SE501971C2 - Use of hydrophobic zeolite to purify air containing mercaptans and H2S - Google Patents

Abstract

The use of hydrophobic zeolites for cleaning air which contains mercaptans and H2S.

Description

501 10 15 20 25 30 35 971 2 With the simultaneous removal of different mercaptans and HZS, there is thus the problem that it is difficult to obtain an effective removal of both mercaptans and H28. H25 is in fact much smaller than the various mercaptans and is thus not adsorbed particularly efficiently by a zeolite, which has larger pores and which is adapted for the various mercaptans.

We have found that the zeolites ZSM 5 (silicalite) and mordenite provide good and effective removal of both H25 and mercaptans when purifying air, and H28.

Mordenite is among the largest known zeolites with one containing mercaptans pore size of 7.5 Å and silicalite has a pore size of about 5.5 Å.

The pore size of the silicalite is such that both H28 and mercaptans are well adsorbed, but the pore size of the mordenite should not give a particularly effective adsorption of H28.

The structure of the mordenite, which is made up of 12-rings, is such that the 12-rings are connected by 8-rings. It has been found that these 8-rings, which have a smaller pore diameter, are excellently adapted to adsorb H28.

The structure of the silicalite is made up of only 10-rings.

In the paper industry and in treatment plants, there are problems with foul-smelling air emissions, and these air emissions contain mercaptans and H28, whereby H28 is also very toxic.

The air in many computer rooms also contains mercaptans and H25, and it is known that H25 causes corrosion in computer contactors. By purifying the air from mercaptans and H28, large financial gains can be made.

Thus, an object of the present invention is the use of hydrophobic zeolites in the purification of air intakes / emissions containing mercaptans and H S. 2 10 15 20 25 30 35 501 971 '3 A particular object of the present invention is the use of mordenite and / or ZSM 5 (silicalite) for purification of air intakes / emissions, containing mercaptans and H28.

These objects are achieved by using hydrophobic zeolites in the purification of air containing mercaptans and H2 zeolite having a zeolite space network structure ((AlO2) x (SiO2) Y], where x and y are integers and y / x> 15, in a sufficient to remove mercaptans and H28 efficiently.

The hydrophobic zeolites used in the present invention have the composition Nax [(AlO 2) x (SiO 2) Y], where x and y are integers and y / x> 15, preferably y / x> 20 and most preferably y / x> 45.

Two preferred hydrophobic zeolites are mordenite and silicalite, and in particular mordenite. The hydrophobic zeolites can be used in the form of powders on carriers, such as in rotors, or in the form of pellets of sintered zeolite crystals. In pellet form, commonly used binders are silica, alumina or certain clays. In the examples given below, the binder is alumina at a content of 15% by weight.

When using hydrophobic zeolites in the purification of air containing mercaptans and H28, the air is brought into contact with the hydrophobic zeolites, preferably mordenite and / or silicalite and most preferably mordenite, in an amount sufficient to effectively remove mercaptans and H28 .

The hydrophobic zeolites can be in the form of pellets and used in a filter bed. The advantage of the zeolites being in pellet form instead of as powder or granules is that a low pressure drop is obtained over the filter bed. In industry, there may be talk of thousands of m air / h flowing through the filter bed. On the other hand, zeolites in powder form can be used if carriers are used, and examples of carriers are rotors. 501 10 15 20 25 30 35 971 4 The attached figures 1-4 refer to the experiments according to examples 1-4.

Fig. 1a shows adsorption of H28 at 20 ° C using mordenite.

Fig. 1b shows adsorption of H28 at 45 ° C using mordenite.

Fig. 2 shows the breakthrough curve for mordenite on adsorption of CH3SH when the concentration of CH3SH at the inlet is 700 ppm.

Fig. 3 shows the breakthrough curve for mordenite upon adsorption of H28 when the concentration of H28 at the inlet is 45 ppm.

Fig. 4 shows the breakthrough curve for mordenite upon adsorption of H28 when the concentration of H28 at the inlet is 70 ppb.

Example 1 Adsorption of H28, CH3SH and C2§6§2 using mordenite and silicalite Pellets of the hydrophobic zeolites mordenite and silicalite with Si: Al> 50 and 90 respectively 90 were used in an experiment for adsorption of pure H28 , CH3SH and C2H6S2 at different temperatures. The results are shown in Table 1. 10 15 20 25 30 35 501 971 '5 Table 1 Zeolite Temperature Gas Adsorption (20 ° C) (weight%) Mordenite 20 ° C H28 5.6 45 ° C "3.8 Silicalite 20 ° C "1.0 45 ° C" 0.1 Mordenite 20 ° C CHSSH 12.7 45 ° C "9.1 Silicalite 20" C "10.0 45 ° C" 7.5 Silicalite 20 ° C C2H6S2 10.2 45 ° C "7.5 As shown in Table 1, mordenite is superior silicate in terms of adsorption of H25, but the adsorption of silicate of H28 is also good. The reason for these experiments at 45 ° C is that the air emissions from The paper industry is at higher temperatures, about 20-60 ° C, and we thus want to show that mordenite and silicalite also work within this temperature range.

Example 2 Breakthrough test for mordenite with CH3§§ Pellets of mordenite (from Tosoh, Japan) with Si: Al> 50 were used in a filter bed (with a volume of 0.3 dms) and air with a relative humidity of 60% and a CH3SH concentration of 700 ppm was allowed to pass through the bed with a residence time of 0.6 s. The air outlet had a CH 3 SH concentration of less than 1 ppm for 50 minutes.

Example 3 Breakthrough test for mordenite with 45 ppm H2 § Pellets of mordenite (from Tosoh, Japan) with Si: Al> 50 were used in a filter bed (with a volume of 0.3 dm3) and air with a relative humidity of 60% and an H 2 S concentration of 45 ppm was allowed to pass through the bed with a residence time of 1.5 s. The air outlet had an H concentration of less than 1 ppm for 18 minutes.

Example 4 Breakthrough test for mordenite with 70 ppb H2§ Pellets of mordenite (from Tosoh, Japan) with Si: Al> 50 were used in a filter bed (with a volume of 0.3 dm3) and air with a relative humidity of 75% and a H2S concentration of 70 ppb was allowed to pass through the bed with a residence time of 1.5 s. The air outlet had an H S concentration of less than 1 ppb for 38 minutes. 2S-con- 2 This experiment shows the mordenite's effective adsorption of H28 even at low H28 concentrations.

The use of the present invention is highly applicable in the paper industry to eliminate malodorous emissions of mercaptans and the highly toxic H28. H28 present in the air in sewage treatment plants is also easily removed according to the present invention. An additional area of use is the purification of air, which contains mercaptans and H28, in computer rooms. Namely, it has recently been shown that it is H28 or other sulfur compounds that cause corrosion of the computers.

Claims (5)

10 15 20 25 30 35 501 971 * PATENT REQUIREMENTS Use of hydrophobic zeolites in the purification of air containing mercaptans and H28, wherein the air is brought into contact with a hydrophobic zeolite having a zeolite space network structure [(AlO2) x (SiO2) Y], where x and y are integers and y / x> 15, in a sufficient amount to mainly remove mercaptans and H28. Use according to claim 1, wherein the hydrophobic zeolites consist of mordenite and / or ZSM (silicalite). Use according to claim 1 or 2, wherein the air containing mercaptans and H28 is constituted by air emissions from the paper industry. Use according to any one of claims 1-3, wherein the air, which contains mercaptans and H25, consists of air emissions from treatment plants. Use according to any one of claims 1-4, wherein and H the air, which contains mercaptans ZS, is constituted by air in computer rooms.