JP2001234735A - Flow control device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent excessive supply of aqueous urea and cooling water to a carburetor. SOLUTION: A NOx removal reactor 11 and an internal combustion engine 12 are connected by an exhaust gas pipe 14. The carburetor 18 arranged the exhaust gas pipe 14 adds a reducing agent to exhaust gas G and aqueous as a reducing agent is supplied from an aqueous urea tank 19 via a liquid delivery pipe 20. A solenoid valve 21 for main valve, a solenoid valve 22 for regulating flow rate, a pump 23 and an aqueous urea flow meter 24 are successively interposed in the liquid delivery pipe 20. The carburetor 18 is provided with a water pipe 25 for supplying cooling water to cool the carburetor 18. In the water pipe 25, a solenoid valve 26 for main valve, a solenoid valve 27 for regulating flow rate and a cooling water flow meter 28 are successively interposed. A solenoid valve 29 for bypass communicates the liquid delivery pipe 20 with the water pipe 25. Each of the solenoid valve 21, 22, 26, 27, 29 is controlled by an operation signal from a program controller 35.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

TECHNICAL FIELD The present invention relates to a denitration apparatus for removing NO _X from particular nitrogen oxides, such as flue gas of an internal combustion engine (NO _X) containing gas, during the operation stop of the abnormality and denitrification apparatus of the denitration device The present invention relates to a flow control device for interrupting the flow of urea water or cooling water.

[0002]

Conventionally the NO _X processing techniques are required in various fields, as a general treatment method, it has been put into practical use as a flue gas denitrification technique. This flue gas denitration technology is roughly classified into a dry method and a wet method. At present, the selective catalytic reduction method, which is one of the dry methods, is technically advanced, and attracts attention as an effective denitration method. The main reaction of the selective catalytic reduction method is represented by the following equation.

4NO + 4NH ₃ + O ₂ → 4N ₂ + 6H ₂ 0 (1) In the reaction of the formula (1), ammonia, hydrocarbon, and carbon monoxide are used as a reducing agent. In particular, ammonia coexists with oxygen. also to remove selectively NO _X and is effective when used to remove of the NO _X contained in the exhaust gas such as a diesel engine. In this reaction, a noble metal such as platinum as a denitration agent, or an oxide such as vanadium (V), molybdenum (Mo), or tungsten (W) as an additive mainly containing alumina and titanium oxide (TiO ₂ ), Catalysts containing double salts are used.

[0004] The selective catalytic reduction method is a simple system.
NO _X can be treated, high NOx removal rate can be obtained, and NO _X can be decomposed into harmless nitrogen gas (N ₂ ) and moisture (H ₂ O), so waste liquid treatment is unnecessary. There is an advantage. Ammonia gas or aqueous ammonia is used as a reducing agent, but urea water is being used from the viewpoint of cost because ammonia is expensive.

[0005]

In the above-described denitration apparatus using ammonia, the injection amount of urea and ammonia must be controlled so that the denitration reaction occurs at a rate close to the theoretical reaction as shown in the above equation (1). Must. This is because if the injection amount is small, the denitration rate is reduced, and if it is too large, ammonia may leak and emit an odor.

[0006] Conventional injection amount control methods include a method of controlling the injection of ammonia (urea) in proportion to the output of a generator driven by a diesel engine, and a method of controlling the injection of exhaust gas discharged from an internal combustion engine. by measuring the NO _X concentration,
And a method of controlling the injection of ammonia (urea).

However, a diesel internal combustion engine, the amount of exhaust gas, since the NO _X concentration is greatly changed by the ambient conditions or the like, wherein (1) NO amount of expression is changed significantly. The NO amount can be obtained from the NO concentration and the exhaust gas amount,
Since the gas amount measurement cannot be performed automatically, it has not been possible to actually control the injection amount of ammonia (urea) by measuring the generation amount of NO.

For this reason, recently, the following denitration apparatus has been developed. The denitration apparatus is provided with an internal combustion engine that drives a generator, a denitration reactor that introduces exhaust gas exhausted from the internal combustion engine via a pipe, and a pipe in the middle of the pipe to add a reducing agent to the exhaust gas. vaporizer and made structure in which a to, those which by adding urea water reducing agent is contacted with the denitration catalyst in the denitration reactor from the vaporizer to remove NO _X in the exhaust gas. The evaporator is configured to supply cooling water to maintain the set temperature because the temperature of the evaporator rises due to heat generated by the exhaust gas. The supply amounts of the urea water and the cooling water to the vaporizer are controlled by the control device.

In the denitration apparatus configured as described above, if an abnormality occurs in a control device (particularly, an electromagnetic valve or a pump) for controlling the supply amounts of urea water and cooling water to the vaporizer, urea is unnecessarily increased. Water and cooling water may continue to be supplied to the vaporizer.

The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a flow control device which prevents excessive supply of urea water and cooling water to a vaporizer.

[0011]

SUMMARY OF THE INVENTION To achieve the above object, the present invention provides a carburetor in an exhaust gas pipe through which exhaust gas discharged from an internal combustion engine flows, and an exhaust gas flowing through the pipe. to, by adding a reducing agent from the vaporizer into contact with the denitration catalyst, a denitration apparatus for removing NO _X in the exhaust gas, the vaporizer to the reducing agent of the cooling of the conduit and the vaporizer cooling additives Along with providing a water supply pipe, an electromagnetic valve is provided in each of the pipes closest to the reducing agent supply side and the cooling water supply side, and a flow meter is inserted in the vicinity of the vaporizer in each of the pipes, The flow signal of the flow meter is input to the controller, and if the flow signal is input to the controller when the operation of the denitration apparatus is stopped, a closing operation signal is supplied from the controller to each of the solenoid valves. Is what you do.

[0012]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a schematic configuration diagram showing an embodiment of the present invention. In FIG. 1, reference numeral 11 denotes a closed type denitration reactor, 12 denotes an internal combustion engine composed of a diesel engine driving a generator 13, and 14 denotes a denitration reactor 11. And internal combustion engine 1
2 is an exhaust gas pipe connecting the second exhaust gas to the second exhaust gas.

The denitration reactor 11 has an introduction portion 11a for introducing exhaust gas G from an exhaust gas pipe 14, and a denitration reactor 11
A discharge portion 11b for discharging the exhaust gas G is further formed, and a shielding plate 15 is provided inside the denitration reactor 11 at a position facing the introduction portion 11a, and further a denitration formed in a honeycomb shape. The catalysts 16 are stacked and arranged, and a temperature sensor 17 composed of a thermocouple for measuring the temperature of the denitration catalyst 16 is provided. As the denitration catalyst 16,
A zeolite (ZSM-5) is used as a main raw material, a zeolite is formed in a honeycomb shape, and then calcined to produce a catalyst carrier, and cobalt is carried on the catalyst carrier by ion exchange.

Reference numeral 18 denotes a vaporizer disposed in the exhaust gas pipe 14 in the middle thereof. The vaporizer 18 adds a reducing agent to the exhaust gas G, and urea water is supplied from a urea water tank 19 as a reducing agent. The gas is supplied to the vaporizer 18 via the feed pipe 20. Further, the evaporator 18 is provided with a water pipe 25 for supplying cooling water for cooling it. Reference numeral 34 denotes a denitration control device for controlling the denitration device such as adjusting the amount of the reducing agent added, and reference numeral 35 denotes a program controller for sending various settings and operation signals. A signal from the generator 13, a signal from the temperature sensor 17 provided in the denitration reactor 11, and a signal from the thermocouple 30 provided in the vaporizer 18 are input to the program controller 35.

In the denitration control device 34, an electromagnetic valve 21 for a main valve, an electromagnetic valve 22 for flow rate adjustment, a pump 23, and a urea water flow meter 24 which are sequentially inserted in the middle of the liquid feed pipe 20 are provided. . In particular, the solenoid valve 21 is provided on the liquid feed pipe 20 closest to the inner wall of the denitration control device 34 into which the liquid feed pipe 20 is introduced from the urea water tank 19.

In the denitration control device 34, a solenoid valve 2 for a main plug, which is sequentially inserted in the middle of the water pipe 25, is provided.
6. A solenoid valve 27 for adjusting the flow rate and a cooling water flow meter 28 are provided. In particular, the solenoid valve 26 is connected to the water pipe 25 closest to the inner wall of the denitration control device 34 into which the water pipe 25 is introduced.
Is provided. Reference numeral 29 denotes a bypass solenoid valve. The solenoid valve 29 has a function of connecting the liquid feed pipe 20 and the water pipe 25 to mix urea water and cooling water respectively.

[0017] 31 NO in _X analyzer, sensor 3 arranged in the denitration reactor 11 connected flue 32 to the discharge unit 11b of the
3, and measures the concentration of NO _X in the exhaust gas G after being denitration.

The urea water flow meter 24 and the cooling water flow meter 28
And each signal from the NO _X analyzer 31 is input to a program controller 35, which is controlled together with the input signal by the controller 35, and sends an operation signal to the pump 23 and each of the solenoid valves 21, 22, 26, 27, 29. Is supplied.

In the denitration apparatus configured as described above, the solenoid valve 21 for the main valve and the solenoid valve 22 for flow rate adjustment are opened by an operation signal from the program controller 35,
Urea water is vaporized from the liquid feed pipe 20 using the pump 23 to the vaporizer 1.
8. Then, the urea water is thermally decomposed in the vaporizer 18 by the heat supplied from the exhaust gas G. The ammonia gas vaporized by the thermal decomposition is discharged from a hole (not shown) formed in the vaporizer 18 into the exhaust gas pipe 14 and added to the exhaust gas G as a reducing agent. At this time, the temperature inside the vaporizer 18 is measured by the thermocouple 30, and based on the measured temperature, the solenoid valve 26 for the main valve and the solenoid valve 27 for flow rate adjustment are opened by an operation signal from the program controller 35. Then, cooling water is supplied from the water pipe 25 to the vaporizer 18, and the temperature inside the vaporizer 18 is adjusted to be in a range of 90C to 162C.

In the denitration apparatus operating as described above,
The flow rates of the urea water and the cooling water are measured by flow meters 24 and 28, respectively, and are supplied to a program controller 35. Therefore, when the operation of the denitration device is stopped, if the solenoid valves 22 and 27 for adjusting the flow rate are broken, the urea water or the cooling water may continue to flow. For example, when the flow control solenoid valve 27 fails, the cooling water continues to be supplied to the carburetor 18 more and more, the cooling water overflows from the carburetor 18, flows backward in the exhaust gas pipe 14, and flows into the diesel engine 12. There is a risk that it will.

However, even in such a case, since the cooling water flow meter 28 is provided, the flow rate is measured even when the operation of the denitration apparatus is stopped, and the cooling water is supplied to the vaporizer 18 based on the flow rate measurement result. Is determined, and this is reported and an alarm is issued. Along with this alarm, the program controller 35 sends a closing operation signal to the main valve solenoid valve 26 to close the main valve solenoid valve 26 and stop the supply of cooling water. When the supply of the urea water is stopped, the same operation is performed, and the solenoid valve 21 for the main stopper is operated.
Or the operation of the pump 23 is stopped.

The flowchart shown in FIG. 2 corresponds to the above description of the operation, and FIG. 2 will be briefly described below.
In FIG. 2, when the denitration device is stopped (S1), it is determined in step S2 whether the flow rate of the urea water flow meter is zero (yes) or not (no). If the result of determination is yes, it is determined in step S4 whether the cooling water flow meter is zero (yes) or not (no) in step S3. As a result of the judgment, ye
If s, the operation is determined to be normal and the process ends (S
4).

Next, if the answer is no in steps S2 and S3, it is determined that there is a flow rate and an alarm is issued in step S5.
At 7, the abnormal processing ends.

[0024]

As described above, according to the present invention,
Even if a control device such as a solenoid valve or a pump in the denitration device breaks down, the flow rate of urea water and cooling water is measured and monitored by the program controller. It is possible to prevent backflow to the engine side. In addition, since it can be easily installed in an existing device, it is technically and economically advantageous.

[Brief description of the drawings]

FIG. 1 is a schematic configuration explanatory view showing an embodiment of the present invention.

FIG. 2 is a flowchart for explaining the operation.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 11 ... Denitrification reactor 12 ... Diesel engine 13 ... Generator 14 ... Exhaust gas piping 17 ... Temperature sensor 18 ... Vaporizer 19 ... Urea water tank 20 ... Liquid sending piping 21, 26 ... Solenoid valve for main plug 22, 27 ... Flow rate Solenoid valve for adjustment 23 ... Pump 24 ... Urea water flow meter 25 ... Water pipe 28 ... Cooling water flow meter 29 ... Electromagnetic valve for bypass 30 ... Thermocouple 34 ... Denitration control device 35 ... Program controller

Claims (1)

[Claims] 1. A carburetor is provided in an exhaust gas pipe through which exhaust gas discharged from an internal combustion engine flows, and a reducing agent is added from the carburetor to the exhaust gas flowing through the pipe to make contact with a denitration catalyst. a denitration apparatus for removing NO _X in the exhaust gas, the vaporizer is provided with the additive conduit and the cooling water supply conduit of the vaporizer for cooling of the reducing agent, the reducing agent supply side and the cooling water supply An electromagnetic valve is provided in each of the two pipes closest to the side, and a flow meter is inserted in the vicinity of the vaporizer in each of the pipes, and a flow signal of the flow meter is input to the controller, and the operation of the denitration device is stopped. A flow control device characterized in that if a flow signal is input to the controller from time to time, a closing operation signal is supplied from the controller to each of the solenoid valves.