JP3204714B2 - Ammonia supply device and supply method to denitration device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus and a method for supplying ammonia to a denitration apparatus, and more particularly to an apparatus for supplying ammonia to a denitration apparatus suitable for reducing nitrogen oxides in exhaust gas using ammonia water. And supply method.

[0002]

2. Description of the Related Art As environmental pollution problems such as acid rain are attracting worldwide attention, demand for a denitration apparatus for removing nitrogen oxides in exhaust gas is increasing. Conventionally, liquid ammonia has been used as a reducing agent used in this denitration apparatus. However, there is a tendency to shift to using ammonia water from the viewpoint of ease of storage and handling and safety. Ammonia water is usually 20 to 30% by weight of ammonia water dissolved in water. However, for use in a denitration device, only ammonia is separated from ammonia water or two types of ammonia water are vaporized and used at once. There is a way. The present invention belongs to the latter.

FIG. 4 shows an embodiment according to the prior art. The air 1 is sent to the ammonia water evaporator 3 by the fan 2, and is heated by the heater element 5. On the other hand, the ammonia water 7 is supplied through an ammonia water injection pipe, is sprayed from the ammonia water spray nozzle 7 'by the ammonia spray air 6, and then is evaporated by the heat of the heated air to form ammonia gas, water vapor, and air. Of mixed gas 8. This mixed gas 8 is injected into the exhaust gas duct 9 by the ammonia injection device 11 on the upstream side of the denitration catalyst 12, mixed with the exhaust gas, and acts as a denitration reducing agent.

The electric heater 4 used in the present process generally raises the temperature by bringing the air 1 into direct contact with the heated heater element 5. If the amount of air contact with the heater element 5 is uneven, the electric heater 4 is contacted. Since the part having a small amount has a small amount of heat dissipated, the element 5 may be heated more than other parts and may damage the element 5, and in order to prevent this, a heater inlet rectifying plate 17 is provided. At the heater outlet, a parallel plate type straightening plate 18 is provided to uniformly send the heated air to the ammonia water spray nozzle 7 '. The rising temperature of the air is determined by the heat capacity of the ammonia water to evaporate, and is usually set at 300 to 400 ° C. A method for controlling the air temperature is to provide a temperature detection seat (shown by TC in the figure) between the heater outlet air straightening plate 18 and the ammonia water spray nozzle 7 ', and to measure the measured temperature and the heater set temperature. The on / off control of the current of the heater element is performed so that the values of the currents coincide.

[0005]

SUMMARY OF THE INVENTION
(1) Appropriate evaporation of ammonia water, (2) Appropriate control of electric heater, (3) Rectification of heated air, (4) Energy saving of electric heater, (5) Prevention of heater damage. It was insufficient and had the following problems. (1) Since the pipe in the duct of the ammonia water 7 is heated by the radiant heat of the heater element 5 and the ammonia evaporates in the pipe and separates from the water, a steady uniform spray from the nozzle 7 'cannot be obtained. In addition, the rectification of the heated air at the ammonia nozzle 7 'is not sufficient, and there is a problem that the ammonia does not sufficiently evaporate in the low-temperature air portion. (2) Since the temperature detector is heated by the radiant heat of the heater element 5 and does not indicate the correct temperature of the heated air, the heater temperature control does not operate normally. (3) The temperature-raised air rectifying plate is intended to send a uniform flow of temperature-raised air to the ammonia water evaporating section to efficiently evaporate the ammonia water.
In No. 8, since the temperature of the heated air in the duct increased above the duct, the flow velocity increased, and a uniform flow velocity in the ammonia evaporator could not be obtained. For this reason, extra energy is required by the heater in order to secure the amount of heat in the portion where the flow velocity is slow. (4) The heater element 5 transfers heat to the air in contact with the heater element 5 in the form of heat transfer, and raises the temperature of the air by radiant heat. In addition to the heat transfer to the air, the heater element 5 is described in (1) and (2). As described above, the energy for heating the members around the heater element by the radiant heat is not directly used for heating the air, and is lost. (5) In the structure of the conventional ammonia water evaporator, when an exhaust gas backflow occurs due to an accident such as an apparatus trip, the heater element 5 is in a state where the ammonia water has not evaporated.
, And the heater element 5 may be damaged by rapid cooling.

An object of the present invention is to solve the above-mentioned problems of the prior art, and to provide an ammonia supply apparatus and a supply method for a denitration apparatus which has a stable evaporation ability, is economical and has high thermal efficiency.

[0007]

Means for Solving the Problems To achieve the above object, a first invention of the present application comprises a gas supply device, a heating device for heating the supplied gas, and a method for spraying ammonia water into the heated gas. And an ammonia water injection device for supplying a mixture of evaporated ammonia, water vapor and gas to the denitration device, wherein a wire mesh layer is arranged between the heating device and the ammonia water injection device. The present invention relates to a device for supplying ammonia to a denitration device.

[0008] The second invention of the present application relates to the ammonia supply device for the denitration device, wherein the gas body is air and the heating device is an electric heater in the first invention. A third invention of the present application is the ammonia supply apparatus for a denitration apparatus according to the first and second inventions, wherein a wire mesh layer is arranged between the gas or air supply apparatus and the heating apparatus. About.

In a fourth aspect of the present invention, a gaseous body is supplied to a heating device, the supplied gaseous body is heated, ammonia water is injected into the heated gaseous body to evaporate, and the evaporated ammonia water and In the method of supplying ammonia to a denitration device, which supplies a mixture of gas bodies to a denitration device, the heating gas exiting the heating device is passed through a wire mesh layer, and the temperature of the passing heating gas is detected so as to reach a predetermined temperature. The present invention also relates to a method for supplying ammonia to a denitration device, which comprises adjusting a heating device and injecting ammonia water into the gas to evaporate the gas.

[0010]

The wire mesh layer provided between the air heater and the ammonia water spray nozzle (1) shields the radiant heat of the heater element, improves the evaporation of the ammonia water, and detects the temperature of the heated gas. (2) Due to the multi-layer structure of the small diameter wire, the heated air is rectified and a uniform flow is supplied to the ammonia evaporating part to help uniform evaporation of ammonia, and (3) ammonia water is prevented from scattering. Protects the heater element as a body. The above-mentioned operation solves the above-mentioned problem of the conventional technology.

[0011]

FIG. 1 shows an embodiment of the present invention. The difference from the prior art is that a wire mesh layer 14 is provided between the heater element 5 and the ammonia water spray nozzle 7 'instead of the parallel plate-type current plate. FIG. 2 shows an example of the structure of the wire mesh layer. Wire mesh layer 14
Is a combination of thin wires in multiple layers.
, The wire mesh is held by covering the entire surface, and the support member 16 supports the wire mesh layer 14. Although the effect of the present invention increases as the thickness of the wire mesh layer 14 increases, the pressure loss increases and the operation cost of the system increases.
The pressure loss is set to about 0 to 100 mmAq, and the thickness is set to about 100 to 200 mm when the thickness is reduced.

First, the first effect of the wire mesh according to the present invention, that is, the radiation heat shielding effect will be described. The thickness of the wire mesh layer 14 is set to 150 mm, the heater is started,
When air of 900 Nm ³ / h is blown and the temperature rises and becomes steady, the temperature of the temperature detector TC (see FIG. 1) when the wire mesh layer 14 is not provided and the radiant heat is directly received is as follows:
The temperature was about 500 ° C. On the other hand, the TC when the wire mesh layer 14 was provided was about 350 ° C. The temperature difference between the two is the difference in radiant heat received by the TC, and it can be seen that the wire mesh has an excellent effect of shielding radiant heat.
This radiant heat shielding effect suppresses the temperature rise of the ammonia water pipe due to the radiant heat, prevents ammonia from being separated from the ammonia water in the ammonia water pipe, and enables the temperature of the temperature detector TC of the heated air to indicate the correct gas temperature. Has the effect of doing The separation temperature of ammonia is
Although it depends on the nozzle spray pressure of the ammonia water and the concentration of the ammonia water, it is usually in the range of 50 to 90 ° C., and it is indispensable to keep the temperature of the ammonia water as low as possible for stable operation of the ammonia spray. The effect of preventing ammonia water separation by radiant heat shielding is particularly effective when applied to a large-section duct having a long ammonia water pipe.

Next, the air rectification effect, which is the second effect of the wire mesh, will be described. The heated air is bent in its flow path while passing through the small-diameter wire in the wire mesh, and the high flow rate portion has high resistance and the low flow speed portion has low resistance. , They tend to be averaged. The degree of this averaging is
Although it depends on the pressure loss of the wire mesh layer 14, it was found that a uniform flow sufficient to uniformly evaporate the sprayed ammonia water mist can be obtained with the above-mentioned about 50 to 100 mmAq. The rectified heated air serves to uniformly evaporate and vaporize the sprayed ammonia water fine particles, and can save heat energy supplied for ammonia water evaporation.

A third effect of the ammonia water scattering prevention member is that the ammonia water is received and held by the wire mesh by the multi-layer structure of the wire mesh, so that the ammonia water is prevented from scattering to the heater element. Can be prevented. Another effect is that the efficiency of the heater is increased by increasing the temperature of the heated air by the heat capacity of the wire mesh. That is, the heat stored in the wire mesh by the radiant heat is used for raising the temperature of the air, and the heat supplied to the heater can be saved by that much.

In the above embodiment, air is used as the heating medium for injecting ammonia, but a gas other than air, for example, nitrogen gas may be used. Further, although an example of the electric heater has been described as the heating device, a steam heating device or the like may be used. Another embodiment of the present invention is shown in FIG. The wire mesh layers 14 and 14a are provided in an upstream example and a downstream example of the electric heater 4. Utilizing the rectification effect of wire mesh and the effect of heating air by radiant heat,
The purpose is to rectify and preheat air at the inlet of the heater unit 4.

[0016]

According to the present invention, since the radiant heat of the electric heater is absorbed and shielded by the wire mesh, the ammonia water pipe is not directly heated by the radiant heat.
The separation of aqueous ammonia in the tube is prevented, and a uniform and stable spray can always be obtained. Also, by shielding radiant heat,
Appropriate gas temperature can be measured, and appropriate temperature control of the electric heater can be performed. In addition, since the ammonia is sprayed in the uniform heated air by rectifying the heated air, efficient ammonia water evaporation can be obtained. Further, there is also an effect of preventing the ammonia water from being scattered in the backflow to the heater element.

With the above effects, it is possible to provide an efficient and reliable ammonia supply device and a supply method.

[Brief description of the drawings]

FIG. 1 is a diagram showing a structure and a system system of an ammonia supply device according to the present invention.

FIG. 2 is a diagram showing a structure of a wire mesh layer applied to the present invention.

FIG. 3 is a diagram showing another embodiment of the present invention.

FIG. 4 is a diagram showing a conventional technique.

[Explanation of symbols]

1 ... air, 2 ... fan, 3 ... ammonia water evaporator, 4 ...
Electric heater, 5: heater element, 6: ammonia spraying air, 7: ammonia water, 7 ': ammonia water spray nozzle, 8: ammonia gas mixed air, 9: exhaust gas duct, 10: untreated exhaust gas, 11: ammonia injection apparatus,
12: NOx removal catalyst, 13: NOx removal exhaust gas, 14, 14a
... wire mesh layer, 15 ... wire mesh, 16 ... support member, 17 ... heater inlet air straightening plate, 18 ... heater outlet air straightening plate.

──────────────────────────────────────────────────続 き Continued on the front page (58) Field surveyed (Int. Cl. ⁷ , DB name) B01D 53/56 B01D 53/94

Claims (4)

(57) [Claims] 1. A gas body supply device, a heating device for heating a supplied gas body, and an ammonia water injection device for spraying ammonia water into the heated gas body to evaporate the gaseous body. An ammonia supply apparatus for supplying a mixture of gas bodies to a denitration apparatus, wherein a wire mesh layer is arranged between a heating apparatus and an ammonia water injection apparatus. 2. The ammonia supply device for a denitration device according to claim 1, wherein the gas body is air, and the heating device is an electric heater. 3. The ammonia supply device for a denitration device according to claim 1, wherein a wire mesh layer is disposed between the supply device for gas or air and the heating device. 4. A gas body is supplied to a heating device, the supplied gas body is heated, ammonia water is injected into the heated gas body to evaporate, and a mixture of the evaporated ammonia water and the gas body is formed. In the method of supplying ammonia to the denitration device, which is supplied to the denitration device, the heating gas exiting the heating device is passed through the wire mesh layer, and the temperature of the passed heating gas is detected to adjust the heating device to a predetermined temperature. A method for supplying ammonia to a denitration apparatus, wherein ammonia gas is injected into the gas to evaporate the gas.