JPH0290921A - Concentrator for fluorocarbon-containing gas - Google Patents

Abstract

PURPOSE:To make the rate of concentration of a fluorocarbon-containing gas higher by dehumidifying a gas containing fluorocarbon in low concentration thought an adsorption material consisting chiefly of zeolite and concentrating such gas after dehumidification by the action of gas adsorption and desorption produce through the honeycomb structure of an active carbon. CONSTITUTION:A dehumidifier 12 is provided with a rotor 20 consisting of a honeycomb structure containing zeolite as a main component and means for providing a dehumidifying zone 21 and regeneration zone 22 to the rotor 20. A gas containing fluorocarbon in low concentration is sent to the dehumidifying zone 21 and a heated regeneration air is sent to the regeneration zone 22. The gas containing fluorocarbon in low concentration, after dehumidification in this way, is sent to a concentrator 13 for concentration by the action of the gas adsorption and desorption produced through the honeycomb structure of an active carbon. This small-size device permits a highly concentrated fluorocarbon gas to be obtained with a high rate of concentration.

Description

Detailed Description of the Invention [Industrial Field of Application] The present invention relates to a fluorocarbon-containing gas concentrator that condenses a gas containing a low concentration of fluorocarbons into a gas containing a high concentration of fluorocarbons through the adsorption and desorption action of activated carbon, and particularly relates to a fluorocarbon-containing gas concentrating device for concentrating a gas containing a low concentration of fluorocarbons into a gas containing a high concentration of fluorocarbons through the adsorption and desorption action of activated carbon. The present invention relates to a fluorocarbon-containing gas concentrator used to increase recovery efficiency by supplying high-concentration fluorocarbon-containing gas.

[Prior Art] Recently, air pollution caused by fluorocarbon gas has been attracting attention as a serious problem, and therefore, there are attempts to regulate the emission of fluorocarbon gas. As a technology for dealing with this fluorocarbon gas emission regulation, there is a fluorocarbon gas recovery device that attempts to recover and reuse the fluorocarbon gas that was previously released into the atmosphere.

Since the concentration of CFC gas in the exhaust gas is generally low, it can be cooled as is in a recovery device, concentrated using a conventional activated carbon fluidized bed or activated carbon fixed bed and then cooled and recovered, or absorbed into oil. Refining and recovering is
Either the size of the recovery device has to be increased, or the recovery rate is so low that it cannot be put to practical use. Therefore, as a pretreatment for recovering the fluorocarbon gas, measures have been taken to condense the gas containing a low concentration of fluorocarbons.

This conventional device for concentrating components in gas was
There is one disclosed in No. 167430. In this technique, the sheet-like adsorption member is placed inside the cylinder so that a large number of ventilation holes formed by bending the sheet-like adsorption member into a wave shape are parallel to the axis of rotation of the cylinder, and the adsorption gas is The cylindrical body is rotated so that the cylindrical body and the desorption gas alternately pass in parallel to the axis of rotation, thereby concentrating the components in the adsorption gas into the desorption gas to a high concentration. ing.

[Problems to be Solved by the Invention] However, the conventional concentrating device described above has been used in a general solvent recovery device, and the concentration rate is low for application to fluorocarbon gas, which is difficult to recover. The disadvantages are that the equipment becomes large and the recovery rate of fluorocarbons is low. Therefore, it does not fully satisfy the recent demand for minimizing the amount of fluorocarbons discharged outdoors.

The present invention has been made in view of such problems, and includes:
It is an object of the present invention to provide a fluorocarbon-containing gas concentrating device that is a small-sized device and has an extremely high fluorocarbon-containing gas concentration rate.

[Means for Solving the Problems] - The fluorocarbon-containing gas concentrating device according to the present invention includes a dehumidifying means for dehumidifying a low-concentration fluorocarbon-containing gas using an adsorbent mainly composed of zeolite, and a dehumidifying means for dehumidifying a low-concentration fluorocarbon-containing gas after dehumidification. It is characterized by having a concentrating means for concentrating by adsorption and desorption action by a honeycomb molded body of activated carbon.

[Function] In the present invention, the low concentration fluorocarbon-containing gas is first passed through a dehumidifying means and dehumidified by an adsorbent containing zeolite as a main component. Next, the low-concentration fluorocarbon-containing gas from which water has been removed is supplied to a concentrating means and concentrated by the adsorption and desorption action of the activated carbon honeycomb body. In this way, since the dehumidified low-concentration fluorocarbon-containing gas is passed through the honeycomb molded body, the fluorocarbon adsorption efficiency is high, and therefore the fluorocarbons are concentrated at a high concentration rate.

[Example] Next, an example of the present invention will be described with reference to the accompanying drawings.

FIG. 1 is a block diagram showing a fluorocarbon-containing gas concentrator according to an embodiment of the present invention. For example, in a factory room, the temperature is 32℃, the relative humidity is 80%RH1, and the absolute humidity is 24.5g.
/kg water content and 11000pp
Contains fluorocarbons. This low-concentration fluorocarbon-containing gas is sucked by a blower 10 through a pipe 1 and supplied to the cooling device 10 at a flow rate of, for example, 300 rrf/hour. Gas containing low concentration of chlorofluorocarbons is cooled by this cooling device, for example, at 10°.
After being cooled to C, it is supplied to the dehumidifier 12 via the pipe 2.

In this dehumidification device 12, a rotor 20 is configured by cutting out a honeycomb molded body mainly composed of zeolite so that the gas passage direction is parallel to the rotation center axis, and the rotor 20 is rotatable around the rotation center axis. It is arranged. A dehumidification zone 21 and a regeneration zone 22 are provided in the rotation range of the rotor 20, and while the rotor 20 passes through the moisture absorption zone 21, a gas containing low concentration of fluorocarbon passes therethrough.
While passing through the regeneration zone 22, the regeneration gas is passed through. This regeneration gas is fed to the regeneration zone 22 of the rotor 20 by a blower 23 via a pipe 9. A heater 24 is disposed in the middle of the pipe 9, and the heater 24 heats the regeneration gas to a predetermined regeneration temperature.

Further, the honeycomb molded body constituting the rotor 20 is molded from synthetic zeolite having gas flow holes with a pore diameter of four. Since this pore size is slightly larger than the water molecule diameter, the water adsorption efficiency is high.

The low-concentration fluorocarbon-containing gas that has been dehumidified to an absolute humidity of Ig/kg by the dehumidifier 20 is passed through the pipe 3 to
It is sent to the fluorocarbon concentrator 13. This fluorocarbon concentration device 13 is provided with a rotor 30 formed by extruding activated carbon powder into a honeycomb shape. This honeycomb molded body is cut into a columnar or cylindrical shape so that the gas flow direction is parallel to the central axis, and the rotor 30
is driven to rotate around the central axis at a constant speed. The pore diameter of the honeycomb formed body is preferably 15 to 30 pores in order to increase the efficiency of adsorption of chlorofluorocarbons.

While rotating in a fixed direction, the rotor 30 passes through a regeneration zone, a cooling zone, and an adsorption zone. The low-concentration fluorocarbon-containing gas fed through the pipe 3 passes through the rotor 30 in the adsorption zone 31, where the fluorocarbons in the gas are removed, and the gas is discharged into the pipe 4 as a clean gas. A pipe 5 is branched from the pipe 4, and a portion of the clean gas is supplied to the cooling zone 32 of the rotor 30 via the pipe 5.

This clean gas passes through the rotor 30 in a cooling zone 32 to cool the rotor 30. This cooled gas is sucked into the regeneration zone 33 via the pipe 6 by the blower 15.
is supplied to A heater 14 is disposed in the pipe 6, and the heater 14 heats the regeneration gas supplied to the regeneration zone 33 to a predetermined regeneration temperature.

The regeneration gas that has passed through the regeneration zone 33 desorbs the fluorocarbons adsorbed on the rotor 30, and is discharged from the rotor 3.0 as a highly concentrated fluorocarbon-containing gas containing the fluorocarbons at a high concentration. This highly concentrated fluorocarbon-containing gas is supplied to the absorption tower 17 via the pipe 7 by the blower 16 . In this absorption tower 17, the fluorocarbons in the gas containing high concentration of fluorocarbons are
It is purified and recovered by cooling or oil absorption. The low concentration fluorocarbon-containing gas after the fluorocarbon recovery is returned to the pipe 1 via the pipe 8 and subjected to the concentration process again together with the room air.

In this embodiment, the low concentration fluorocarbon-containing gas is first cooled by the cooling device 11, so that the moisture in the gas is easily adsorbed by the adsorbent. This low-temperature, low-concentration fluorocarbon-containing gas is transferred to a rotor 20 whose main component is zeolite.
dehumidifies.

This zeolite has a sufficiently high amount of moisture adsorption even when the steam partial pressure is low, and removes moisture from gas with high efficiency. When the theorite rotor 20 which has adsorbed moisture in the moisture absorption zone 21 rotates to the regeneration zone 22, the high temperature regeneration gas heated by the heater 24 passes therethrough, and the rotor 20 is heated, releases moisture, and is regenerated. In this way, the gas containing low concentration of fluorocarbon is continuously dehumidified.

The dehumidified low-concentration fluorocarbon-containing gas is supplied to the rotor 30 of the concentrator 13 and passes through the rotor 30 in the adsorption zone 31 . This rotor 30 is made of an activated carbon honeycomb molded body, and fluorocarbons in gas containing low concentration of fluorocarbons are adsorbed by the activated carbon and removed from the gas. In this case, since moisture has been removed from the gas containing low-concentration fluorocarbons in advance, fluorocarbons are adsorbed at a high adsorption concentration. The gas after the Freon removal becomes clean gas and is discharged into the pipe 4, and a part of it is dissipated into the atmosphere. On the other hand, a part of the clean gas is supplied to the cooling zone 32 via the pipe 5, passes through the rotor 30 in the cooling zone 32, and cools the rotor 30. After cooling, the gas is transferred to pipe 6.
After being heated by the heater 14 via the regeneration zone 3
3.

The heated regeneration gas passes through the rotor 30 in the regeneration zone 33, heats the rotor 30, and releases freon.

During its rotation, the rotor 30 first adsorbs fluorocarbons from low-concentration fluorocarbon gas in the adsorption zone 31, and then the rotor 30 is heated by high-temperature regeneration gas in the regeneration zone 33 to desorb the adsorbed fluorocarbons. Then, regeneration gas containing a high concentration of fluorocarbons (gas containing high concentration of fluorocarbons) is discharged. Thereafter, the rotor 30 reaches the cooling zone 32 and is cooled by the cooling gas. Therefore, although the high-temperature portion of the rotor 30 does not directly enter the adsorption zone 31, there is no risk of fluorocarbon being desorbed in the adsorption zone 31, and the piping 4
The fluorocarbon content in the clean gas inside can be kept extremely small. Note that the rotor 30 is in the regeneration zone 3.
The time required to pass through step 3 is preferably about 3 minutes. This is because the fluorocarbon desorption property of activated carbon is that a high concentration of fluorocarbons is released for 3 minutes after the start of regeneration gas supply, and thereafter the concentration of released fluorocarbons decreases. Therefore, the rotor 30 that has passed through the regeneration zone 33 still contains a small amount of fluorocarbons and remains in the cooling zone 33.
2 and reaches the adsorption zone 31.

In this case, if the rotor 30 enters the adsorption zone 31 while still at a high temperature, residual fluorocarbons will be released into the adsorption zone 31, but as described above, the rotor 30 enters the adsorption zone 31.
There is no such inconvenience because the air is cooled by passing through the air. Therefore, the concentration of fluorocarbons in the clean gas is extremely low, and the fluorocarbons can be concentrated at a high concentration rate to obtain concentrated fluorocarbon gas with an extremely high concentration. For example, if the fluorocarbon concentration in the indoor low-concentration fluorocarbon-containing gas is 11,000 ppm, the fluorocarbon concentration in the clean gas will be 20 ppm, making it possible to obtain a recovery rate of 98%.

[Effects of the Invention] As explained above, according to the present invention, extremely highly concentrated concentrated chlorofluorocarbon gas can be obtained at an extremely high concentration rate. Therefore, the present invention makes a significant contribution to the technical field of using fluorocarbon gas, as it becomes possible to increase the recovery efficiency of the fluorocarbon recovery device, and it becomes possible for industries that use fluorocarbons to continue using fluorocarbon gas.

[Brief explanation of the drawing]

FIG. 1 is a block diagram showing a fluorocarbon-containing gas concentrator according to an embodiment of the present invention. 12; Dehumidifier, 20; Rotor, 21; Moisture absorption zone, 2
2; Regeneration zone, 13; Concentrator, 30; Rotor, 31
; Adsorption zone, 32; Cooling zone, 33; Regeneration zone

Claims (4)

[Claims] (1) A dehumidifying means for dehumidifying gas containing low concentration of fluorocarbons using an adsorbent mainly composed of zeolite, and a concentrating means for concentrating the gas containing low concentration of fluorocarbons after dehumidification by adsorption and desorption action by a honeycomb formed body of activated carbon. A fluorocarbon-containing gas concentrator comprising: (2) The dehumidification means has a rotor made of a honeycomb molded body mainly composed of zeolite, and means for providing a moisture absorption zone and a regeneration zone in the rotor, and the moisture absorption zone is provided with a gas containing a low concentration of fluorocarbons. Claim 1, wherein heated regeneration air is supplied to the regeneration zone.
Or the fluorocarbon-containing gas concentrator according to 2. (3) The fluorocarbon-containing gas concentrating device according to claim 1 or 2, wherein the rotor is formed of a honeycomb molded body having pores with a pore diameter of 4 Å. (4) A fluorocarbon according to any one of claims 1 to 3, characterized in that a cooling means for cooling the gas containing low concentration fluorocarbon is provided, and the cooled gas containing fluorocarbon at a low concentration is supplied to the dehumidifying means. Contained gas concentrator.