FR3082757A1 - DEHUMIDIFICATION GALETTE - Google Patents

Abstract

A dehumidification pad (3) is described, comprising a silica gel (SiO2) and a water-based adhesive (2), the silica gel (SiO2) being ground to form an absorbent micro-powder (1) with a particle size of between 25 and 500 mesh (approx. 710 µm to approx. 31 µm), then being intimately mixed with the water-based adhesive (2) according to a weight ratio of 80% to 98% by weight: 20% to 2% by weight for a predetermined shaping by molding and, sequentially, a baking process and a cooling process, to form a preformed dehumidifying wafer (3) having a plurality of pores (21). The invention also relates to the corresponding method.

Description

BACKGROUND OF THE INVENTION

1. Field of the invention

The present invention relates to a dehumidifying wafer which has a preformed structure and a plurality of pores, which does not require any packaging envelope and which can be formed in a variety of shapes attractive to consumers. The invention also relates to a method for manufacturing this cake.

2. Description of the prior art

Mold belongs to a kind of fungus that is widely found in nature. Mold grows easily in poorly ventilated and humid environments and has a high reproductive capacity. It is well known that food, clothing and furniture, in a poorly ventilated and humid environment, are subject to moisture and mold, which has harmful effects on human health. As a result, various dehumidification products are produced in response to the need to reduce the humidity in the ambient environment, to maintain the environment in a dry state and to reduce the proliferation of mold.

Generally, dehumidification products can be classified into two types. One is a condensing dehumidifier placed in a certain location and powered by electricity. The large condensing dehumidifier is not easy to transport and is generally used to reduce humidity in a large space. The other concerns certain chemical substances having the property of easily absorbing molecules of water present in the air, for example. calcium chloride. Such a dehumidification product, e.g. a moisture-proof bag in food packaging or a moisture-proof box in a cupboard, is usually placed in a confined space and requires continuous replenishment due to the consumption of chemicals, so it is inconvenient use. In addition, some dehumidification boxes are divided into upper and lower reception areas. The upper layer is used to receive granular calcium chloride, while the lower layer is used to collect the liquid absorbed by the upper layer. The collected liquid also contains a chemical, e.g. calcium chloride. If the dehumidification box is accidentally overturned, the collected liquid, which is difficult to remove, may come into contact with surrounding objects. The fluid collected can also cause inflammation, such as redness, swelling and pain on the human skin if the human body contacts it. In addition, liquid containing calcium chloride is often poured directly into the water drainage system by users, causing serious environmental pollution.

Recently, a reusable dehumidification product has been developed, which is mainly supplied with a box or sachet-shaped packaging shell and then filled with granular material absorbing moisture (with a diameter of about 2 to 3 mm) in the packaging shell so as to absorb the moisture present in the air. After the moisture absorbing material has completely absorbed the moisture, the packaging shell filled with the moisture absorbing material can be placed in an oven or microwave to dry the moisture absorbing material for reduction reaction. As a result, the moisture absorbing material can reabsorb moisture to obtain reusability.

Although the product mentioned above achieves a reproducible dehumidification capacity, there is still a certain distance to travel to be perfect.

For example, the product's packaging shell or sachet should be made of plastic or fabric, which increases the cost and carbon footprint of manufacturing and causes problems with subsequent disposal. In addition, the packaging shell or the packaging bag can be easily damaged by the high temperature of the oven or microwave when it is inappropriately dried, which results in a significant shortening of the duration of product service.

SUMMARY OF THE INVENTION

In view of the problems mentioned above, the objective of the present invention is to provide a dehumidification wafer having a plurality of pores, which comprises:

a silica gel (S1O2) and a water-based adhesive, the silica gel (S1O2) being in the form of an absorbent micro-powder with a particle size between 25 and 500 mesh (approx. 710 gm to approx .31 gm), which is intimately mixed with the water-based adhesive in a ratio of 80% to 98% by weight: 20% to 2% by weight, for, after a predetermined shaping by molding and, sequentially, a cooking process and a cooling process, forming a preformed dehumidification wafer, having a plurality of pores.

The dehumidifying wafer has a hygroscopic effect and does not require the use of packaging sachets or packaging envelopes for packaging, so that the present invention simultaneously increases costs and environmental benefits.

According to one embodiment of the present invention, the water-based adhesive is chosen from the group consisting of: an acrylic resin emulsion, a polyvinyl acetate emulsion, polyvinyl alcohol (PVA), polyvinylpyrrolidone (PVP), a starch suspension, a natural cellulose suspension, a synthetic artificial cellulose suspension, an edible gel, a mineral suspension and a cellulose pulp.

The method according to the invention comprises the steps consisting in:

- grinding a silica gel (S1O2) to form an absorbent micropowder having a particle size between 25 and 500 mesh (approx. 710 gm to approx. 31 gm);

- Intimately mixing the absorbent micro-powder having a plurality of pores with a water-based adhesive (2) in a ratio of 80% to 98% by weight: 20% to 2% by weight, to form a mixture;

- implementing a molding process of the mixture to form a semi-product of preformed dehumidification cake;

- sequentially operating a cooking and cooling process of the semi-product of the dehumidification wafer to form a preformed dehumidification wafer (3), having a plurality of pores.

According to an embodiment of the present invention, the cooking process is carried out at a temperature ranging from 100 ° C to 400 ° C for 1 to 4 hours.

Consequently, the dehumidification wafer according to the present invention, in the form of a block, does not require a wrapping envelope for its use and can also be formed in various forms, which avoids the waste of resources and further promotes the economic efficiency.

BRIEF DESCRIPTION OF THE DRAWINGS

Figure 1 is a block diagram for preparing a dehumidification wafer according to the present invention;

Figure 2 is an enlarged view showing a dehumidification wafer according to the present invention, formed by adhesion and aggregation of an absorbent micropowder and a water-based adhesive;

Figure 3 is a schematic view showing a dehumidification wafer according to the present invention, molded into a star-shaped block;

Figure 4 is a schematic view showing a dehumidification wafer according to the present invention, molded into a block in the shape of a heart.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

An exemplary embodiment of the present invention will be described in detail below, with reference to the accompanying drawings.

A block diagram for preparing a dehumidification cake according to the present invention is described with reference to FIG. 1. The dehumidification cake essentially comprises a silica gel (S1O2) and a water-based adhesive. The silica gel (S1O2) is ground to form an absorbent micro-powder having a particle size between 25 and 500 mesh (approx. 710 gm to approx. 31 gm) and then is intimately mixed with the water-based adhesive according to a weight ratio of 80% to 98% by weight: 20% to 2% by weight with a view to a predetermined shaping by molding and, sequentially, a cooking process and a cooling process, in order forming a preformed dehumidification wafer having a plurality of pores. A process for preparing the dehumidification cake comprises the steps consisting in:

(a) grinding a silica gel (S1O2) to form an absorbent micropowder having a particle size of between 25 and 500 mesh (approx. 710 μτη to approx. 31 μτη);

(b) intimately mixing the absorbent micropowder having a plurality of pores with a water-based adhesive in a weight ratio of 80% to 98% by weight: 20% to 2% by weight to form a mixture; preferably, the water-based adhesive is chosen from the group consisting of: an acrylic resin emulsion, a polyvinyl acetate emulsion, polyvinyl alcohol (PVA), polyvinylpyrrolidone (PVP), a suspension of starch, a suspension of natural cellulose, a suspension of synthetic artificial cellulose, an edible gel, a mineral suspension and a pulp of cellulose;

(c) implementing a process of molding the mixture to form a semi-product of a preformed dehumidification wafer;

(d) operating a process of cooking the semi-finished dehumidification cake at a temperature of 100 ° C to 400 ° C for 1 to 4 hours; and (e) operating a process of cooling the semi-finished wafer.

By mixing the porous absorbent micro-powder and the water-based adhesive in specific weight ratios, only a small amount of the water-based adhesive is used to adhere and aggregate the micro-powder absorbent porous. Although the water-based adhesive can be filled into the pores of the absorbent micro-powder when mixed with each other, the moisture in the water-based adhesive after baking is evaporated so that the plurality of pores of the absorbent micropowder can be regenerated.

In addition, after the adhesion and aggregation of the porous absorbent micro-powder and the water-based adhesive, the inter-particle space of each porous absorbent micro-powder is filled with the adhesive based of water, but a large number of pores are formed by the evaporation of moisture during the cooking process. Thanks to the plurality of pores, the total area of the absorbent body of the preformed dehumidifying wafer can be increased to provide a good moisture absorbing effect.

Figure 2 is an enlarged view showing an adhesion and aggregation of a plurality of absorbent powders and a water-based adhesive to form a dehumidification wafer according to the present invention. The dehumidification wafer comprises an absorbent body consisting of an absorbent micro-powder (1) and a water-based adhesive (2). The absorbent micropowder (1) has a plurality of pores (11) and a plurality of pores (21) is formed inside the water-based adhesive (2) due to evaporation of the l water-based adhesive (2) during the baking process of the dehumidification wafer semi-product. As shown in Figure 2, the water-based adhesive (2) adheres and aggregates the absorbent micro-powders (1) and retains the structure with the plurality of pores (11). The water-based adhesive (2) also has a large number of pores (21) due to the evaporation of moisture, so that the total area of the absorbent body of the preformed dehumidification pad can be increased .

Figure 3 and Figure 4 are schematic views showing a dehumidification wafer molded into a star-shaped block and a dehumidification wafer molded into a heart-shaped block. The dehumidification plate (3) with specific shapes can be directly placed or hung in a cabinet for dehumidification. After the dehumidifying wafer (3) has completely absorbed the moisture, it can be dried so that the dehumidifying wafers (3) can be used repeatedly.

Claims (4)

1. Dehumidification wafer (3), characterized in that it comprises: a silica gel (S1O2) and a water-based adhesive (2), the silica gel (S1O2) being in the form of an absorbent micropowder (1) with a particle size between 25 and 500 mesh ( about 710 pm to about 31 pm), which is intimately mixed with the water-based adhesive (2) in a ratio of 80% to 98% by weight: 20% to 2% by weight, for, after a predetermined shaping by molding and, sequentially, a cooking process and a cooling process, forming a preformed dehumidification wafer (3), having a plurality of pores (21). 2. Dehumidification wafer (3) according to claim 1, characterized in that the water-based adhesive (2) is chosen from the group consisting of: an acrylic resin emulsion, a polyvinyl acetate emulsion, polyvinyl alcohol (PVA), polyvinylpyrrolidone (PVP), a starch suspension, a natural cellulose suspension, a synthetic artificial cellulose suspension, an edible gel, a mineral suspension and a cellulose paste. 3. Method for manufacturing the dehumidification wafer, characterized in that it comprises the steps consisting in: - grinding a silica gel (S1O2) to form an absorbent micro-powder having a particle size between 25 and 500 mesh (approx. 710 pm to approx. 31 pm); - Intimately mixing the absorbent micro-powder having a plurality of pores with a water-based adhesive (2) in a ratio of 80% to 98% by weight: 20% to 2% by weight, to form a mixture; - implementing a molding process of the mixture to form a semi-product of preformed dehumidification cake; - sequentially operating a cooking and cooling process of the semi-product of the dehumidification wafer to form a preformed dehumidification wafer (3), having a plurality of pores (21). 4. Method according to claim 3, characterized in that the cooking process is carried out at a temperature ranging from 100 ° C to 400 ° C for 1 to 4 hours.