JP2012024688A - Facility for treatment of gas in tunnel - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a facility for treatment of gas in a tunnel which may be achieved long lifetime of nitrogen dioxide absorbent compared with prior arts.SOLUTION: The facility for treating a gas in a tunnel includes: a duct 11 which enables the communication between the inside and the outside of the tunnel and can allow gas 1 in the tunnel to flow to the outside; an electrical dust precipitator 12 which is arranged in the duct 11; a nitrogen dioxide absorbent 13 which is placed in the duct 11 on the side of downstream of the flow of the gas 1 relative to the electrical dust precipitator 12; an air-permeable fine filter 15 which is arranged between the electrical dust precipitator 12 and the nitrogen dioxide absorbent 13 in the duct 11 and can trap only particles having particle diameters of less than 20 μm, and an air-permeable coarse filter 14 which is arranged between the fine filter 15 and the electrical dust precipitator 12 in the duct 11 and can trap particles having particle diameters of 20 μm or more.

Description

  The present invention relates to a tunnel gas processing facility for processing a gas in a tunnel through which an automobile or the like passes.

  In a tunnel through which an automobile or the like passes, exhaust gas from the automobile or the like tends to stay. Therefore, an in-tunnel gas processing facility is provided for ventilating while processing the gas in the tunnel outside the tunnel. As such a gas processing facility in the tunnel, for example, as described in Patent Document 1 below, the suspended particulate matter (SPM) is removed from the gas in the tunnel with an electric dust collector. From the above, after absorbing and removing nitrogen dioxide with a nitrogen dioxide absorbent, various post-treatments and exhausting them out of the tunnel are known.

  In such a conventional gas treatment facility in a tunnel, the nitrogen dioxide absorbent absorbs and removes nitrogen dioxide, so as the gas in the tunnel is treated, the nitrogen dioxide absorbent absorbs nitrogen dioxide. Is gradually reduced, so that the nitrogen dioxide absorbent is replaced every operation for a predetermined time.

JP 2009-240973 A JP-A-5-123533

  However, in the conventional tunnel gas treatment equipment as described above, the actual nitrogen dioxide absorption capacity of the nitrogen dioxide absorbent is considerably lower than the theoretical nitrogen dioxide absorption capacity. The life has been shortened.

  For this reason, when the present inventors diligently studied, particles such as oil mist (particle diameter: about 20 μm) in the gas are not completely removed by the electric dust collector (removal rate: about 80%), and the electric It turned out that the said particle | grains which passed the dust collector gradually coat | covered the surface of the nitrogen dioxide absorbent, and have gradually inhibited the nitrogen dioxide absorption ability of the nitrogen dioxide absorbent.

  Therefore, it is conceivable to increase the applied voltage of the electrostatic precipitator so as to increase the dust collection capacity of the electrostatic precipitator to increase the removal rate of the particles, but the applied voltage of the electrostatic precipitator is increased. As a result, a lot of ozone is generated, and nitrogen monoxide in the gas is oxidized into nitrogen dioxide, and the amount of nitrogen dioxide absorbed and removed by the nitrogen dioxide absorbent increases, eventually absorbing nitrogen dioxide. The life of the agent will not be significantly different from the conventional one.

  In view of the above, an object of the present invention is to provide a tunnel gas treatment facility capable of extending the life of a nitrogen dioxide absorbent as compared with the prior art.

  In order to solve the above-mentioned problems, a gas processing facility in a tunnel according to the present invention is provided in a duct that communicates the inside and outside of the tunnel and distributes the gas in the tunnel to the outside, and the duct. An electrostatic precipitator, a nitrogen dioxide absorbent disposed downstream of the electric precipitator in the duct in the flow direction of the gas, the electrostatic precipitator in the duct and the nitrogen dioxide absorption A fine filter having air permeability that is disposed between the agent and capable of collecting only particles having a particle diameter of less than 20 μm, and is disposed between the fine filter in the duct and the electric dust collector. A coarse filter having air permeability capable of collecting particles having a particle diameter of 20 μm or more is provided.

  The tunnel gas treatment facility according to the present invention is characterized in that, in the tunnel gas treatment facility described above, the fine filter can collect only particles having a particle size of 10 μm or more.

  According to the gas processing facility in a tunnel according to the present invention, particles such as oil mist that have passed without being removed by the electric dust collector can be removed by the filter, so that the applied voltage of the electric dust collector is increased. Therefore, it is possible to remarkably suppress the surface of the nitrogen dioxide absorbent from being coated with the particles, and it is possible to extend the life of the nitrogen dioxide absorbent as compared with the prior art.

It is a schematic block diagram of the principal part of main embodiment of the gas processing equipment in a tunnel which concerns on this invention. It is a graph showing the nitrogen dioxide removal rate with respect to the operation time of the Example and comparative example in the test conducted in order to confirm the effect of the gas processing equipment in a tunnel which concerns on this invention.

  Embodiments of a tunnel gas treatment facility according to the present invention will be described below with reference to the drawings. However, the present invention is not limited to the following embodiments described with reference to the drawings.

[Main embodiments]
A main embodiment of a gas processing facility in a tunnel according to the present invention will be described with reference to FIG.

  As shown in FIG. 1, an electrostatic precipitator 12 that removes suspended particulate matter (SPM) in the gas 1 is disposed in a duct 11 that connects the inside and outside of a tunnel through which an automobile or the like passes. ing. A nitrogen dioxide absorbent 13 that absorbs and removes nitrogen dioxide in the gas 1 is disposed downstream of the electric dust collector 12 in the duct 11 in the flow direction of the gas 1. This nitrogen dioxide absorbent 13 is a honeycomb carrier made of activated carbon or the like as a main raw material, impregnated with an alkali such as potassium hydroxide in an aqueous solution and dried, and the nitrogen dioxide is hydroxylated. Absorption is removed by reacting with an alkali such as potassium to make potassium nitrate or the like.

  Between the electric dust collector 12 and the nitrogen dioxide absorbent 13 in the duct 11, a non-woven fabric having air permeability capable of collecting only particles having a particle size of less than 20 μm (preferably further a particle size of 10 μm or more). A fine filter 15 is provided. Between the fine filter 15 in the duct 11 and the electrostatic precipitator 12, a coarse filter 14 made of an air-permeable nonwoven fabric capable of collecting particles having a particle diameter of 20 μm or more is disposed.

  In the in-tunnel gas processing facility according to this embodiment, when the gas 1 in the tunnel flows through the duct 11, the electrostatic precipitator 12 removes the SPM in the gas 1. At this time, although a part (about 20%) of particles such as oil mist (particle size: about 20 μm) in the gas 1 passes through the electrostatic precipitator 12 without being removed, the coarse filter 14 and the fine filter 15. Then, after the nitrogen dioxide is absorbed and removed by the nitrogen dioxide absorbent 13, the gas 1 is exhausted out of the tunnel after various post treatments.

  In other words, in the in-tunnel gas processing facility according to the present embodiment, the particles that have passed without being removed by the electrostatic precipitator 12 are collected by the filters 14 and 15.

  For this reason, in the in-tunnel gas treatment facility according to the present embodiment, the surface of the nitrogen dioxide absorbent 13 is remarkably suppressed from being covered with the particles without increasing the applied voltage of the electrostatic precipitator 12. Can do.

  Therefore, according to the in-tunnel gas treatment facility according to the present embodiment, the life of the nitrogen dioxide absorbent 13 can be extended as compared with the conventional case.

  In addition, the particles such as oil mist (particle size: about 20 μm) passed without being removed by the electrostatic precipitator 12 are collected by the coarse filter 14 and then collected by the fine filter 15. As a result, the fine filter 15 can be greatly prevented from being clogged at an early stage, and the periodic inspection interval and replacement of the filters 14 and 15 can be performed together with the extension of the replacement life of the nitrogen dioxide absorbent 13. Life can be extended.

  The thicknesses of the filters 14 and 15 are appropriately determined in consideration of the pressure loss and the like with respect to the gas 1, but are preferably 50 mm or less. In particular, the coarse filter 14 has a thickness of 40 mm or less. More preferably, the fine filter 15 has a thickness of 20 mm or less.

  Moreover, in this embodiment, although the case where the said filters 14 and 15 were each provided was demonstrated, as another embodiment, for example, the said filters 14 and 15 are each along the distribution direction of the said gas 1. It is also possible to provide a plurality of sheets. In this case, for example, at the time of maintenance / inspection management, each of the filters 14 and 15 located on the most upstream side in the flow direction of the gas 1 is moved to the most downstream side in the flow direction and located on the most upstream side. The filters 14 and 15 respectively disposed adjacent to the filters 14 and 15 are moved so as to be positioned on the most upstream side, and hereinafter, the filters 14 and 15 are upstream of the gas 1 in the flow direction. The filters 14 and 15 can be used without waste if they are arranged so as to be sequentially moved to the side. The number of the filters 14 and 15 is appropriately selected in consideration of the pressure loss with respect to the gas 1 and the thickness thereof.

  Here, the test result (Example) performed in order to confirm the effect of the gas processing equipment in a tunnel concerning the present invention is shown in FIG. For comparison, FIG. 2 also shows a test result (comparative example) in the case where there is no conventional tunnel gas treatment facility, that is, a coarse filter and a fine filter. The test conditions are as follows.

<gas>
And composition -CO _2: base NO: 1.5~2.0ppm
NO _2: 1.5~2.0ppm
Particles: 0.5-4.0 mg / m ³ (electric dust collector inlet)
・ Total gas amount: 860 Nm ³ / h
・ GHSV: 15000h ^-1
・ Temperature: 30 ± 5 ℃
・ Humidity: 70 ± 20%

<Coarse filter>
・ Capable particle size: 20 μm or more ・ Thickness: 40 mm

<Fine filter>
・ Capable particle size: 10 μm or more ・ Thickness: 20 mm

  As can be seen from FIG. 2, in the comparative example, the nitrogen dioxide removal rate by the nitrogen dioxide removing agent begins to gradually decrease from around 1000 hours, sharply decreases from around 2000 hours, and at 3000 hours. It became 90% or less. On the other hand, in the examples, the nitrogen dioxide removal rate by the nitrogen dioxide removing agent starts to gradually decrease from around 2000 hours, but the performance of 90% or more can be maintained even after 5000 hours. It could be confirmed.

  Since the in-tunnel gas treatment facility according to the present invention can extend the life of the nitrogen dioxide absorbent as compared with the prior art, it can be used extremely beneficially industrially.

1 Gas 11 Duct 12 Electric Dust Collector 13 Nitrogen Dioxide Absorber 14 Coarse Filter 15 Fine Filter

Claims (2)

A duct that connects the inside and outside of the tunnel and distributes the gas in the tunnel to the outside;
An electrostatic precipitator disposed in the duct;
A nitrogen dioxide absorbent disposed downstream of the electric dust collector in the duct in the gas flow direction; and
A fine filter having air permeability disposed between the electrostatic precipitator in the duct and the nitrogen dioxide absorbent and capable of collecting only particles having a particle size of less than 20 μm;
A tunnel having a breathability that is disposed between the fine filter in the duct and the electrostatic precipitator and is capable of collecting particles having a particle size of 20 μm or more. Gas processing equipment. In the tunnel gas treatment facility according to claim 1,
The tunnel gas treatment facility, wherein the fine filter is capable of collecting only particles having a particle size of 10 μm or more.

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