JP2001132116A - Humidity conditioning panel - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a humidity conditioning panel having an excellent humidity conditioning function to enable a neutral environment to be maintained in a storehouse at all times, and also having heat resistance and incombustibility and being manufacturable through a simple process. SOLUTION: The humidity conditioning panel comprises a humidity conditioning portion formed into a plate shape by kneading main constituents together which include diatomaceous shale, gypsum and water, and a moisture- impermeable member covering at least one side of the humidity conditioning portion. The hydrogen ion concentration index of the humidity conditioning portion is in the range of from 5.5 to 8.0 and the bending strength of the humidity conditioning portion is 1.5 N/mm2 or more.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a storage member (hereinafter referred to as "storage"), and more particularly to a panel member excellent in humidity control used as a wall material of a storage for storing cultural properties. is there.

[0002]

2. Description of the Related Art A storehouse is a structure constructed for the purpose of preserving stored items for a long period of time while preventing deterioration of the stored items. As for the deterioration of the stored items, there are primary deterioration due to the effects of humidity, temperature, light, air, harmful substances, etc., or secondary deterioration due to the occurrence of worms, mold, etc. Effective protection of stored items is required from the causes of deterioration.

In order to prevent the deterioration, the storage wall of the storage is generally of a double wall structure. That is, the storage wall of the storage is composed of a primary wall as an outer wall and a secondary wall as an inner wall provided inside the primary wall. Usually, the primary wall is made of concrete. On the other hand, the secondary wall absorbs and desorbs moisture inside the storage, and has a high degree of humidity control required to keep the humidity constant at all times. It is necessary to satisfy the high airtightness required to eliminate the effects of harmful substances. Also, the secondary wall is
In consideration of workability, it is becoming common to form the panel by joining a plurality of panel members. Therefore, hereinafter, a panel member having the above-described property used as a wall material of the secondary wall of the storage is defined as a humidity control panel, and the description will be given.

Conventionally, the following types of humidity control panels exist. (1) Humidity control panel in which a wood-based, fiber-based, calcium silicate-based humidity control material is interposed inside an outer frame formed of a metal material such as a steel plate, and a front plate is formed of a material other than metal. (See JP-A-60-219343). (2) A humidity control panel in which an aluminum foil of a moisture-impermeable material is adhered to a wood-based (for example, cedar wood) humidity control material. (3) A humidity control panel in which an aluminum foil of a moisture-impermeable material is adhered to a calcium silicate plate.

[0005]

However, since the conventional humidity control panel uses a wood type, fiber type or calcium silicate type humidity control material, the humidity control function of the humidity control material used is weak. In the case of a humidity control panel using only a wood-based humidity control material (corresponding to the above (2)), there is a problem in that it lacks heat resistance and incombustibility. In addition, if new cypress wood or cedar wood is used as a wood-based humidity control material, acidic substances are released from the humidity control material, and the storage compartment becomes an acidic environment, causing deterioration of stored products. And other disadvantages.

SUMMARY OF THE INVENTION The present invention has been made in view of such a problem, and has a humidity control function superior to that of the conventional humidity control panel. Another object of the present invention is to provide a humidity control panel having both airtightness, heat resistance, and nonflammability and a simple manufacturing method.

[0007]

In short, the humidity control panel according to the first aspect of the present invention includes a humidity control section formed by kneading a main constituent material composed of diatom shale, gypsum and water into a plate shape, and the humidity control section. And a moisture-impermeable member covering at least one surface of the humidity control panel, wherein the hydrogen ion concentration index (pH) of the humidity control section is in the range of 5.5 to 8.0. It is characterized in that the bending strength of the wet part is 1.5 N / mm ² or more. Here, the moisture-impermeable member is formed of a material having moisture impermeability, such as iron and aluminum.
It means all members such as plate material and frame material. In addition, even when the entire surface of the humidity control unit is covered with the moisture-impermeable member, it is sufficient that the humidity control unit is configured to communicate with the outside.

That is, according to the present invention, diatom shale, gypsum, and water are used as main constituent materials and kneaded at an appropriate mixing ratio to form a plate, which is necessary to prevent deterioration of stored items. It is possible to provide a humidity control panel having a predetermined strength while forming the humidity control portion so as to belong to a certain neutral region. Note that the neutral region in the present invention is a range in which deterioration of the stored product can be appropriately prevented.
H shall mean the range of 5.5 to 8.0.

Further, according to the present invention, since at least one surface of the humidity control section is covered with a moisture-impermeable member, a humidity control panel having a high degree of airtightness can be obtained.

The present invention described in claim 2 is the same as the claim 1.
Wherein the diatom shale is a Wakkanai diatom shale.

[0011] That is, according to the present invention, by using the Wakkanai diatom shale having particularly excellent moisture absorption / desorption properties as the diatom shale, it is possible to provide a humidity control panel with higher performance.

A humidity control panel according to a third aspect of the present invention includes a humidity control section formed by kneading a main constituent material composed of diatom shale, gypsum and water of the Wakkanai layer, and at least one surface of the humidity control section. A moisture control panel comprising a moisture-impermeable member to be covered, wherein the mixing ratio of the Wakkanai diatom shale and the gypsum is from 34% by mass to 83% by mass of the Wakkanai diatom shale based on the total mass thereof.
%, And the mixing ratio of the gypsum and the water is 30 parts by mass to 160 parts by mass with respect to 100 parts by mass of the gypsum.

That is, according to the present invention, the Wakkanai diatom shale, gypsum, and water are used as main constituent materials, and are kneaded at the above mixing ratio to form a plate, which is necessary for preventing deterioration of stored items. It is possible to provide a humidity control panel having a predetermined strength while forming the humidity control portion so as to belong to the neutral region.

Further, the present invention described in claim 4 is based on claim 1.
According to a third aspect of the present invention, in the humidity control panel of the humidity control panel, an uneven portion is formed on a surface portion not covered with the moisture-impermeable member.

That is, according to the present invention, in the humidity control section, the uneven portion is formed on the surface portion not covered with the moisture-impermeable member, so that the humidity control panel having the same shape without the uneven portion can be provided. Increase the surface area of the humidity control part in comparison,
It is possible to provide a humidity control panel in which the speed of absorbing and releasing moisture in the humidity control section (hereinafter, referred to as “moisture absorbing and releasing speed”) is increased.

Further, the present invention described in claim 5 is based on claim 1.
5. The humidity control section of the humidity control panel according to claim 4, wherein a surface portion not covered with the moisture-impermeable member is covered with a neutral moisture-permeable material. 6. It is.

That is, according to the present invention, since the surface of the humidity control panel of the humidity control panel that is not covered with the moisture-impermeable member is covered with the neutral moisture-permeable material. In addition, it is possible to provide a humidity control panel that protects the surface of the humidity control section and facilitates application of a moisture-permeable paint or the like. Note that it is preferable to use a moisture-permeable nonwoven fabric or a sealer material as the moisture-permeable material.

[0018]

Embodiments of the present invention will be described below in detail with reference to the drawings.

(1) Material of Humidity Control Section First, before describing the structure of the humidity control panel of the present invention, the material of the humidity control section will be described.

Diatom shale diatom shale is an inorganic porous material having fine pores, and has the property of adsorbing moisture (moisture) and other harmful substances to the pores. . Although there is a slight difference depending on the place of origin, the substances that make up diatom shale are mainly silicon dioxide (SiO ₂ ) and aluminum oxide (Al ₂ O ₃ ), and the composition of both substances is about 90%. is occupying.

Among the diatom shale, the Wakkanai diatom shale is:
Unlike ordinary diatom shale, it has a unique mineral species, and therefore has a high humidity control function (adsorption function, moisture release function), and is a substance very suitable for the present invention. In addition, it is described in Japanese Patent No. 2652593 that the humidity control function of the Wakkanai diatom shale is extremely superior to that of general diatom shale.

The humidity control function of diatom shale increases as the mixing amount increases. Further, as described later, when the mixing ratio of the diatom shale in the constituent material increases, the pH of the humidity control section decreases (becomes acidic), and the bending strength of the humidity control section decreases. In order to form a humidity control section for use as a secondary wall of the storage, the pH of the humidity control section is 5.5 to 8.0, and the bending strength of the humidity control section is 1.5 N /. mm ² or more, and its mixing amount is limited.

Here, the pH of the humidity control section is set to a neutral range.
The reason why the value must be kept at 5 to 8.0 will be described. When the pH of the storage room in the storage is 8.0 or more, that is, when the storage room is biased toward alkaline, the following adverse effects occur. In an alkaline environment, linseed oil used for oil painting is altered and becomes more compatible with water. Also,
Corrosion of bronze used for sculptures, etc. is accelerated and rust is generated. Furthermore, the luster and smoothness of the surface of lacquer art is lost,
It becomes easy to adapt to water. As mentioned above, deteriorated oil painting,
The surface of the sculpture and lacquer art is further accelerated by the synergistic action of light, heat, and the like, and the deterioration is accelerated.

When the pH of the storage room is 5.5 or less,
In other words, if it is unbalanced to acidity, for example, when a new cypress or cedar is used as an interior material, an acidic substance is released from the interior material, so that the surface of a metal such as iron or copper used for sculpture or the like is stained. Rust including such as occurs, and if left as it is for a long time, the metal itself becomes tattered and eventually loses its shape. Similarly, paper used for paintings and the like is in a boxing state in the initial stage, but becomes more and more ragged when it is further deteriorated. Therefore, in order to prevent deterioration of the stored items stored in the storage room, the storage room must be constantly maintained in an environment of pH 5.5 to 8.0. For that purpose, it is necessary to prevent the release of an acidic substance or an alkaline substance into the storage room by using a humidity control panel prepared using a humidity control section having a pH of 5.5 to 8.0. Become. The pH of cedar wood, which has been conventionally recommended as a humidity control material, is in a relatively narrow range of 5.40 to 6.10, and it has been difficult to keep the storage room neutral enough. According to this, the pH range can be appropriately maintained.

Further, the bending strength of the humidity control section is 1.5 N / mm
^The reason why it is necessary to have ^two or more will be described. When a humidity control panel is used as a wall material, the entire humidity control panel needs to have a bending strength similar to that of a conventional gypsum board. As is well known, the gypsum board is a material in which both sides of the gypsum board are reinforced with paper, the bending strength of the gypsum board not reinforced with paper is 1.5 N / mm ² , and the bending strength of the entire gypsum board is that of the gypsum board. The value is about three to four times. Since the humidity control panel of the present invention covers at least one surface of the humidity control section with an impermeable member such as an iron plate or aluminum and uses it reinforced, the bending strength of the humidity control section is not reinforced with paper. It is sufficient if the gypsum board has a bending strength of 1.5 N / mm ² or more, and the value of the bending strength is used as a reference.

◎ Gypsum Gypsum is added to make the humidity control part exhibit a predetermined strength.
Material. Gypsum reacts with water to prevent hydration
And harden to develop strength.
If the mixing amount is less than necessary, the bending strength of the humidity control
Decreases sharply. Also, the mixing of gypsum in the constituent materials
The higher the percentage, the closer to neutrality. As a secondary wall of storage
When used as a constituent material for use, the humidity control section
PH 5.5 to 8.0, and the humidity control part
Bending strength is 1.5N / mm ^TwoNeed to be more than
Therefore, the mixing amount is limited.

Water Water is a material required to cause a reaction in the gypsum and form a humidity control part. Oil, acid, salts, organic substances, etc.
There is no particular limitation on the type or the like as long as it does not contain a substance that affects the quality of the humidity control unit. As the amount of water becomes smaller than the predetermined amount, the viscosity of the humidity control part before hardening becomes extremely high, and it becomes difficult to mold the humidity control part. Conversely, as the amount exceeds the predetermined amount, the strength of the humidity control unit after curing decreases. Therefore, in both cases, the humidity control section cannot satisfy the required strength, and the mixing amount is limited.

◎ Mixing ratio As will be described in detail in the examples described later, in order to form the humidity control part, the Wakkanai diatom shale is used as a main constituent material by pulverized material, gypsum and water of the Wakkanai diatom shale. The mixing ratio of the gypsum is in the range of 34 mass% to 83 mass% of the Wakkanai diatom shale with respect to the total mass thereof, and the water is 30 mass parts to 16 mass parts with respect to 100 mass parts of the gypsum.
It is necessary to mix and knead so as to be 0 parts by mass. By adjusting the mixing ratio, the pH of the humidity control section is adjusted.
Is in the range of 5.5 to 8.0, and the bending strength of the humidity control section can be 1.5 N / mm ² or more. Depending on the conditions of the storage, it is possible to determine appropriately within the above range.

Other mixed materials In addition to diatom shale, gypsum, and water, other admixtures can be added as needed as long as the role of the humidity control material is not impaired. For example, by mixing various fibers and various polymers with the constituent material, the bending strength of the humidity control section can be increased. Examples of the fiber include vinylon fiber, glass fiber, polypropylene fiber, carbon fiber, and polyethylene fiber. Examples of the polymer include an aqueous polymer dispersion, a re-emulsifying powder resin, a water-soluble polymer, and a liquid polymer. As an example, if 1 part by volume of vinylon fiber is added to 100 parts by volume of the main constituent material, the bending strength of the humidity control section will increase by about 20%.

Further, by adding a water reducing agent, a superplasticizer, a retarder, an accelerator and the like to the above-mentioned main constituent materials, the fluidity and curing time of the main constituent materials can be adjusted.
It is possible to increase the work efficiency when preparing the humidity control panel.
For example, with respect to 100 parts by mass of gypsum, a gypsum retardant is added in an amount of 0.1 g / m 2.
By adding from 01 parts by mass to 0.1 parts by mass, the curing time of the humidity control unit can be freely adjusted. Furthermore, by mixing a heat insulating material with the main constituent material,
It is also possible to create a humidity control panel having an insulating effect.

(2) Configuration of Humidity Control Panel Next, the configuration of the humidity control panel of the present invention will be described. Although various embodiments exist for the humidity control panel, an example of the embodiment will be described below. In the description of the different embodiments, the same reference numerals are given to the elements that play the same role, and duplicate description will be omitted.

First Embodiment As shown in FIG. 1, a first embodiment (P1) of the humidity control panel of the present invention has a rectangular cross section frame 25 having an opening.
And a plate-shaped humidity control section C1 interposed therein. The humidity control panel P1 is formed by pouring the kneaded constituent materials such as diatom shale, gypsum, water and the like (hereinafter, referred to as “humidity control constituent material”) into a frame 25 (impermeable member) and hardening. , And can be easily manufactured.

The frame 25 is formed of a steel plate frame, an aluminum plate frame, or the like, which is a moisture-impermeable material, and is a member that plays a role of blocking external moisture and the like. In addition, the humidity control section C1 may be filled in the entire inside of the frame 25 as shown in FIG. 1, or may be filled only in a part of the inside of the frame 25. There may be. Further, a layer made of a heat insulating material is formed at the bottom inside the frame body 25, and a humidity control component constituting material is provided on the bottom so as to have both a humidity control function and a heat insulating function. It can also be.

In the humidity control section C1, for the purpose of improving the powderiness of diatom shale and gypsum, for example, a neutrally permeable nonwoven fabric or a sealer is replaced with a moisture-impermeable member. The surface of the humidity control unit C1 can be protected and can be easily coated with paint or the like by sticking or applying to the surface that is not covered with, and covering the surface. Here, the reason why the moisture permeable material is used is that the humidity control section C1
This is because the humidity control function is not hindered. The reason why the neutral moisture permeable material is used is to keep the storage room neutral.

Examples of the moisture-permeable nonwoven fabric include a nonwoven fabric of resin fibers made of polypropylene or the like, a nonwoven fabric made of glass fibers, and the like. As the moisture-permeable sealer, there are various kinds such as a polyurethane resin sealer and an acrylic resin emulsion sealer. Since the sealer material is usually used as an undercoat material, it is generally applied with a finish overcoat. However, in the humidity control panel of the present invention, after the sealer material is applied, the portion is not overcoated and is used as it is.

Second Embodiment As shown in FIG. 2, a second embodiment (P2) of the humidity control panel of the present invention comprises a steel frame 26 (impermeable member) having a rectangular cross section, The frame 26 includes a bottom plate 27 (impermeable member) fixed to the bottom of the frame 26 and a plate-shaped humidity control portion C2 interposed inside the frame 26. The upper surface portion (the surface portion not covered by the moisture-impermeable member) of the humidity control portion C2 has a concave portion 22a formed of a rectangular parallelepiped.
The uneven portions 22 are formed such that the and the convex portions 22b are alternately arranged. The uneven portion 22 is formed in order to increase the surface area of the humidity control section C2 and increase the moisture absorption / release rate of the humidity control section C2.

In the humidity control panel P2, the frame 26 is placed on a mold having an uneven shape, and the kneaded material for the humidity control part is poured into the frame 26, and the material for the humidity control part is hardened. Later, it can be manufactured by removing the mold and closing one surface on which no unevenness is formed by using a bottom plate 27 formed of a steel plate or the like.

Third Embodiment As shown in FIG. 3, in a third embodiment (P3) of the humidity control panel of the present invention, a steel frame body 28 having a rectangular cross section having an opening (a moisture-impermeable panel) is provided. ) And a plate-shaped humidity control section C3 interposed inside the frame 28. A large number of concave portions 29 each having a conical tip and a cylindrical intermediate portion are formed on the upper surface portion (the surface portion not covered by the moisture-impermeable member) of the humidity control portion C3. The concave portion 29 is formed to increase the surface area of the humidity control section C3 and increase the rate of moisture absorption / release of the humidity control section C3, similarly to the humidity control panel P2 of the second embodiment. The humidity control panel P3 is formed by pouring the kneading component material mixed into the frame 28 and, after the humidity control component material has hardened, forming the concave portion 29 using a drill or the like having a predetermined shape. It can be easily manufactured.

The concave portions 22a, 29 of the humidity control panel P2 of the second embodiment and the humidity control panel P3 of the third embodiment.
Is performed for the purpose of increasing the surface area of the humidity control sections C2 and C3, and the shape is not limited. Therefore, it is also possible to provide an uneven portion having another shape or the like in the humidity control portion C2.
Also, by changing the number and size of the recesses 22a, 29 formed in the humidity control sections C2, C3 of the humidity control panels P2, P3, the rate of moisture absorption and desorption of moisture and the like can be freely adjusted. Can be adjusted.

Fourth Embodiment As shown in FIG. 4, a fourth embodiment (P4) of the humidity control panel of the present invention has a substantially rectangular cross section having an opening and a convex portion 31a on a side surface. Shaped steel frame 31
(Water-impermeable member), a steel plate 32 attached to the opening of the frame 31, and a plate-shaped humidity control portion C4 interposed in a part of the inside of the frame 31. Have been. The front plate 32 is provided with the air in the storage room by the humidity control section C4.
A large number of through holes 32a are bored to take in (or release) the frame plate 31. The front plate 32 is attached to the opening of the frame body 31 with a screw or an adhesive.

The preferred embodiment of the humidity control panel of the present invention has been described above. However, the design of the humidity control panel is not limited to the above embodiment, and the design can be appropriately changed without departing from the spirit of the present invention. That is, any structure can be used as long as a high degree of airtightness can be ensured by covering one surface of the humidity control panel outside the storage room with a moisture-impermeable member. Therefore, as in the first embodiment to the third embodiment, only one surface may be left and covered with a moisture-impermeable member. It is also possible to adopt a structure in which a steel plate or the like is attached to the entire back surface of the humidity control unit formed in a shape. Further, the surface of the humidity control panel on the storage room side may have any structure as long as it can absorb and release moisture in the storage room and maintain a constant humidity.

Method of Using Humidity Control Panel as Secondary Wall Subsequently, the humidity control panel P described as the second embodiment is used.
2 is used as the secondary wall 20 of the storage B. As shown in FIG. 5, the storage B is surrounded by a primary wall 10 which is a concrete wall, and a storage room F for storing stored items is formed therein. Here, as shown in FIG. 6, a required number of humidity control panels P2 are attached to the storage room F side of the primary wall 10 via a spacer 35. At that time, the bottom panel 27 of the humidity control panel P2 is set to the primary wall 10 side, and the upper surface of the humidity control unit C2 (the surface facing the bottom plate 27) is set to the storage room F side. By letting
The secondary wall 20 will be constructed.

(3) Operation of Humidity Control Panel Next, the humidity control panel P2 of the present invention is mounted on the secondary wall 2 of the storage B.
The operation when used as 0 will be described. In the humidity control panel P2 of the present invention, the pH of the humidity control portion C2 is adjusted to a neutral range of 5.5 to 8.0. Therefore, storage B
Even when used as the secondary wall 20 of
No acidic or alkaline substance is released from 2, and the storage room F is always kept neutral. Therefore, it is possible to effectively prevent deterioration of the stored items stored in the storage B.

The upper surface of the humidity control panel P2 is provided so as to be located on the storage room F side. Therefore, when the humidity in the storage room F is high, the humidity control section C2 is
If the humidity inside the storage room F is low, the humidity control section C2 will release moisture into the storage room F, and conversely, if the humidity inside the storage room F is low, the humidity inside the storage room F will be reduced. Humidity can be kept constant.

Further, the surface on the primary wall 10 side of the humidity control section C2 of the humidity control panel P2 is connected to a moisture impermeable member (the frame 26, the bottom plate 2).
Since it is covered by 7), it has a predetermined airtightness, and can effectively prevent various harmful substances from entering the storage room F. That is, sulfur oxides and concrete primary walls 10 that mainly enter from the atmosphere.
Prevent harmful substances (hereinafter referred to as "harmful substances") such as ammonia, formaldehyde generated from the mixture / adhesives, etc., from the inside, such as eggs of insect pests and fungi, from entering the storage room F. Can be. Note that even if a part of the harmful substance enters the storage chamber F, the humidity control unit C2 can adsorb the harmful substance.
Deterioration of stored items can be effectively prevented.

In addition, the unevenness portion 22 is formed on the surface of the humidity control portion C2, and the surface area of the humidity control portion C2 is large, so that the moisture absorption and desorption speed is high and the humidity control in the storage chamber F can be performed quickly. Can be.

Further, the surface of the humidity control section C2 is protected by attaching or applying a neutral permeable nonwoven fabric or a sealer material to the surface of the humidity control section C2. Etc. can be easily applied.

[0048]

EXAMPLES The results of various studies on the humidity control panel of the present invention will be described with reference to figures and tables.

Examination on Mixing Ratio of Main Constituent Materials The mixing ratio of the main constituent materials used in the humidity control panel of the present invention will be specifically described.

Mixing ratio of Wakkanai diatom shale and gypsum The mixing ratio of Wakkanai diatom shale and gypsum will be examined. When examining the following (1) to (4),
A humidity control unit prepared by mixing 120 parts by mass of water with 00 parts by mass is used.

(1) Investigation on pH of Humidity Control Section FIG. 7 (a) shows the total mass of Wakkanai diatom shale and gypsum in the humidity control section of the present invention (hereinafter referred to as "total mass of Wakkanai diatom shale / gypsum"). ) And the mixing ratio of Wakkanai diatom shale to p
9 shows the relationship of H. The pH was measured by crushing a 5 g sample of the moisture-conditioned part after curing, suspending it in 50 ml of distilled water, filtering after 30 minutes, and measuring the pH of the filtrate with a pH meter. The measurement results show that the pH tends to decrease as the mixing ratio of Wakkanai diatom shale increases. As described above, the pH of the humidity control unit that does not cause deterioration of the stored product in the storage is in the range of 5.5 to 8.0, and the pH is adjusted when the mixing ratio of the Wakkanai diatom shale is 0 to 83% by mass. It can be seen that this corresponds to the pH range.

(2) Study on Flexural Strength of Humidity Control Section FIG. 7B shows the relationship between the mixing ratio of the diatom shale of the Wakkanai layer to the total mass of the diatom shale and gypsum of the Wakkanai layer and the flexural strength of the humidity control section. Things. Note that the humidity control unit used in this study uses the type of humidity control unit C1 described in the first embodiment, which does not have the uneven portion on the surface. According to the measurement results, the bending strength slightly increases until the mixing ratio of the Wakkanai diatom shale becomes about 66% by mass, but the bending strength decreases as the Wakkanai diatom shale increases beyond the mixing ratio. You can see that there is. As described above, the bending strength of the humidity control section used for the storage needs to be 1.5 N / mm ² or more,
It can be seen that the mixing ratio of the Wakkanai diatom shale corresponds to the range of 0 to 85% by mass. When the mixing ratio of the Wakkanai diatom shale becomes 80% by mass or more, the reason why the bending strength sharply decreases is that the binder relatively decreases.

(3) Investigation on the amount of moisture absorbed by the humidity control section FIG. 9A shows the mixing ratio of the Wakkanai diatom shale to the total mass of the diatom shale and gypsum of the Wakkanai layer, and 1 hour per unit area of the humidity control section. It shows the relationship of the amount of moisture absorption. FIG. 10 (a) shows the relationship between the mixing ratio of the Wakkanai diatom shale to the total mass of the Wakkanai diatom shale and gypsum, and the amount of moisture absorbed for 96 hours per unit area of the humidity control section.

The moisture absorption test for measuring the amount of moisture absorption of the humidity control section was performed by the following method. The humidity control part of the humidity control panel was used as a test body, and seasoning was performed in a constant temperature / humidity chamber at a temperature of 20 ° C. and a relative humidity of 60% until a constant weight was reached. Then, temperature 2
The humidity setting was changed to 0 ° C. and a relative humidity of 90%, and the mass change of the test specimen after 1 hour and 96 hours (4 days) was measured as the moisture absorption according to the formula (A). Further, the amount of moisture absorption per unit area of the test specimen was calculated by the formula (B). Moisture absorption (g) = mass at measurement time−mass at completion of seasoning (A) Moisture absorption per unit area of test specimen (g / m ² ) = moisture absorption / area of moisture absorption surface (( B)

The target of the performance of the humidity control material is about twice the capacity of the conventionally used cedar wood, so that the moisture absorption is twice as much as that of the cedar wood. The following can be seen from the results of the moisture absorption test. 1) The one-hour moisture absorption of cedar wood is about 10 g / m ² , and when the mixing ratio of Wakkanai diatom shale is 30% by mass or more, it exceeds twice the one-hour moisture absorption of cedar wood. 2) The 96-hour moisture absorption of cedar wood is about 130 g / m ² , and when the Wakkanai diatom shale is 15% by mass or more, it exceeds twice the 96-hour moisture absorption of cedar wood. 3) When the Wakkanai diatom shale and gypsum are mixed, the moisture absorption increases as the mixing ratio of the Wakkanai diatom shale increases. 4) The mixing ratio of Wakkanai diatom shale is 8 with 96 hours of moisture absorption.
When comparing the case of 0% by mass with the amount of moisture absorption of cedar wood, the moisture absorption of the present invention is about 1450 g / m ² , and the moisture absorption of cedar wood (13
0 g / m ² ), which is about 11.2 times that of the conventional humidity control material.

Therefore, from the above results, it is necessary to mix 30% by mass or more of Wakkanai diatom shale in order to exhibit a moisture absorption performance exceeding twice that of cedar wood.

(4) Investigation on the amount of moisture released from the humidity control section FIG. 9B shows the mixing ratio of the Wakkanai diatom shale to the total mass of the diatom shale and gypsum of the Wakkanai layer, and 1 per unit area of the humidity control section. It shows the relationship of the amount of time moisture release. FIG. 10B shows the relationship between the mixing ratio of the Wakkanai diatom shale and the total mass of the Wakkanai diatom shale and gypsum, and the amount of moisture released for 96 hours per unit area of the humidity control section.

The moisture release test for measuring the moisture release of the humidity control panel was performed by the following method. The humidity control part of the humidity control panel was used as a test body, and seasoning was performed in a constant temperature / humidity chamber at a temperature of 20 ° C. and a relative humidity of 60% until a constant weight was reached. Thereafter, the humidity setting was changed to a temperature of 20 ° C. and a relative humidity of 40%, and (C)
According to the formula, the mass change of the test body after 1 hour and 96 hours (4 days) was measured as a moisture release amount. Further, the amount of moisture release per unit area of the test specimen was calculated by the formula (D). Moisture releasing amount (g) = seasoning at completion of the mass - the area of the desorption amount (g / m ²⁾ = moisture release amount sorption / desorption surface of the mass · · · (C) specimens per unit area at the measurement time,・ ・ (D)

Since the target of the performance of the humidity control material is about twice the capacity of the conventionally used cedar material, the moisture release amount is twice as much as that of the cedar material. The following can be seen from the results of the moisture release test. 1) The hourly moisture release of cedar wood is about 10 g / m ² , and when the Wakkanai diatom shale is 34% by mass or more, it exceeds twice the amount of one hour moisture release of cedar wood. 2) The 96-hour moisture release of cedar wood is about 120 g / m ² , and when the Wakkanai diatom shale is 30% by mass or more, it exceeds twice the 96-hour moisture release of cedar wood. You. 3) When Wakkanai diatom shale and gypsum are mixed, the higher the mixing ratio of Wakkanai diatom shale, the greater the amount of moisture release. 4) Mixing ratio of Wakkanai diatom shale is 8 at 96 hours
Comparing the case of 0% by mass with the amount of moisture release of cedar wood, the amount of moisture release of the present invention is about 680 g / m ² , and the amount of moisture release of cedar wood (120
g / m ² ), which is about 5.7 times that of the conventional humidity control material.

Therefore, from the above results, it is necessary to mix 34% by mass or more of Wakkanai diatom shale in order to exhibit a moisture release performance exceeding twice that of cedar wood.

(5) Conclusion From the results of the above (1) to (4), in order to form a humidity control part having a performance exceeding twice the performance of cedar wood,
It is necessary to mix the Wakkanai diatom shale so that the mixing ratio of the Wakkanai diatom shale to the total mass of the Wakkanai diatom shale and gypsum is in the range of 34% to 83% by mass. In particular, the higher the content of Wakkanai diatom shale, the more porous parts it contains, and the higher its adsorption effect.
Therefore, the effect becomes higher as the mixing ratio of the Wakkanai diatom shale is closer to 83% by mass.

FIG. 8 shows the mixing ratio of Wakkanai diatom shale and gypsum, which is a mixing ratio of 74 mass% of Wakkanai diatom shale and 26 mass% of gypsum. The bending strength of the humidity control section was examined by changing the mixing ratio of water. According to this result, the mixing ratio of water is about 60 parts by mass,
The monotonous increase has changed to a monotonous decrease, and the value of the maximum bending strength is about 3.8 N / mm ² . As described above, the bending strength of the humidity control panel used for the storage is 1.5 N / mm ^2.
More preferably, the mixing ratio of water is 30 to 1
It is necessary to be within the range of 60 parts by mass. In particular, it is preferable that the mixing ratio of water is a value close to 60 parts by mass.

When the mixing ratio of water is less than 30 parts by mass, the viscosity of the mixed main constituent materials becomes extremely high, and it becomes difficult to mold the humidity control section. Conversely, if the mixing ratio of water is more than 160 parts by mass, the mixed main constituent materials will not solidify. Therefore, in both cases, the humidity control unit cannot satisfy the required strength.

Examination of Adsorption Performance of Humidity Control Unit An adsorption test was conducted to determine how much the humidity control unit used in the humidity control panel of the present invention adsorbs various harmful substances other than water. . In the present study, the mixing ratio of the main constituent materials of the humidity control section was as follows: a mixture of the Wakkanai diatom shale and gypsum consisting of 74% by mass of Wakkanai diatom shale and 26% by mass of gypsum
120 parts by mass of water is mixed with 100 parts by mass of the gypsum. As shown in FIG. 11, the test method was performed using the cured humidity control section 52 (7.5) used in the humidity control panel.
g) was placed in a test container 51, each test gas was injected under the conditions shown in Table 1, and the concentrations were measured at the inlet 51a and the outlet 51b with a detector tube, and the adsorptivity was determined from the degree of decrease in the concentration. From the results shown in Table 1, sulfur dioxide (SO ₂ ) and ammonia (N
H _3), significant adsorption performance was observed for the formaldehyde (HCHO).

[0065]

[Table 1]

Examination of the moisture absorption / desorption performance of the uneven part in the humidity control part In order to investigate the moisture absorption / desorption performance of the uneven part in the humidity control part, the moisture absorption and release of the humidity control panel having the uneven part formed in the humidity control part was examined. Wetness was measured. In the present study, the mixing ratio of the main constituent materials of the humidity control section is as follows: in a mixture of the Wakkanai diatom shale and gypsum consisting of 74% by weight of Wakkanai diatom shale and 26% by weight of gypsum, 120 parts by weight of water and 100 parts by weight of the gypsum Parts are mixed.

Although the humidity control panel has different moisture absorption / desorption performance depending on the shape of the uneven portion even with the same surface area, in this embodiment, the humidity control panel P having the uneven portion 22 formed on one surface of the humidity control portion shown in FIG.
2 was used for the test. The humidity control panel P2 has the same shape as the humidity control panel P1 in which the uneven portion 22 is not formed (FIG. 1).
(Hereinafter, referred to as “comparison panel”), the surface area is 1.72 times and the volume is 0.78 times. Table 2
It shows how many times the moisture absorption and desorption amount of the humidity control panel P2 is larger than the moisture absorption and desorption amount of the comparative panel P1. According to this result, it was found that the moisture absorption / desorption rate was extremely high (particularly, the moisture absorption / desorption amount for one hour), and that the humidity in the storage room could be quickly adjusted.

[0068]

[Table 2]

Examination of the effect of improving the surface of the humidity control section by the nonwoven fabric and the sealer material In order to examine the effect of improving the surface of the humidity control section by the nonwoven fabric and the sealer material, the cellophane tape method (JIS K 5400) was used.
8.5 Paint general test method: see adhesion). In the present study, the mixing ratio of the main constituent materials of the humidity control section was as follows.
It is obtained by mixing 120 parts by mass of water with respect to 00 parts by mass.

The outline of the test is as follows. First, a humidity control unit cut into a shape of product thickness x 100 mm x 150 mm is fixed on a surface plate, and a cellophane adhesive having a width of 18 mm or 24 mm is attached to the upper surface of the humidity control unit so that the length of the adhesive portion is 50 mm. A tape (hereinafter, referred to as “tape”) is stuck and rubbed with an eraser to completely adhere to the humidity control unit. Next, one to two minutes after the tape is attached, hold one end of the tape and instantaneously peel off the tape while keeping it perpendicular to the surface of the humidity control unit, and determine the amount, size, etc. of the constituent materials attached to the tape. Observe.

As a result of the test using the cellophane tape method, when the nonwoven fabric and the sealer material were applied to the surface of the humidity control part, the adhesion of the constituent material to the tape was slightly observed when the nonwoven fabric and the sealer material were not applied. It became clear that the powderiness improved.

[0072]

According to the humidity control panel of the present invention, since the pH of the humidity control section is maintained in the neutral range of 5.5 to 8.0, it can be used as a secondary wall of a storage. Even if the humidity control unit does not release acidic or alkaline substances,
The storage room is kept neutral at all times. Therefore, it is possible to effectively prevent deterioration of the stored items stored in the storage room.

Further, it is possible to produce a humidity control panel which is far superior in humidity control property and heat resistance and nonflammability, as compared with the conventional humidity control panel using wood or the like. In addition, since harmful substances can be adsorbed not only to moisture but also to stored items stored in the storage room, deterioration of the stored items can be effectively prevented.

Further, since the diatom shale and the gypsum are mixed at an appropriate mixing ratio, the humidity control section can have a desired strength. In addition, since at least one surface of the humidity control section is covered with the moisture-impermeable member, it is possible to provide a highly airtight humidity-control panel, and a frame formed from the moisture-impermeable member. By filling the kneaded constituent material, the method of manufacturing the humidity control panel can be performed very easily.

[Brief description of the drawings]

FIG. 1A is a perspective view and FIG. 1B is a sectional view showing a first embodiment of a humidity control panel of the present invention.

FIG. 2A is a perspective view and FIG. 2B is a sectional view showing a second embodiment of the humidity control panel of the present invention.

FIG. 3A is a perspective view and FIG. 3B is a cross-sectional view showing a third embodiment of the humidity control panel of the present invention.

FIG. 4A is a perspective view and FIG. 4B is a cross-sectional view showing a humidity control panel according to a fourth embodiment of the present invention.

FIG. 5 is a partially cutaway perspective view of a storage.

FIG. 6 is a partially enlarged perspective view showing a state where a secondary wall is formed by the humidity control panel of the present invention.

FIG. 7 (a) is a graph showing the relationship between the mixing ratio of the Wakkanai diatom shale and the pH relative to the total mass of the Wakkanai diatom shale and gypsum, and the horizontal axis represents the mixing ratio of the Wakkanai diatom shale (mass%). ), The vertical axis is the pH value. (B) is a graph showing the relationship between the mixing ratio of the Wakkanai diatom shale and the bending strength with respect to the total mass of the Wakkanai diatom shale and gypsum, where the horizontal axis is the mixing ratio (mass%) of the Wakkanai diatom shale and the vertical axis. Is the bending strength (N / mm ² )
It is.

FIG. 8: With the total mass of the diatom shale and gypsum of the Wakkanai layer constant,
It is the graph which showed the relationship between the mixing ratio of water and the bending strength of a humidity control part, and a horizontal axis | shaft is a mixing ratio of water (mass part), and a vertical axis | shaft is bending strength (N / mm < ² >).

FIG. 9A is a graph showing the relationship between the mixing ratio of the Wakkanai diatom shale and the amount of moisture absorption in the humidity control section with respect to the total mass of the Wakkanai diatom shale and gypsum, and the horizontal axis represents the mixing of the Wakkanai diatom shale. The ratio (% by mass) and the vertical axis represent the amount of moisture absorbed per hour (g / m ² ).
(B) is a graph showing the relationship between the mixing ratio of the Wakkanai diatom shale and the amount of moisture released in the humidity control section with respect to the total mass of the Wakkanai diatom shale and gypsum, and the horizontal axis is the mixing ratio of the Wakkanai diatom shale (mass) %), And the vertical axis indicates the amount of moisture released per hour (g / m ² ).

FIG. 10 (a) is a graph showing the relationship between the mixing ratio of the Wakkanai diatom shale to the total mass of the diatom shale and gypsum of the Wakkanai layer and the amount of moisture absorbed in the humidity control section, and the horizontal axis represents the mixing of the diatom shale of the Wakkanai layer. The ratio (% by mass) and the vertical axis indicate the amount of moisture absorption (g / m ² ) for 96 hours. (B) is a graph showing the relationship between the mixing ratio of the Wakkanai diatom shale and the amount of moisture released in the humidity control section with respect to the total mass of the Wakkanai diatom shale and gypsum, and the horizontal axis is the mixing ratio of the Wakkanai diatom shale (mass) %), And the vertical axis indicates the amount of moisture released for 96 hours (g / m ² ).

FIG. 11 is an explanatory diagram of an apparatus used for an adsorption test.

[Explanation of symbols]

 C1, C2, C3, C4 Humidity control part P1, P2, P3, P4 Humidity control panel 22 Concavo-convex part 22a Concave part 22b Convex part 25, 26, 28, 31 Frame 27 Bottom plate 29 Concave part 31a Convex part

 ──────────────────────────────────────────────────続 き Continued on the front page F term (reference) 2E001 DB00 DB04 DD02 DD05 DE01 DH12 DH13 EA01 FA00 FA03 GA17 GA28 GA46 HA33 HB02 HB04 HE10 JA02 JA22 KA03 KA08 LA00 LA01 LA04 4G012 PA05 PA07 PB11

Claims (5)

[Claims] 1. A humidity control unit comprising: a humidity control unit formed by kneading a main constituent material composed of diatom shale, gypsum, and water into a plate shape; and a moisture-impermeable member covering at least one surface of the humidity control unit. A panel, wherein the hydrogen ion concentration index of the humidity control section is in a range of 5.5 to 8.0, and the bending strength of the humidity control section is 1.5 N / mm ² or more. Humidity control panel. 2. The humidity control panel according to claim 1, wherein the diatom shale is Wakkanai diatom shale. 3. A humidity control section formed by kneading a main constituent material composed of diatom shale, gypsum and water of the Wakkanai layer, and a moisture-impermeable member covering at least one surface of the humidity control section. A humidity control panel, wherein the mixing ratio of the Wakkanai diatom shale and the gypsum is in the range of 34% to 83% by mass of the Wakkanai diatom shale with respect to the total mass thereof, and the gypsum and the water are mixed. The mixing ratio is 30 parts by mass to 160 parts by mass of the water with respect to 100 parts by mass of the gypsum. 4. The humidity control panel according to claim 1, wherein an uneven portion is formed on a surface of the humidity control section that is not covered with the moisture-impermeable member. 5. The moisture control unit according to claim 1, wherein a surface portion of the humidity control unit that is not covered with the moisture-impermeable member is covered with a neutral moisture-permeable material. The humidity control panel described in.