Gas separation – Means within gas stream for conducting concentrate to collector
Patent
1988-08-01
1990-08-14
Nozick, Bernard
Gas separation
Means within gas stream for conducting concentrate to collector
55387, B01D 5304
Patent
active
049484010
DESCRIPTION:
BRIEF SUMMARY
BACKGROUND OF THE INVENTION
The present invention relates to a gas mixture separator utilizing pressure modulation which is used, for example, in a fuel power plant and uses adsorbent that has pressure dependent adsorptivity, such as zeolite.
The typical prior examples of gas mixture separators utilizing pressure modulation (referred to as PSA hereafter) are disclosed in Japanese Patent Publication No. 20082/1970, Japanese Patent Provisional Publication No. 14070/1972, and Japanese Patent Provisional Publication No. 16874/1973. In any of the above prior art references, gases are separated from a mixture by: pressurizing an ingredient gas mixture with a suitable means, normally a gas compressor, to a certain pressure; then leading the mixture into adsorption towers that contain an adsorbent through valves; and repeating, for example, the following cycle:
(1) A supply gas is fed through a supply inlet, and part of the product gas is fed through an outlet to equalize the pressure.
(2) The supply gas continues to be fed to pressurize further.
(3) Part of the product gas is fed into another tower, and the pressure is equalized.
(4) Through parallel current depressurization, part of the product gas is used to purge another tower.
(5) With counter current depressurization the desorption of adsorbed components is carried out.
(6) The purge is received from an outlet.
TABLE 1. ______________________________________
Time from
the begin-
ning of
each cycle
Adsorption towers
(sec.) No. 1 No. 2 No. 3
______________________________________
0-15 Repressuriza-
Counter current
Pressure
tion depressuriza-
equalization
tion (I)
15-35 Repressuriza-
Discharge Parallel current
tion depressuriza-
tion
35-40 Repressuriza-
Repressuriza-
Pressure
tion tion equalization
(II)
40-55 Pressure Repressuriza-
Counter current
equalization
tion depressuriza-
(I) tion
55-75 Parrallel Repressuriza-
Discharge
current depres-
tion
surization
75-80 Pressure Repressuriza-
Repressuriza-
equalization
tion tion
(II)
80-95 Counter current
Pressure Repressuriza-
depressuriza-
equalization
tion
tion (I)
95-115 Discharge Parrallel Repressuriza-
current depres-
tion
surization
115-120 Repressuriza-
Pressure Repressuriza-
tion equalization
tion
(II)
______________________________________
FIG. 4 shows, as an example, an air separator utilizing an adsorption method that is used to separate the air into oxygen and nitrogen. According to this, after dust is removed from the air using an air filter 26, the air is pressurized to about 5 Kg/cm.sup.2 by an air compressor 27c, and the heat of compression is removed by a water cooler 28. Water is then removed by a water separator 29, and the air is led into adsorption towers 19a-19d.
The adsorption towers 19a-19d contain adsorbent 20a-20d, respectively, that is made of zeolite or the like having a filtering function. Of the air fed through valves 24a-24d, only the product gas component passes through the adsorbent 20a-20d and is led into a product gas holder 21 through valves 24e-24h.
Since a large amount of the air, compared with the adsorptivity of the adsorbent 20a-20d, is fed, it is necessary to desorb by depressurization in order to recover adsorptivity, followed by discharge of the waste air through valves 24i-24l.
Thus, to supply the product gas continuously, it is necessary to carry out adsorption under high pressure and desorption under low pressure periodically, and this requires at least two adsorption towers. Here, an example with 4 towers is shown. Also, 24m-24q in FIG. 4 are pressure equalization valves. The valves 24a-24q are controlled by a controller 22 to ensure smooth adsorption and desorption.
In order to make the air separator of FIG. 4 more economical, a cost reduction in equipment and in operation has to be achieved through a size reduction and an increase in operational efficiency.
To reduce equipment costs a reduction in time per cycle would be effective, and to achieve a higher ef
REFERENCES:
patent: 3121625 (1964-02-01), Broughton
patent: 3164454 (1965-01-01), Wilson
patent: 4354859 (1983-10-01), Keller et al.
patent: 4702903 (1987-10-01), Keefer
Izumi Jun
Ohshima Kazuaki
Tanabe Seiichi
Mitsubishi Jukogyo Kabushiki Kaisha
Nozick Bernard
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