JP2005232130A - Method for separating mist - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method for separating mist that can prevent solid matter from sticking to the mist separator, when solid substance is included in the gas fed to the separator. <P>SOLUTION: In this mist separation method, a solid matter-including gas that contains mist and solid matter is fed into a mist separator to separate the mist. In this case, the solid matter-including gas in the mist separator is allowed to satisfy the following relations: W2 > W1, preferably W2 > (1.01 x W1) wherein W1 is the totao amount of saturated moisture per gas unit capacity and W2 is the total amount of saturated moisture per gas unit capacity. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

 The present invention relates to a mist separation method for separating mist from a solid-containing gas containing mist and solids by a mist separator.

Mist separators are widely used for the purpose of separating mist contained in gas, and are used, for example, in the production of (meth) acrylic acid.
Here, the usage example of the mist separator in manufacture of (meth) acrylic acid is demonstrated as an example of use of a mist separator. In the production of (meth) acrylic acid, as shown in FIG. 1, an oxidation reactor 11 for performing a gas phase oxidation reaction, and (meth) acrylic acid from (meth) acrylic acid-containing gas discharged from the oxidation reactor 11 are used. A production apparatus including a collection tower 12 for collecting and a mist separator 13 for separating mist in the gas discharged from the collection tower 12 is used. And the (meth) acrylic acid containing gas discharged | emitted from the oxidation reactor 11 is guide | induced to the collection tower 12, water is sprayed in the inside of the collection tower 12, and the (meth) acrylic acid containing gas in the water is contained in it. Collects (meth) acrylic acid. When water is sprayed in the collection tower 12 in this way, mist which is fine particles of water may accompany the gas discharged from the top of the collection tower 12. Gas containing mist may cause scale to adhere to piping, equipment, etc. When the amount of adhesion increases, the production of (meth) acrylic acid must be interrupted, and the scale must be removed artificially or chemically. I had to.
Therefore, mist in the gas discharged from the collection tower 12 is separated by the mist separator 13 for the purpose of preventing scale adhesion of piping, equipment, etc. (see, for example, Patent Document 1). The gas from which the mist has been separated is returned to the oxidation reactor 11 for dilution or treated as exhaust gas.
JP 2001-163828 A

However, in the production of (meth) acrylic acid, solid gas such as terephthalic acid may be included in the gas discharged from the collection tower. When solids are contained in the gas discharged from the collection tower, the solids adhere to the mist separator, so that problems such as an increase in pressure loss and a decrease in mist separation performance occur in the mist separator. As a result, production of (meth) acrylic acid had to be interrupted for maintenance.
In addition to the production of (meth) acrylic acid, the same problem sometimes occurs when mist is separated from a gas containing solids by a mist separator.
The objective of this invention is providing the mist separation method which prevents adhesion of the solid substance to a mist separator, when the solid substance is contained in the gas supplied to a mist separator.

When separating the mist from the gas containing solids by the mist separator, the present inventors, if the total moisture content per unit volume of gas in the gas in the mist separator is greater than a predetermined amount, The inventors have found that the amount of solid matter attached decreases, and invented the following mist separation method.
That is, the mist separation method of the present invention is a method for separating a mist by supplying a solid-containing gas containing a mist and a solid to a mist separator,
The solid-containing gas in the mist separator has a saturated water content W ₁ per unit gas volume and a total water content W ₂ per unit gas volume W ₂ > W ₁ , preferably W ₂ > (1.01 × It is characterized by satisfying the relationship of W ₁ ).
In the mist separation method of the present invention, it is preferable to entrain the mist in the solid-containing gas before supplying it into the mist separator.
The mist separation method of the present invention is particularly useful when the solid-containing gas is a gas discharged from a collection tower that collects (meth) acrylic acid in the (meth) acrylic acid-containing gas. Here, “(meth) acrylic acid” means acrylic acid and / or methacrylic acid.
The mist separation method of the present invention is particularly useful when the solid is a terephthalic acid-containing material.

According to the mist separation method of the present invention, it is possible to prevent the solid matter from adhering to the mist separator even if the solid matter-containing gas supplied to the mist separator contains a solid matter. As a result, in the mist separator, an increase in pressure loss and a decrease in mist separation performance can be prevented, and the number of times that production of (meth) acrylic acid is interrupted for maintenance can be reduced.
Moreover, if the solid-containing gas satisfies the relationship of W ₂ > (1.01 × W ₁ ), it is possible to further prevent the solid from adhering to the mist separator.

An embodiment of the mist separation method of the present invention will be described with reference to FIG.
In this embodiment, in the production of (meth) acrylic acid using the production apparatus of FIG. 1 described above, the mist in the gas discharged from the collection tower 12 for collecting (meth) acrylic acid is a mist separator. 13 relates to a mist separation method of separating at 13. In this mist separation method, water is sprayed in the collection tower 12 to collect (meth) acrylic acid from the (meth) acrylic acid-containing gas, so that the gas discharged from the collection tower 12 Contains. Moreover, the gas discharged | emitted from the collection tower 12 is solid substance containing gas containing solid substances, such as a terephthalic acid byproduced by the gaseous-phase oxidation reaction of (meth) acrylic acid.

In this mist separation method, the saturated water content W ₁ per gas unit volume and the total water content W ₂ per gas unit volume in the mist separator 13 are W ₂ > W ₁ , preferably W ₂ > ( Mist is separated as a solid-containing gas that satisfies the relationship of 1.01 × W ₁ ).
As described above, the solid-containing gas in the mist separator 13 has a saturated water content W ₁ per gas unit volume and a total water content W ₂ per gas unit volume of W ₂ > W ₁ , preferably W ₂ > ( Satisfying the relationship of 1.01 × W ₁ ) means that the moisture content is higher than the saturated moisture content and the relative humidity is high.

Here, the mist is fine particles of water. In this embodiment, since the solid-containing gas is a gas discharged from the collection tower 12 that collects (meth) acrylic acid in the (meth) acrylic acid-containing gas, Meta) acrolein is also included.
In the solid-containing gas, the saturated water content W ₁ per unit gas volume is the theoretical water content that reaches the saturated water vapor concentration when the temperature and pressure in the mist separator 13 are reached (the unit is, for example, [Kg / m ³ ]). Further, the total water content W ₂ per unit gas volume is the total amount of water (such as water vapor and water in the mist) actually contained in the solid-containing gas in the mist separator 13 (unit is: For example, [kg / m ³ ]).

In this mist separation method, the saturated water content W ₁ per unit gas volume and the total water content W ₂ per unit gas volume satisfy the relationship of W ₂ > W ₁ or W ₂ > (1.01 × W ₁ ). to may be increasing the total amount of water W ₂ by supplying water to the solids-containing gas.
As a method of supplying moisture to the solid-containing gas, a spray (moisture supply means) for supplying moisture to the solid-containing gas is provided near the gas introduction part of the mist separator 13 to introduce gas into the mist separator 13. A method of spraying water on the solid-containing gas by providing a spray near the portion is exemplified. By spraying water onto the solid-containing gas by spraying, the solid-containing gas can be accompanied by mist so as to satisfy the relationship of W ₂ > W ₁ . And if mist is made to accompany in this way, adhesion of the solid substance to a mist separator can be prevented more reliably.
Moreover, as means for supplying moisture to the solid-containing gas, water vapor may be supplied to the solid-containing gas.
Furthermore, as another method for satisfying the relationship of W ₂ > W ₁ or W ₂ > (1.01 × W ₁ ), the collection tower 12 is set to a gas flow velocity in which a predetermined amount of mist is accompanied by the gas. The method of designing is mentioned.

 As a typical form of the mist separator 13 that can be used in this mist separation method, a solid-containing gas is swirled to apply a centrifugal force, a mist having a large specific gravity is moved to the outside, and the mist is separated by a blade installed on the outside. The thing which capture | acquires and isolate | separates mist and gas is mentioned. Moreover, what passes a solid substance containing gas through a filter, capture | acquires mist with the filter, and isolate | separates mist and gas is mentioned.

 In this mist separation method, it is preferable that the mist in the solid-containing gas is separated as much as possible from the viewpoint of further preventing the scale from adhering to piping and equipment. The specification mist separator must be used and is not industrial. Therefore, it is preferable that the mist separated by the mist separator 13 has a particle diameter of 1000 μm or more, preferably 800 μm or more.

In the mist separation method described above, a solid-containing gas in which the saturated water content W ₁ per unit gas volume and the total water content W ₂ per unit gas volume satisfy the relationship of W ₂ > W _{1 in} the mist separator 13. Separate the mist from the. Since the solid-containing gas in the mist separator 13 satisfies the relationship of W ₂ > W ₁ and contains a lot of moisture, and the relative humidity is high, the evaporation of moisture in the mist attached to the mist separator is prevented. It can be reliably suppressed. As a result, since the surface in the mist separator 13 remains wet with moisture, it is possible to prevent the solid matter from being dried by the mist separator 13. Therefore, even when a gas containing solids is supplied, it is possible to prevent solids from adhering to the mist separator 13.

 The present invention is not limited to the above-described embodiment example. For example, the embodiment described above is an example of separating the mist in the solid-containing gas discharged from the collection tower for collecting (meth) acrylic acid, but the mist is removed from the gas containing the solid. If it isolate | separates with a mist separator, this invention can be applied without a restriction | limiting. Further, the solid material may be other than terephthalic acid.

Hereinafter, the present invention will be described in detail with reference to examples.
(Example)
In the oxidation reactor, tertiary butanol was subjected to a gas phase oxidation reaction to produce methacrolein and methacrylic acid, and then the gas containing methacrolein and methacrylic acid discharged from the oxidation reactor was led to a collection tower. And in the collection tower, the gas containing methacrolein and methacrylic acid was brought into contact with the aqueous methacrylic acid solution, and methacrylic acid contained in the gas was collected. Next, the gas after methacrylic acid collection varies depending on the operating conditions, but is passed through a mist separator at a flow rate of about 40,000 to 80,000 m ³ / hour in a standard state, and then absorbs methacrolein. Sent to absorption tower. Here, the gas after the collection of methacrylic acid contained a solid containing terephthalic acid as a main component. In addition, the mist separator is equipped with a blade that swirls a gas containing solid matter (solid matter-containing gas), and swirls the supplied solid matter-containing gas to impart centrifugal force to the mist. Then, the mist is moved outward and the mist is captured by the blade.

In this method for producing methacrylic acid, the temperature of the solid-containing gas supplied to the mist separator is set to 60 ° C., and water is supplied to the solid-containing gas in the vicinity of the gas introduction part of the mist separator at 0.05 m ³ / Sprayed in time. By supplying water to the solid-containing gas in this way, the solid-containing gas has a saturated water content W ₁ per unit gas volume of 0.05 to 0.1 kg / m ³ and a total water content per unit gas volume. the amount _{W 2} became 0.051~0.101kg / ^{m 3.} That is, the amount of W ₂ was (1.01 to 1.02) × W ₁ .
When production of methacrylic acid was continued for 1 year under these conditions, problems such as an increase in pressure loss in the mist separator and a decrease in mist separation performance did not occur. Furthermore, when the inside of the mist separator was inspected after the plant was shut down, no solid matter was observed.

(Comparative example)
In the mist separator, methacrylic acid was produced in the same manner as in Example except that spraying from the top was not performed and the solid-containing gas did not satisfy W ₂ > W ₁ . As a result, the pressure loss in the mist separator gradually increased from the start of operation, and after about 6 months, the pressure reached an allowable value and the production was forced to stop. When the inside of the mist separator was inspected, solid matter containing terephthalic acid as a main component adhered to the entire surface of the blade that swirled the gas.

  INDUSTRIAL APPLICABILITY The present invention can be used when a solid-containing gas containing mist and solid is supplied to a mist separator to separate the mist.

It is a figure which shows typically the manufacturing process of (meth) acrylic acid.

Explanation of symbols

12 Collection tower 13 Mist separator

Claims (5)

In a method for separating a mist by supplying a solid-containing gas containing a mist and a solid to a mist separator,
The solid-containing gas in the mist separator is characterized in that the saturated water content W ₁ per unit gas volume and the total water content W ₂ per unit gas volume satisfy the relationship of W ₂ > W _1. Mist separation method.   The mist separation method according to claim 1, wherein the mist is caused to accompany the solid-containing gas before being supplied to the mist separator. 3. The mist separation method according to claim 1, wherein the solid-containing gas in the mist separator satisfies a relationship of W ₂ > (1.01 × W ₁ ).   The solid substance-containing gas is a gas discharged from a collection tower that collects (meth) acrylic acid in the (meth) acrylic acid-containing gas. Mist separation method. The mist separation method according to any one of claims 1 to 4, wherein the solid substance is a terephthalic acid-containing substance.

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