided amount of water and the temperature difference of the cooling water over a portion of the cooling pipe string as a measure of the average temperature of lying between the measuring points Reaction space is used.

From the DE 4113447 A1 a method for controlling the operation of a gasification reactor is known in which the operating temperature in the gasification reactor is to be kept by determining the ratio of gasification agent to each actually present in the fuel amount of combustible substance within a range which is determined by the melting temperature of the slag ,

From the DE 3219190 A1 a temperature measurement on the reactor of a coal gasification plant is known, in which a continuous and accurate temperature determination in the reactor of a coal gasification plant with liquid slag removal is to be achieved that the liquid-cooled reactor wall with defined, independent of the reactor temperature water circulation and defined, independent of the reactor temperature water inlet temperature is provided and the water outlet temperature is measured.

The invention is based on the problem of providing a possibility for controlling a gasification reactor which brings with it a thickness of the slag layer protecting the cooling screen from thermal overloading.

The problem is solved by a method having the features of claim 1.

The invention makes use of the finding that the thickness of the slag layer protecting the cooling screen from thermal overloading can be ensured if the temperature at the end of the cooling of the cooling screen is kept constant in a narrow temperature window, wherein the heat discharge introduced into the cooling screen is for adjustment the amount of fuel supplied to the gasification reactor is used.

According to the invention, the heat flow from the reaction space of a gasification reactor via the controlled addition of gasification agent, primarily oxygen, kept constant in a predetermined range.

In a further refinement, the absolute height of the temperature determined at one point, for example the temperature of the cooling water when leaving the cooling screen, can be evaluated as the evaluation variable for the heat output from the reaction space. In a further refinement, the absolute temperatures, for example the temperature of the cooling water entering the cooling screen and the temperature of the cooling water leaving the cooling screen, can be evaluated as evaluation variables for the heat output from the reaction space.

In a further refinement, a temperature difference, for example between the temperature of the cooling water leaving the cooling screen and the temperature of the cooling water entering the cooling screen, can be evaluated as evaluation variables for the heat output from the reaction space.

In a further embodiment, a plurality of heat flows in different regions of the reactor chamber can be evaluated to determine the heat flow from the reaction space.

In a further embodiment can serve as a rating for the heat flow from the Reaction space, the currently implemented fuel quantity are evaluated.

In a further refinement, the produced synthesis gas quantity can be evaluated as the evaluation variable for the heat output from the reaction space.

In a further embodiment, the supplied amount of gasification agent may be limited by the boundary condition of a permissible oxygen / fuel ratio.

In a further embodiment, the supplied amount of gasification agent by the boundary condition of a maximum allowable pressure difference between the reaction space ( 4 ) and quench area ( 5 ) be limited.

In a further embodiment, to avoid an overshoot of the control, the trend of the change in the heat flow from the reactor to the control act. As a result, an overshoot of the control is prevented and allows a more stable driving.

By adjusting the setting via different evaluation variables from the gasification process, the control becomes more stable in its function.

In a further embodiment, the control can be superimposed on an independent system for safety shutdown, in particular due to exceeding of a limiting pressure P or a limit temperature.

In a further embodiment, an intervention of the operating personnel may be given.

The adjustment thus takes place via an intelligent controller, which realizes compliance with the heat flow in a given range, taking into account the current load case, without exceeding the prescribed lambda values (i.e.e gasification agent / fuel ratio).

By automatically setting a constant heat flow, it is possible to control the process largely independently of the constant intervention of the operator, even if boundary conditions such as fuel composition or the composition of their inert substances change during operation.

Advantageous developments of the invention are specified in the subclaims.

The invention is explained in more detail below as an exemplary embodiment in a scope necessary for understanding with reference to figures. Showing:

1 a schematic representation of a gasification reactor,

2 a schematic representation of a carburetor control with correction of the oxygen addition on the amount of heat introduced and the temperature of the cooling screen,

3 a schematic representation of a carburetor control with correction of the oxygen addition on the amount of heat introduced and the temperature of the cooling screen as a function of the amount of coal and the coal properties and

4 a schematic representation of a carburetor control with correction of the oxygen addition on the amount of heat introduced and the temperatures on the cooling screen as a function of the amount of coal, the coal properties and the trend of change in the amount of heat.

In the figures, like names denote like elements.

1 shows a gasification device for the gasification of ash-forming solid or liquid carbonaceous fuels in the air flow under ambient pressure up to a pressure of 8 MPa and temperatures between 1250 ° C and 1900 ° C. The gasification device is on the head side via a burner 1 the fuel 2 and the gasifying agent 3 , in particular the oxidizing agent oxygen, fed. Fuel and gasification agent are in the arranged in the upper part of the gasification chamber 4 , which may also be referred to as the reaction space, gasified in a flame reaction under partial oxidation to a rich in hydrogen and carbon monoxide gasification gas. The gasification room is through a cooling screen 8th limited, which is formed by water-flow cooling tubes. The gasification gas, together with the molten slag, passes from the gasification chamber into a quench space arranged underneath 5 where by injecting water through nozzles 6 a raw gas conversion takes place and the slag is granulated in a bottom water bath. The raw gas 7 from the quench space is sent for further processing or use.

example 1

Correction of the oxygen addition via the amount of heat introduced and the temperature of the cooling screen according to FIG. 2:

The setpoint for the regulation of the oxygen flow 9 will be corrected over in the cooling screen 8th introduced amounts of heat 10 . 11 and the adjusting temperature 12 at the end of the cooling of the cooling screen.

These are the amounts of heat 10 . 11 compared with the respective expected values and depending on the deviation, the oxygen addition is varied so that the re-adjusting amounts of heat equal the expected values, without affecting the temperature 12 at the end of the cooling of the cooling screen changed significantly.

About a switch 15 it is possible at any time, the value for the regulation of the oxygen flow to fixed lambda value control by intervention of the operating personnel 16 with the possibility to vary the lambda value default and thus the gasification agent addition by means of correction factor.

For all corrective movements, the setting result of the controller with the permissible safety limits is also displayed 18 of the system, in the present case primarily with the calculated lambda value, adjusted and if necessary via a corresponding limiter 17 kept in the process-technically permissible range. Should this range be exceeded takes place via the switch 19 a security intervention 20 which brings the system into a safe state.

Example 2

Correction of the oxygen addition via the amount of heat introduced and the temperature of the cooling screen as a function of the fuel, in particular the amount of coal and the carbon properties according to FIG. 3:

The setpoint 9 for the control of the oxygen flow is corrected by the amount of heat introduced into the cooling screen depending on the fuel 2 and its properties and the resulting temperature 12 at the end of the cooling of the cooling screen.

These are the amounts of heat 10 . 11 compared with the respective expected values. This comparison 13 is guided by the instantaneous throughput of the fuel 2 (Coal) and the current properties of the fuel 22 such as calorific value and inert matter content. Depending on the deviation thus determined 21 the oxygen addition is via a corrective 14 varies, so that then adjusting amounts of heat 10 . 11 The calculated and adjusted expected values can be adjusted without the temperature 12 at the end of the cooling of the cooling screen changed significantly.

About a switch 15 it is possible at any time, the value for the regulation of the oxygen flow to fixed lambda value control by intervention of the operating personnel 16 switch with the possibility of the lambda value specification and thus to vary the gasification agent addition by means of correction factor.

For all corrective movements, the setting result of the controller with the permissible safety limits is also displayed 18 of the system, in the present case primarily with the calculated lambda value, adjusted and if necessary via a corresponding limiter 17 kept in the process-technically permissible range. Should this range be exceeded takes place via the switch 19 a security intervention 20 which brings the system into a safe state.

Example 3

Correction of the addition of oxygen via the amount of heat introduced and the temperatures on the cooling screen as a function of the amount of coal and the carbon properties and the trend of the change in the heat input according to FIG. 4:

The setpoint 9 for the control of the oxygen flow is corrected by the amount of heat introduced into the cooling screen 10 . 11 depending on the amount of fuel 2 and the fuel properties 22 as well as depending on the trend of the temporal change of the heat input 24 , the adjusting temperatures 12 at the end of the cooling of the cooling screen and in certain Kühlschirmabschitten 23 ,

These are the amounts of heat 10 . 11 in several sections, in particular two sections of the cooling screen 8th compared with the respective expected values. This comparison 21 is guided by the instantaneous throughput of the fuel 2 (Coal) and the current properties of the fuel 22 , such as calorific value and inert matter content. The deviation thus determined is further enhanced, attenuated or possibly ignored on the basis of the change over time in order to react flexibly and quickly, but also to avoid overreactions and misinterpretations. On the basis of the deviation thus determined 14 . 25 the oxygen addition is adjusted so that the resulting heat quantities can match the given expected values, without the two temperatures 12 . 23 increase significantly at the end of the cooling of the cooling screen and the cooling screen section.

About a switch 15 it is possible at any time, the value for the regulation of the oxygen flow through intervention of the operating personnel 16 , with the ability to switch to fixed lambda value control, with the possibility of the lambda value specification and thus the gasification agent addition then vary by means of correction factor.

For all corrective movements, the setting result of the controller with the permissible safety limits is also displayed 18 . 26 of the system, in the present case primarily with the calculated lambda value and expandable by, for example, the amount of raw gas produced 26 , adjusted and if necessary via a corresponding limiter 17 or 26 kept in the process-technically permissible range. Should this range be exceeded, via the coupling takes place 19 a security intervention 20 which brings the system into a safe state.

The carburettor control is via the coupling 19 a security intervention 20 superimposed, for example, downshifts the supply of gasification agent to the carburetor when a limit temperature or a limit pressure is exceeded.

Exceeding a limit pressure can, for example, by the pressure P in the gasification space 4 or in the pressure difference between the gasification chamber 4 and quenching room 5 be given, exceeding the temperature, for example, by inadmissibly high temperatures in the raw gas 7 , in the reactor room 4 or in the quench room 5 be given.

LIST OF REFERENCE NUMBERS

1

burner

2

fuel

3

oxidant

4

gasification chamber

5

quench

6

jet

7

raw gas

8th

cooling screen

9

Setpoint for oxygen controller

10

Amount of heat Q 1

11

Amount of heat Q 2

12

temperature

13

comparison

14

correction

15

switch

16

Intervention operator

17

limiter

18

Upper and lower limits of lambda value

19

Coupling security intervention

20

safety catch

21

correction

22

fuel properties

23

Temperature cooling screen section

24

Trend of change

25

correction

26

limiter

Claims (12)

A method for controlling and monitoring of Flugstromreaktoren with cooled reaction space structure in the form of a cooling water-flowed cooling screen, the amount of cooling water and their input and output temperatures are measured and used to determine the amount of heat transferred and used for process control, characterized in that the heat transfer amounts with each Compare expected values and, depending on their deviations, the amounts of oxygen supplied are changed until the re-adjusting amounts of heat equal the expected values without the temperature at the end of the cooling of the cooling screen substantially changing. A method according to claim 1, characterized in that the introduced depending on the fuel quantity and the fuel properties in the cooling screen amount of heat is compared with the respective expected values and based on this comparison, taking into account the instantaneous throughput of the fuel, the oxygen addition is changed until the in Adjust the amount of heat entered in the cooling screen to the expected values. Method according to one of the preceding claims, characterized in that the supplied amount of gasification agent is limited by a predetermined gasification agent / fuel ratio. Method according to one of the preceding claims, characterized in that the amount of gasification agent supplied is limited by the maximum permissible pressure difference between the reaction space and quench area. Method according to one of the preceding claims, characterized in that the heat flow from the reaction space in different areas of the reaction space is determined. Method according to one of the preceding claims, characterized in that the heat flow from the reaction space in accordance with the self-adjusting absolute temperature is determined. Method according to one of the preceding claims, characterized in that the heat flow from the reaction space is determined in accordance with a self-adjusting temperature difference. Method according to one of the preceding claims, characterized in that the heat flow from the reaction space is determined in accordance with the amount of fuel supplied. Method according to one of the preceding claims, characterized in that the heat flow from the reaction space is determined in accordance with the raw gas quantity produced. Method according to one of the preceding claims, characterized in that to avoid overshoot of the control, the trend of the change in the heat flow from the reaction chamber acts on the control. Method according to one of the preceding claims, characterized in that a possibility for intervention of the operating personnel is given. Method according to one of the preceding claims, characterized in that the control of the heat flow is superimposed on an independent system of safety shutdown.

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