JPS6168119A - Dehumidifier and dehumidifying method using said dehumidifier - Google Patents

Abstract

PURPOSE:To obtain a dehumidifier capable of being regenerated with low regeneration energy by depositing a hygroscopic inorg. electrolyte capable of contg. water of crystallization on a nonconducting carrier. CONSTITUTION:A nonconducting carrier of silica gel, etc. is immersed in an aq. soln. of the hygroscopic material of a hygroscopic inorg. electrolyte such as MgCl2 and CaCl2 capable of contg. water of crystallization, and then dried. The dehumidifier thus prepared is brought into contact with the atmosphere to adsorb the water in the atmosphere. The dehumidifier saturated with water is arranged in the space between electrode 4, and regenerating air 1 is supplied while impressing an AC high voltage between both electrodes 4. The water of crystallization contained in a dehumidifying material 2 is converted into free water by electric conduction, and the free water is entrained by the regenerating air and discharged to the outside of the system. Since an increase in the temp. of the dehumidifier during regeneration is small, dehumidification can be immediately carried out without cooling the dehumidifier after regeneration.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a moisture absorbent capable of adsorbing moisture in the atmosphere and a dehumidification method for adsorbing and desorbing moisture using this moisture absorbent.

Prior art and its problems Methods for removing moisture from the atmosphere are mainly divided into cooling methods and adsorption methods. The cooling method performs dehumidification by cooling the air to be dehumidified below its dew point. In the adsorption method, a moisture absorbent such as silica gel is brought into contact with the atmosphere to cause the moisture absorbent to adsorb moisture and dehumidify. When dehumidifying without lowering the temperature or when dehumidifying at a low dew point, an adsorption method has conventionally been adopted.

In the adsorption method, the moisture absorbent that has absorbed moisture is regenerated and used repeatedly. Methods for regenerating the moisture absorbent include a hot air regeneration method, a high frequency induction heating regeneration method, and an electrolysis method. In the hot air regeneration method, the moisture absorbent is heated by high-temperature hot air to evaporate the adsorbed moisture. Although this regeneration method has been used in the past, it is not suitable for small-scale dehumidification because it requires a boiler or the like to generate hot air and the regeneration equipment becomes large. In addition, not only the moisture removed by the hot air but also the moisture absorbent itself is heated, and the heat loss is large, so the regeneration energy (the energy required to adsorb to the moisture absorbent and remove 9 water) is approximately 1. It is high at .5 kcal/1. There are other problems such as the need to cool down the moisture absorbent after hot air regeneration.

Japanese Unexamined Patent Publication No. 57-32713 discloses regeneration of a moisture absorbent by high frequency induction heating. This regeneration method is a method in which water in the moisture absorbent is directly heated and evaporated by electromagnetic induction from a high-frequency induction heating coil. This method can be said to be superior to the hot air regeneration method in that it does not heat the outside air or the moisture absorbent itself. However, since this regeneration method basically belongs to heating regeneration, it requires at least regeneration energy (0.6kcllt/11) corresponding to the latent heat of vaporization of water, and therefore the regeneration energy cannot be said to be low. Another problem is that the playback device becomes complicated.

JP-A-49-70447 discloses a method for regenerating a moisture absorbent by electrolysis. In this method, a direct current voltage is applied to the moisture absorbent to electrolyze the moisture in the moisture absorbent into hydrogen and oxygen to remove moisture.The regeneration device for this method has a simple structure, and Better. but,
The energy required for electrolysis of water is necessarily determined by 7 Alladay's law, and the renewable energy is at least 4
High kcal/g.

OBJECTS OF THE INVENTION The present invention eliminates the drawbacks of the prior art, and aims to provide a moisture absorbent that requires low regeneration energy and a dehumidification method using this moisture absorbent.

Summary of the Invention The present inventors have investigated moisture absorbents and regeneration methods that can be regenerated with far lower regeneration energy than conventional methods, and as a result, the present inventors have developed a moisture absorbent in which a specific moisture absorbing material is supported on a non-conductive carrier under specific energizing conditions. The present inventors have discovered that by applying electricity, it is possible to regenerate the material using a much lower amount of regeneration energy than in the past and using a simple method, thereby completing the present invention.

That is, the present invention provides a hygroscopic agent comprising a hygroscopic inorganic electrolyte hygroscopic material capable of containing crystal water on a non-conductive carrier; and a dehumidifying method using this hygroscopic agent. This is a dehumidification method characterized by regenerating the moisture absorbent by applying a low frequency AC high voltage to the moisture absorbent.

Preferred Embodiments of the Invention The hygroscopic agent according to the present invention is one in which a hygroscopic material is supported on a non-conductive carrier. The carrier must not be electrically conductive. As will be described later, when the moisture absorbent is regenerated in the dehumidification method of the present invention, electricity is applied to the moisture absorbing material to cause phase transition of crystal water and desorption of moisture. This is because if the carrier is conductive, a current will also flow through the carrier during regeneration, resulting in an energy loss corresponding to this amount. Preferably, the carrier is porous. By making the carrier porous, the surface area per unit volume of the carrier can be increased,
The contact efficiency between the moisture-absorbing material coated on the surface of the carrier and the outside air can be increased. The carrier may be an inorganic or organic material. Preferred inorganic carriers are, for example, silica, alumina, glass fiber iron oxide, magnesia, zeolite, ceramics, and the like. Preferred organic carriers are polyethylene,
Plastics and vegetable fibers such as polypropylene, polystyrene, polyester, polyvinyl chloride, and polyurethane. The most preferred carrier is silica. Traditionally, silica (as silica gel) has been used as a moisture-absorbing material, but in the present invention it is used as a carrier. The moisture absorbing function of silica gel is not utilized in the present invention. Silica is used as a carrier because it is non-conductive, porous, and easily available. Activated carbon cannot be used as a carrier in the present invention because it is electrically conductive (electrical resistance 2 to 3 Ω·a·cl).

However, activated carbon may also be used as a carrier in a mixture with other materials. In this case, the carrier as a whole must be electrically non-conductive.

Next, the hygroscopic material used in the present invention is a hygroscopic inorganic electrolyte that can contain water of crystallization. As used herein, the term "capable of having crystallization water" means that the hygroscopic material can change from a state without crystallization water to a state in which crystallization water is added by contacting with humid air, or that the hygroscopic material can change from a state without crystallization water to a state in which crystallization water is added, or the number of crystallization water. This means that the amount increases. Examples of moisture absorbing materials include magnesium chloride, calcium chloride, lithium chloride,
These include magnesium sulfate and aluminum sulfate. These moisture-absorbing materials can be used alone or as a mixture. A preferred moisture-absorbing material is magnesium chloride, which transitions from a state with no water of crystallization to a form with six waters of crystallization.

A dipping method is suitable as a method for supporting the hygroscopic material on the carrier. The carrier is immersed in a solution in which a hygroscopic material is dissolved or suspended in a solvent. After this solution has sufficiently penetrated into the carrier, the carrier is taken out and dried to remove the solvent, and the moisture-absorbing material is supported on the carrier surface. In addition to water, an organic solvent may be used as the solvent. In order to strengthen the adhesive force between the carrier and the hygroscopic material, an adhesive such as polyvinyl alcohol may be dissolved in advance in the solution. By changing the concentration of the hygroscopic material in the solution, the immersion time, the immersion temperature, etc., the supported amount of the hygroscopic material can be appropriately set.

When the hygroscopic agent prepared as described above is brought into contact with the atmosphere, the hygroscopic material in the hygroscopic agent adsorbs moisture in the atmosphere. The hygroscopic agent saturated with water is regenerated by energizing it. In the regeneration of the present invention, a moisture absorbent is placed in the gap between the electrodes, and a high AC voltage is applied to both electrodes. In this specification, "high voltage"
means a voltage higher than that applied in electrolysis. In regeneration by electrolysis, the theoretical decomposition voltage of water is 1.7■ and the overvoltage of both oxygen and hydrogen? Taking into account a voltage of about 2 to 2.5 μ is applied. In the regeneration of the present invention, a voltage higher than this is applied to the electrodes.

A preferred high voltage is 10 to 600V, more preferably 30 to 220V.

Also, the high voltage is alternating current. Although direct current is applied in the electrolysis method, the efficiency decreases when direct current is used in the present invention. , this alternating current is of low frequency, preferably at least 60 Hz or less, preferably 20 Hz or less. Regeneration efficiency is improved by applying a pulsed AC high voltage to the electrodes. The current application time is a factor depending on the type of moisture absorbent, the applied voltage, etc., and is approximately several minutes to several tens of minutes. The current value is not an important factor in the reproduction of the present invention. In the conventional electrolysis method, since adsorbed moisture is decomposed and removed in proportion to the amount of electricity, the current value is necessarily determined. However, in the present invention, the adsorbed water is not electrolyzed but the adsorbed water that has become crystal water is converted into a free state, so a low current may be used. When a large amount of current is passed, water is heated and evaporated by that amount, and in the present invention, this results in an energy loss and a decrease in regeneration efficiency. The electrode materials used can be those used in conventional electrolysis methods, such as graphite and stainless steel.

The accompanying drawings are schematic configuration diagrams showing a method for regenerating a moisture absorbent according to the present invention. The moisture absorbent is particularly enlarged. When the hygroscopic agent is brought into contact with humid air, moisture in the air is adsorbed by the hygroscopic material 2 of the hygroscopic agent. For example, when anhydrous magnesium chloride is used as the moisture absorbing material 2, MgCl2・
It will be 6H20. After the filled moisture absorbent is saturated with moisture,
The moisture absorbent is regenerated by applying electricity. While applying AC voltage to the electrodes 4 arranged at predetermined intervals from the regeneration power source 6,
Regeneration air 1 is supplied to the moisture absorbent. Crystallized water contained in the hygroscopic material is turned into free water by the energization process, and is transported into the regeneration air and discharged out of the system as moist air 5. Although the principle of regeneration in the present invention is not necessarily clear, since only the moisture-absorbing material supported on the surface of the carrier 3 is conductive, current flows only in this portion, and crystallization is produced with little energy by the action of specific current conditions. This is thought to have been transferred to free water.

Example 1-12 Mgc12+CaC112+ was used as a hygroscopic material and 7-force gel was used as a LiCl2° carrier. The carriers were immersed in an aqueous solution of each hygroscopic material for 1 to 24 hours and then dried to obtain a hygroscopic agent. This hygroscopic agent contained about 0.27 to 0.409/l of hygroscopic material supported on the carrier.

A dehumidifying operation was performed by passing outside air into a test container loaded with about 10,011 liters of moisture absorbent. Thereafter, the used moisture absorbent was treated with electricity and regenerated. The results are summarized in the table below. The same procedure was carried out when conductive activated carbon was used as the carrier/liver gel, and the results are shown in the same table as a comparative example.

Effects The present invention exhibits great effects during playback. In other words, the renewable energy in the hot air regeneration method is approximately 1.5 k
cllt/g, or approximately J kCd/i of renewable energy in electrolysis, in the present invention 0,1
to 0.5 kc4t/g, making it possible to regenerate the moisture absorbent with much less energy than conventional methods.

Further, in the present invention, since the temperature rise of the desiccant during regeneration is as low as about 5° C., the dehumidification operation can be performed immediately after the regeneration without cooling the desiccant. Furthermore, in conventional electrolysis methods, water electrolysis reaction occurs on the electrode surface, making it difficult to uniformly regenerate the moisture absorbent. On the other hand, in the present invention, crystal water and free water are converted into crystal water and free water by a specific energization operation rather than electrolysis.
Can be regenerated uniformly over the entire moisture absorbent. In terms of other equipment structures as well, it is possible to regenerate using equipment that is simpler than conventional equipment.

[Brief explanation of the drawing]

The accompanying drawings are schematic configuration diagrams showing a method for regenerating a moisture absorbent according to the present invention. 1...Regeneration air 2...Moisture absorbing material 3...
Carrier 4... Electrode 5... Humid air
6... Power source for regeneration 7... Patent applicant for control resistance meter Shinryo Corporation Procedural amendment (method) February 1985 1Cf Commissioner of the Japan Patent Office Gakudono Shiga 1, Case description 3 , Relationship to the case of the person making the amendment Applicant address 4, agent 5, date of amendment order January 9, 1985 (shipment date) 6, subject of amendment

Claims (1)

[Scope of Claims] 1) A hygroscopic agent comprising a hygroscopic material such as a hygroscopic inorganic electrolyte capable of containing crystal water supported on a non-conductive carrier. 2) The moisture absorbent according to claim 1, wherein the carrier is porous. 3) The moisture absorbent according to claim 1 or 2, wherein the carrier is an inorganic oxide, plastic, vegetable fiber, or a combination thereof. 4) The moisture absorbent according to claim 3, wherein the inorganic oxide is silica, alumina, glass fiber, iron oxide, magnesia, zeolite, ceramics, or a mixture thereof. 5) The moisture absorbent according to claim 3, wherein the plastic is polyethylene, polypropylene, polystyrene, polyester, polyvinyl chloride, polyurethane, or a mixture thereof. 6) The moisture absorbing agent according to any one of claims 1 to 5, wherein the moisture absorbing material is magnesium chloride, calcium chloride, lithium chloride, magnesium sulfate, calcium sulfate, aluminum sulfate, or a mixture thereof. . 7) A dehumidification method comprising adsorbing moisture in the atmosphere onto a hygroscopic agent and then regenerating this hygroscopic agent, the method comprising: a) moisture absorption of a hygroscopic inorganic electrolyte capable of having water of crystallization on a non-conductive carrier; From each of the above steps, air is passed through the moisture absorbent carrying the material and the moisture is adsorbed by the moisture absorbent, and b) a low frequency AC high voltage is applied to the moisture absorbent that has absorbed the moisture to remove the moisture in the moisture absorbent. A dehumidification method. 8) The dehumidification method according to claim 7, wherein the low frequency is 60 Hz or less. 9) The dehumidification method according to claim 7, wherein the low frequency is 20 Hz or less. 10) The dehumidification method according to any one of claims 7 to 9, wherein the high voltage is 10V to 600V. 11) The dehumidification method according to claim 10, wherein the high voltage is 30V to 220V.