NL1006965C2 - Desiccant. - Google Patents

Description

NL 2091-Me / hv Desiccant

The present invention relates to a drying agent provided with a solid, porous carrier with a hygroscopic material, in particular a hygroscopic salt, such as a chloride impregnated thereon.

Such a desiccant, which can for instance be used as energy storage material in heat pumps or as an adsorbent or adsorbent in an air-conditioning installation, is known for instance from Japanese patent applications 55039240 and 03009767.

The present invention now aims to provide a drying agent with improved absorption properties.

For this purpose, the desiccant according to the invention is characterized in that the support has a pore area of about 200 - 350 m2 / g, and / or a pore volume of about 0.8 - 1.5 cm3 / g and / or a pore diameter of approx. 150 - 250 A.

It has surprisingly been found that a drying agent with such a carrier has very good drying properties. The pore surface and the pore volume ensure a large moisture absorption capacity, while a relatively large pore diameter ensures that the moisture absorbed in the pores can be released again relatively easily without blockages in the pores and capillary forces exiting the moisture from prevent the pores. The most favorable properties arise when all the above conditions are met, but also partial combinations lead to favorable properties.

A very advantageous embodiment of the drying agent according to the invention is that in which the hygroscopic material with a homogeneous distribution of at least one monomolecular layer is applied to the carrier.

Due to the substantially complete covering of the carrier with a very thin homogeneous layer of hygroscopic material, the material of the carrier itself is not active in the drying process, so that the material of the carrier can be selected entirely on the basis of favorable carrier properties. pen. Possible materials for the support include silica, alumina, carbon black, paper or the like. Preferably, the support is supplied in the form of particles, in particular spheres with, for example, a size of about 2.5-5 mm. Relatively good mechanical properties can be given to these spheres, so that particles are formed which, for example, can withstand a compressive force of 8 kg per particle in a "crush test". In addition to a porous material, it is also possible to choose a material which is formed in a honeycomb structure or the like, or in which a porous material is given a honeycomb structure.

The invention will be further elucidated hereinbelow on the basis of a number of examples.

EXAMPLE 1

As the carrier for the desiccant, silica was chosen with a pore volume of 1.2 cm3 / g, a pore area of 260 m2 / g and an average pore diameter of about 200 A. 1 kg of silica was treated with a solution of 1200 ml with the following composition: 300 g LiCl, 20 g Ca (OH) 2, 15 g CaCl 2 and 1635 ml water. After the treatment and drying, a desiccant with a bulk density of 0.47 g / cm 3 was formed.

A dynamic absorption test was performed under the following conditions: a. The initial weight of the desiccant was 20 g, b. an air stream was passed through the desiccant with a flow rate of 1.48 m3 / h, an air inlet temperature of Tinlet = 15 ° C and a relative humidity at the inlet of 80%, C. the desiccant was regenerated at 100 ° C at an air flow of 20 m3 / h for 15 minutes.

The test showed that the desiccant absorbed 5.0 g of moisture during each cycle.

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A dew point measurement also yielded favorable results. Air with a temperature at the inlet of T = 17 ° C and a dew point of D.P. = 11 ° C at a regeneration temperature of 80 ° C gave a dew point of the exhaust air in this desiccant from D.P. = -10 ° C. At an air inlet temperature of T = 22 ° C and a dew point of D.P. »12 ° C, at a regeneration temperature of 70 ° C, an exhaust air dew point of D.P. = -3 ° C.

The above desiccant was also tested in a much larger amount.

A dynamic absorption test was performed under the following conditions: a. The initial weight of the desiccant was 4 kg, 15 b. an air stream was passed through the desiccant with a flow rate of 137 m3 / h and an adsorption time of 30 min. C. the desiccant was regenerated at 50 ° C during a regeneration time of 30 min.

20

The exhaust air dew point was 11 ° C.

EXAMPLE 2 100 grams of silica with a pore area of 260 m2 / g, a pore volume of 1.2 cm3 / g and a pore diameter of 200 A were treated with 120 ml of an aqueous solution of Na2SiO 3 9H20 (250 grams in 2000 ml water) and then dried. The dried material was then treated with an aqueous solution of LiCl (330 grams of LiCl in 1635 ml of water) and regenerated. The desiccant was found to have a high absorption capacity, while the active ingredient could not be removed under mild conditions (temperature 20-100 ° C and relative humidity up to 100%). The test results were similar to those of the first example.

1006965 4 EXAMPLE 3

Silica (100 grams) with a pore area of 260 m3 / g, a pore volume of 1.2 cm3 / g and a pore diameter of approximately 200 A was treated with 120 ml of lithium chloride solution (230 grams of LiCl in 1635 ml of water ). The material was then regenerated and impregnated with 120 ml LiCl (100 grams) LiCl in 1635 ml water.

The dynamic absorption test described in example 1 led to an absorption of ca.

5.5 grams of fluid during each cycle. A dew point measurement led at inlet air with T = 17 ° C and D.P. - 11 ° C and a regeneration temperature of 80 ° C to an exhaust air dew point with this desiccant of -12 ° C.

15 EXAMPLE 4

As the carrier for the desiccant, alumina was chosen with a pore volume of 1.0 cm3 / g, a pore surface area of 260 m2 / g and an average pore diameter of approx. 154 A. 1 kg of alumina was treated with a 1000 ml solution of the following composition: 300 g LiCl, 20 g CaCl 2 and 1635 ml water. After the treatment and drying, a desiccant with a bulk density of 0.49 g / cm3 was formed.

A static adsorption test showed that the desiccant had a high adsorption capacity as opposed to untreated alumina which has only a very small adsorption capacity.

A dynamic absorption test was performed under the following conditions: a. The initial weight of the desiccant was 20 g, b. an air stream was passed through the desiccant with a flow rate of 1.48 m3 / h, an air inlet temperature of Tinlet = 15 ° C and a relative humidity at the inlet of 80%, C. the desiccant was regenerated at 100 ° C at a air flow of 20 m3 / h for 15 minutes.

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The test showed that the desiccant absorbed 4.8 g of moisture during each cycle.

A dew point measurement also yielded favorable results. Air with a temperature of T = 17 ° C at the inlet and a dew point of D.P. = 11 ° C at a regeneration temperature of 80 ° C gave a dew point of the exhaust air in this desiccant from D.P. = -9 ° C. At an air inlet temperature of T = 22 ° C and a dew point of D.P. = 12 ° C, at a regeneration temperature of 70 ° C, an exhaust air dew point of D.P. = -2 ° C.

In summary, the following beneficial properties can be attributed to the desiccant; A. high static and dynamic absorption capacity up to 1.3 g moisture per 1 g desiccant.

B. a low regeneration temperature (up to 35-40 ° C) combined with a high absorption capacity, C. an ability to produce an air flow with any relative humidity 20 (20-95%) during a regeneration process, D. a small bulk density, E good resistance to washing out of the active components.

Due to the properties of the desiccant 25 according to the invention, this could be used in the following devices; air-conditioning installations for the utilization of waste energy (supermarkets, offices and the like), air-conditioning installations for passenger cars, caravans and the like, 30 as a drying agent for the atmospheric and pressure treatments of air, as a means for producing air with a certain relative humidity, as a material in a heat pump and as energy storage material.

The invention is not limited to the above-described embodiments, which can be varied in various ways within the scope of the invention.

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Claims (7)

Desiccant provided with a solid, porous support with a hygroscopic material impregnated thereon, in particular a hygroscopic salt, such as a chloride, characterized in that the support has a pore surface area of approximately 200 - 350 m 2 / g , and / or a pore volume of about 0.8 - 1.5 cmVg and / or a pore diameter of about 150 - 250 A. Desiccant according to claim 1, wherein the hygroscopic material with a homogeneous distribution of at least one monomolecular layer is applied to the support. Desiccant according to claim 1 or 2, wherein the carrier is made of silica, alumina, carbon black, paper or the like. Desiccant according to any one of the preceding claims, wherein the carrier has a pore area of about 250 - 350 m2 / g, a pore volume of about 1.2 - 1.5 cm3 / g and a pore diameter of 150 - 250 A. Desiccant according to any one of the preceding claims, wherein the carrier is in the form of particles, in particular spheres with a size of about 2.5-5 mm. 6. Desiccant according to any one of the preceding claims for use as an absorbent in an absorption reactor of an air-conditioning installation. Desiccant according to any one of the preceding claims, wherein the hygroscopic material is lithium chloride, calcium chloride, sodium silicate or the like. 1006965 COOPERATION TREATY (PCT) REPORT ON NEWNESS RESEARCH OF INTERNATIONAL TYPE IDENTIFICATION OF THE NATIONAL APPLICATION Characteristic of the applicant ol of the combined NL 2091-Me Dutch application no. Date of the request for an investigation of an international type Ooor oe Instanoe for International Research (ISA) to a request for an investigation of mtemoneoonaan type granted no. SN 29927 EN I. CLASSIFICATION OF THE SUBJECT (in case of differences of classifications. All specify dassificaoe symbols) According to the Intemaoonaie classification (IPC) Int.Cl.6: B 01 J 20/04 II. FIELDS OF TECHNIQUE EXAMINED _ Minimum Documentation Examined_ Classification System__Classification Symbols__ Int.Cl.6: B 01 J Documentation examined other than the minimum documentation to the extent that such dooms are included in the prayers examined III. I 'CANNOT INVESTIGATE FOR CERTAIN CONCLUSIONS (comments on supplementary sheet) IV. '_ | LACK OF UNIT OF INVENTION (comments on supplementosoad)! Form PC7 / lSA / 20l (aiCS 19Sa