NL9201226A - METHOD AND APPARATUS FOR REGULATING THE HUMIDITY OF A GAS FLOW AND PURIFYING IT AT THE SAME TIME FROM UNWANTED ACID OR BASIC GASES. - Google Patents

Description

Method and device for regulating the humidity of a gas stream and at the same time purifying it from undesired acidic or basic gases.

The invention relates to a method for regulating the moisture of a gas stream and purifying that gas stream from, for example, acidic or basic gases, the gas stream being guided along one side - the retentate side - of a membrane, through which water vapor can diffuse and on the other side of which - the permeate side - a hygroscopic liquid flows.

It is known to extract water vapor from a gas stream by condensing the moisture therein by cooling below the dew point. To set the humidity of a gas stream to a certain desired value, it is also possible to first heat the gas, saturate it at that temperature with moisture and then cool it to the desired dew point.

Other methods of removing water vapor from a gas are those using hygroscopic media or salts.

A practical and continuously usable method of this type is described in U.S. Patent No. 4,915,838: to remove water vapor from air, the air stream to be dried is passed along the retentate side of a microporous membrane. The membrane used is a so-called hollow fiber membrane.

A hygroscopic liquid flows on the permeate side of the membrane. Water vapor from the gas stream diffuses through the pores of the membrane from the retentate side to the permeate side, where it is taken up and discharged by the hygroscopic liquid.

For the use of methods for regulating the humidity of gases such as air, there is a wide range of applications: in buildings, vehicles, etc. In particular, it is often also important to purify those gases from undesired, for example, harmful gas components such as the acidic gases H2S, SO2, NO2, CO2, etc., but also of basic gases such as NH3 and others. With regard to the removal of harmful gases in air, applications can be made for polluted air in industrial and urban areas, along motorways, but also within buildings and vehicles, such as in museums, for example, to prevent damage to artworks by penetrating gases or tobacco smoke. appearance.

This removal of undesirable components from air cannot take place simultaneously with the previously described methods of controlling the humidity of that air. For example, by cooling the air below the dew point, only the condensable components can be removed therefrom, provided that the dew points of those components also correspond to each other. And when hygroscopic media are used, no other gas is removed except water vapor.

The invention relates to a method by which the regulation of the humidity of an air flow and the removal thereof of undesired gases, which are well absorbed in basic, acidic or neutral aqueous solutions, can be realized simultaneously in one process. To this end, the method according to the invention is characterized in that a membrane is used, through which the relevant gases to be removed can also diffuse and that the hygroscopic liquid is mixed with an aqueous component, such that the water content of the mixture is attuned to the desired equilibrium moisture of the gas stream to be treated and its composition is adapted to the solubility therein of, for example, acidic or basic components to be removed from the gas stream.

The water content of the hygroscopic mixture determines the balance moisture to be set. Since the membrane can pass in both directions - from the retentate side to the permeate side and reverse water vapor, both water vapor can be added to and withdrawn from the gas stream to be treated. And by diffusion of the respective gas component (s) from the retentate side of the membrane to its permeate side, followed by absorption into the aqueous, optionally acidic or basic component of the hygroscopic mixture flowing along the permeate side of the membrane, that gas component becomes (s) removed from the gas stream to be treated simultaneously with the humidity control. For this purpose, the aqueous component must then have such a composition that the solubility of the component to be removed is increased and / or accelerated by a physical or chemical interaction. The composition should be adapted to the nature of the gases to be removed. For example, strong or weak organic or inorganic acids or bases are dissolved therein.

Good results have been achieved with a hygroscopic liquid, which consists of polar glycols, alcohols or glycerols such as triethylene glycol or polyethylene glycol or mixtures thereof. Aqueous electrolyte solutions with hygroscopic properties are also eligible. Generally, such a hygroscopic mixture, the hygroscopic liquid with the components dissolved therein, must be selected to be compatible with the membranes and module materials to be used.

The invention also includes a method of regenerating a hygroscopic mixture used for humidity control during the process until the weather has the desired water content. This method is characterized in that the mixture is first heated or cooled to a certain temperature, then it is contacted via a membrane permeable to water vapor with a gas flow of a certain humidity, until equilibrium is reached and finally the mixture is again is cooled or heated to the operating temperature.

The membrane module to be used contains one or more membranes, which are microporous and hydrophobic. For example, polypropylene suffices in this regard. In any case, they must have a sufficiently large exchanging surface for the purpose; they can be hollow fiber membranes, but flat membranes can also be used. In principle, it does not matter on which side of the membrane the gas or liquid flow is conducted. For example, with a hollow fiber membrane, either the liquid flow can flow through the fiber or the gas flow.

Under circumstances, it is preferable to use said type of membranes with a non-porous top layer. Such membranes are especially advantageous if, due to the nature of the hygroscopic mixture and / or the manner in which it is operated, there is a risk of undesired breakdown of the hygroscopic mixture through the pores of the microporous membrane. A thin top layer consists, for example, of PDMS (silicone rubber) or polytrimethylsilyl propyne, or of thin gel layers on a polymer basis.

Of course, the permeability of this top layer for both water vapor and for the components to be removed from the gas to be treated must be sufficiently high for effective removal to take place. Such a top layer can be hydrophobic or hydrophilic.

When using membranes with a non-porous top layer, preference will be given to the flow of liquid along the top layer, based on considerations regarding effective dust transfer in the choice of the membrane side along which the liquid or gas flows, respectively. Due to possible contamination from the gas / air phase, it is also possible to opt for flow of gas / air along the top layer: dirt will then remain in front of the top layer and will not penetrate into the porous layer of the membrane.

The invention also includes an apparatus for performing the methods described above. For this purpose it contains a membrane module with one or more membranes through which both water vapor and the to be removed, for example acid or basic gases, can diffuse and provided with means to purify the gas flow on one side of the membrane / membranes and to regulate it in terms of moisture past it and to pass an acidic, basic or neutral hygroscopic mixture on the other side.

The membranes are then preferably microporous and hydrophobic, have a sufficiently large exchanging surface and are optionally provided with a non-porous top layer with a sufficiently great permeability for the substances to be diffused therethrough.

The following are descriptions of some exemplary embodiments of methods of the invention, in which the various aspects thereof are exposed.

In general, it holds that the concentration of the acid or base in the absorption liquid, or also in the total mixture, varies with the amount of water extracted from or added to the air stream to be treated.

Example 1

A moist nitrogen stream with an SO2 content of 500 ppm was passed at 20 ° C at a flow rate of 4 liters per minute through the fibers of a hollow fiber membrane module (type ENKA LM2P06, polypropylene fibers, microporous). The membrane module has fibers with an internal diameter of 0.6 nm and a total membrane area of 400 cm2. As the absorbing liquid, the fiber bundle was surrounded on the outside at 0.25 l / min. of a mixture of ethylene glycol and about 20%, 1 Mol, sodium carbonate solution. The ratio of ethylene glycol and sodium carbonate solution in this mixture was 4: 1 by weight. For the incoming nitrogen flow, a relative humidity of about 94% was measured, with a dew point of 18.8 ° C. The SO2 concentration was brought to 500 ppm.

In the outgoing nitrogen stream, a relative humidity of about 61% was measured, with a dew point of 12.1 ° C. A concentration of 0.5 ppm was measured as the SO2 concentration of the outgoing nitrogen stream.

It thus appears that at the same time the humidity of the nitrogen stream has been regulated, or has decreased, and the SO2 content of the nitrogen stream has been reduced by 99%.

Example 2

In the same membrane module as in example 1, a dry nitrogen stream with an SO2 content of 500 ppm was passed through the fibers, at a flow rate of 4 liters per minute. As the absorption liquid, a liquid was pumped around the fibers, containing about 80% ethylene glycol and about 20%, 1 M sodium carbonate solution. The absorbing liquid had a flow rate of about 0.5 liter / min. The operating temperature was about 28 ° C.

In the incoming nitrogen stream, a relative humidity of about 10% was measured, with a dew point of -5.5 ° C. In the outgoing nitrogen stream, an SO2 concentration of 0.5 ppm and a relative humidity of about 41% (dew point 14.0 ° C) were measured.

It thus appears that at the same time the humidity of the nitrogen flow is regulated or increased, and the SO2 content of the nitrogen flow is reduced by 99%.

Example 3

In the same setup as in Examples 1 and 2, it was then investigated what influence the concentration of sodium carbonate has on the degree of removal of SO2 from the nitrogen stream. To this end, the sodium carbonate concentration was lowered from the original 1 Mol to resp. 0.3 M and 0.1 M. It was found that at 0.3 M sodium carbonate the removal rate for SO 2 was still 99% higher. With 0.1 M sodium carbonate, the removal rate of SO2 was found to be reduced to about 90%.

Example 4

In the same experimental set-up as in Examples 1 and 2, it was then investigated which removal of SO 2 from the nitrogen stream can be achieved in mixtures of ethylene glycol and water (without sodium carbonate) and in water alone. The starting concentration of SO2 in the nitrogen flow was lowered to 51.3 ppm. Removal rates of up to 50% were found; with a longer duration of the test, the degree of removal dropped to about 40% or less. From the results of Examples 3 and 4 it can be deduced that without addition of sodium carbonate, or when addition of sodium carbonate in a concentration of less than 0.1 M, the removal rate for SO2 decreases rapidly. Apparently in that case the solution quickly becomes saturated with SO2, so that further absorption is impeded. Therefore, an efficient removal of SO2 while simultaneously controlling the humidity of the nitrogen stream requires a sodium carbonate concentration of 0.1 M or higher.

Example 5

In the same experimental set-up as in Examples 1 and 2, the experiment of Example 1 was repeated, except that the absorption liquid used was a mixture of triethylene glycol (TEG) and a potassium carbonate solution (1 M). The ratio of TEG and potassium carbonate solution in this mixture was about 4: 1 by weight. With this mixture, the same degree of removal for moisture, and at the same time for SO2, was measured as in example 1.

It can be concluded that with a mixture of TEG and potassium carbonate solution, the moisture for the nitrogen flow can be regulated in the same manner as with the mixtures used in Examples 1-4, while at the same time the S 2 content can be reduced by 99%.

Claims (10)

A method for regulating the moisture of a gas stream and purifying that gas stream from, for example, acidic or basic gases, the gas stream being guided along one side - the retentate side - of a membrane, through which water vapor can diffuse and on the on the other side of which - the permeate side - a hygroscopic liquid flows, characterized in that a membrane is used, through which the respective acid or basic gases can diffuse and in which the hygroscopic liquid is mixed with an aqueous component, such that the water content of the mixture is adapted to the desired equilibrium moisture of the gas stream to be treated and its composition is adapted to increase and / or accelerate the solubility therein of the gas stream to be removed, for example, acidic or basic components. Method according to claim 1, characterized in that the hygroscopic liquid consists of polar glycols, alcohols or glycerols, such as triethylene glycol or polyethylene glycol or mixtures thereof. Method according to claim 1 or 2, characterized in that the hygroscopic liquid consists of an aqueous electrolyte solution with hygroscopic properties. Method according to claims 1-3, characterized in that during the execution of the method, the hygroscopic mixture used is regenerated until the desired water content is reached, by first heating or cooling it to a certain temperature, then by means of a for water vapor permeable membrane to contact a gas flow with a certain humidity until equilibrium is reached and finally to cool or heat the mixture again to the working temperature. Method according to any one of claims 1-4, characterized in that a membrane module is used with one or more microporous, hydrophobic membranes, with a sufficiently large exchanging membrane surface. Method according to claim 5, characterized in that a membrane / membranes is / are used with a non-porous top layer, which has a sufficiently high permeability for both water vapor and for the gases to be removed, for example acidic or basic gases. Device for carrying out one of the methods according to claims 1-6, comprising a membrane module with one or more membranes through which both water vapor and the acidic or basic gases to be removed, for example, can diffuse and provided with means on one side of which the membrane / membranes to pass the gas stream to be purified and to be regulated in terms of humidity and to pass on the other side an acid, basic or neutral hygroscopic mixture. Device according to claim 7, characterized in that the membrane / membranes is / are a microporous hollow fiber membrane / membranes made of hydrophobic materials. Device as claimed in claim 7, characterized in that the membrane (s) are / are flat, microporous and hydrophobic with a sufficiently large exchanging membrane surface. Device according to any one of claims 7, 8 and 9, characterized in that the membrane / membranes is / are provided with a non-porous top layer, with such permeability to water vapor and the acidic or basic gases that the method according to claim 6 can be carried out.