JP5382416B2 - Joinery and fireproof covering materials - Google Patents

Description

  The present invention relates to a fitting such as a glass door or a glass partition that is formed with a glass plate and partitions a space inside a building.

  Conventionally, for example, glass windows, glass doors, glass walls, glass partitions, etc. are often used as building members that divide the space inside a building such as an office building. (See, for example, Patent Document 1). Moreover, generally, the glass plate of this type of joinery often uses float glass because it has a great advantage of being inexpensive. However, float glass is easy to crack and fall off when heated at high temperatures in the event of a fire, so it cannot prevent the outflow of flames and smoke from the fire side to the non-fire side and suppresses the spread of fire spread in the building There was a fault that the effect and the effect on life safety cannot be expected.

  On the other hand, as a glass plate for joinery, for example, heat-resistant tempered glass having excellent heat resistance is often used by forming only pure anhydrous silicic acid as a component. This heat-resistant tempered glass has almost the same appearance as float glass, and at the time of fire, the glass does not fall off for at least 20 minutes, and it is possible to prevent a flame or smoke from penetrating the back side of the glass.

Japanese Patent Laid-Open No. 5-287611

  However, heat-resistant tempered glass is very expensive compared to float glass, and when heat-resistant tempered glass is used as a glass plate for joinery, it can be prevented from falling off in the event of a fire, but radiant heat is the same as float glass. Therefore, there is a risk that radiant heat may propagate from the fire side to the non-fire side and cause fire spread.

In view of the above circumstances, the present invention provides a joinery that is inexpensive and uses a float glass and that can reliably exhibit flameproofness, smokeproofing, and thermal barrier properties in the event of a fire, and a fireproof coating material provided therein. The purpose is to do.

  In order to achieve the above object, the present invention provides the following means.

ここで、ＳｉＯ _２ 、Ｎａ _２ Ｏ、Ｘ、Ｙは重量あるいは重量比、［ＳｉＯ _２ ］、［Ｎａ _２ Ｏ］、［Ｘ］、［Ｙ］は式量であり、Ｘは水酸化カリウム、Ｙは硼砂を示す。
また、本発明の耐火被覆材は、ガラス板の両面または片面のガラス面に接着して、火災時に遮熱性を発揮するとともに前記ガラス板の脱落を防止するための耐火被覆材であって、透明なフィルムシートからなる表面保護フィルムに珪酸ソーダ層を一体に積層して形成され、且つ、下記の式（化２）で設定されるモル比の数値が２〜３となるように珪酸ソーダ層が形成されていることを特徴とする。

ここで、ＳｉＯ _２ 、Ｎａ _２ Ｏ、Ｘ、Ｙは重量あるいは重量比、［ＳｉＯ _２ ］、［Ｎａ _２ Ｏ］、［Ｘ］、［Ｙ］は式量であり、Ｘは水酸化カリウム、Ｙは硼砂を示す。 The joinery of the present invention is a joinery for partitioning a space inside a building, and a glass plate whose both surfaces or one surface is coated with a fireproof coating material and an outer edge portion side of the glass plate are engaged with an engagement groove. An outer peripheral support frame that supports the glass plate, a setting block that is provided in the engagement groove and positions the glass plate, and is provided by filling the engagement groove. A backup material for supporting by the outer peripheral support frame; and a sealing material provided by filling the opening side of the engagement groove and sealing between the outer peripheral support frame and the glass plate, Sodium silicate is formed by integrally laminating a sodium silicate layer on a surface protective film made of a transparent film sheet, and the numerical value of the molar ratio set by the following formula (Formula 1) is 2-3. Layer formed And which, refractory coating material, fixed to the end side by the sealing material, the sodium silicate layer is adhered to the glass surface of the glass plate, that is provided so as to cover the glass plate Features.

Here, SiO ₂ , Na ₂ O, X and Y are weights or weight ratios, [SiO ₂ ], [Na ₂ O], [X] and [Y] are formula weights, X is potassium hydroxide, Y Indicates borax.
The fire-resistant coating material of the present invention is a fire-resistant coating material that adheres to both or one glass surface of a glass plate and exhibits thermal insulation in the event of a fire and prevents the glass plate from falling off. The sodium silicate layer is formed by integrally laminating a sodium silicate layer on a surface protective film made of a simple film sheet, and the molar ratio set by the following formula (Formula 2) is 2-3. It is formed.

Here, SiO ₂ , Na ₂ O, X and Y are weights or weight ratios, [SiO ₂ ], [Na ₂ O], [X] and [Y] are formula weights, X is potassium hydroxide, Y Indicates borax.

In these inventions, the fireproof coating is formed by integrally laminating a sodium silicate layer on the surface protective film, and the numerical value of the molar ratio set by the above formulas (Chemical Formula 1, Chemical Formula 2) is 2-3. Since the sodium silicate layer is formed so that it becomes, and since this fireproof coating material is provided by adhering and covering one or both sides of the glass plate, the sodium silicate layer is heated in the event of a fire. And foams, increasing its thickness and changing its color from nearly transparent to white. Further, even when the glass plate is cracked by heating, the sodium silicate layer is foamed, adheres to the glass plate, and enters the cracked portion, so that the glass plate can be prevented from falling off.

In the joinery and fireproof coating material of the present invention, the sodium silicate layer of the fireproof coating material is heated and foamed in the event of a fire, the thickness increases, and the color changes from substantially transparent to nearly white. For this reason, at the time of a fire, heat insulation is exhibited by the increase in the thickness of the sodium silicate layer and the color change to a color close to white, and even when, for example, float glass is used for the glass plate, the glass plate is broken by heating. Can be suppressed. Moreover, it can prevent that radiant heat permeate | transmits from a fire side to a non-fire side, and can prevent fire spread by radiant heat.

  Furthermore, even if the glass plate is cracked by heating, the sodium silicate layer foams and adheres to the glass plate, and also enters the cracked part, preventing the glass plate from falling off. As a result, it is possible to prevent the flame and smoke from flowing out from the fire side to the non-fire side.

Therefore, according to the joinery and fireproof covering material of the present invention, it is possible to form the joinery at low cost using float glass, and to reliably exhibit flameproof, smokeproof, and heatproof properties in the event of a fire. Is possible.

It is sectional drawing which shows the fitting which concerns on one Embodiment of this invention. It is sectional drawing which shows the modification of the fitting which concerns on one Embodiment of this invention.

Hereinafter, with reference to FIG.1 and FIG.2, the fitting and fireproof coating | covering material which concern on one Embodiment of this invention are demonstrated. The present embodiment relates to a fixture such as a glass door or a glass partition, which is formed with a glass plate and divides a space inside a building, and a fireproof covering material provided therein .

  As shown in FIG. 1, the joinery A of this embodiment includes a glass plate 1, an outer peripheral support frame 2, a setting block 3, a backup material 4, a fireproof covering material 5, and a sealing material 6. Has been.

  The glass plate 1 of the present embodiment is float glass formed in, for example, a rectangular plate shape, and is basically one having a thickness of 6 mm that is most often used for a normal glass partition or the like. In addition, you may use what has higher intensity | strength, such as thicker float glass and tempered glass, for the glass plate 1. FIG.

  The outer peripheral support frame 2 is formed using, for example, a non-combustible material such as steel or aluminum used for a normal glass door or glass partition. Moreover, the outer periphery support frame 2 is provided with the engagement groove | channel 2a dented from an inner surface toward an outer surface, and is formed in the cross-sectional concave shape. And this outer periphery support frame 2 is provided so that the outer edge part 1a side of the glass plate 1 may be engaged with the engaging groove 2a, and the glass plate 1 arrange | positioned inside the outer periphery support frame 2 may be supported. .

  The setting block 3 is a non-combustible material, and is interposed between the bottom surface 2b of the engaging groove 2a below the outer peripheral support frame 2 and the outer edge 1a (lower end) of the glass plate 1 engaged with the engaging groove 2a. It is provided inside the engaging groove 2a so as to be worn. The setting block 3 is provided to support the glass plate 1 in a state where it is disposed at a predetermined height and to position the glass plate 1.

  The backup material 4 is a non-combustible material, and is provided by filling the inside of the engagement groove 2 a on the bottom surface 2 b side so as to fill the space between the outer edge portion 1 a side of the glass plate 1 and the outer peripheral support frame 2. The backup material 4 is provided to support the glass plate 1 with the outer peripheral support frame 2.

  The fireproof covering material 5 is formed by integrally laminating a sodium silicate layer 5b on a surface protective film 5a, and the glass substrate 1 is covered by adhering the sodium silicate layer 5b to the glass surfaces 1b and 1c of the glass plate 1. It is provided to do. Moreover, in this embodiment, although the fireproof covering material 5 is provided so that both surfaces (glass surface 1b, 1c) of the glass plate 1 may be coat | covered, the state which installed the fitting A so that the space inside a building may be divided Thus, when only the space on one side is the fire side across the fitting A, the fireproof covering material 5 may be provided only on the one surface 1b (1c) side of the glass plate 1 facing the fire side.

  And the surface protection film 5a of this fireproof covering material 5 is a transparent (including colored transparency) film sheet, and is formed using, for example, polycarbonate, polyester, polypropylene, polyamide, polyimide, polyetherimide, or the like. . Further, the surface protective film 5a does not impair the thickness of the workability when the fireproof coating material 5 is attached to the glass plate 1, that is, the flexibility of the fireproof coating material 5 (surface protective film 5a). For example, it is formed with a thickness of less than 0.1 mm. Further, the surface protective film 5a is melted when heated, and one surface of the surface protective film 5a is subjected to an easy adhesion treatment so as to be in close contact with the sodium silicate layer 5b. Such a surface protective film 5a protects the sodium silicate layer 5b during normal operation (when the fitting A is in service), prevents the sodium silicate layer 5b from drying, and keeps the sodium silicate layer 5b having a predetermined moisture content over a long period of time. It is provided for holding in a state.

  The sodium silicate layer 5b is transparent (including colored transparent) in which powdered sodium silicate is mixed with water, potassium hydroxide, borax, etc., and has a predetermined moisture content, for example, about 40 to about 70%, preferably Is formed with a moisture content of about 50 to about 60%. The thickness of the sodium silicate layer 5b is about 1 mm. And such a sodium silicate layer 5b is provided with adhesiveness, and can be easily adhere | attached with the surface protection film 5a and the glass plate 1. FIG. The sodium silicate layer 5b may be formed using liquid sodium silicate instead of powdered sodium silicate and water. In addition, the thickness of the sodium silicate layer 5b may be appropriately determined according to the required fire resistance.

Further, the sodium silicate layer 5b has elasticity and is not easily damaged. This elasticity is ensured by adding a predetermined amount of a metal salt such as potassium hydroxide or borax to sodium silicate. And, at the time of blending, by making the numerical value of the molar ratio set as the following formula ( Chemical Formula 3 ) to be about 2-3, it is possible to suitably impart elasticity and form the sodium silicate layer 5b. It becomes possible.

ここで、ＳｉＯ_２、Ｎａ_２Ｏ、Ｘ（水酸化カリウム）、Ｙ（硼砂）は重量（ｇ）あるいは重量比（％）であり、[ＳｉＯ_２]、[Ｎａ_２Ｏ]、[Ｘ]、[Ｙ]は式量である。

Here, SiO ₂ , Na ₂ O, X ( potassium hydroxide ), Y ( borax ) are weight (g) or weight ratio (%), and [SiO ₂ ], [Na ₂ O], [X], [Y] is a formula weight.

  The sealing material 6 is a non-combustible material, and is based on the designation for a fire door such as a one-component silicone sealant, and the inside of the engagement groove 2a of the outer peripheral support frame 2 (the outer support frame 2 is more The inner engagement groove 2a is filled and provided. And this sealing material 6 is provided between the outer periphery support frame 2 and the glass plate 1, and is provided so that this part may be sealed. Moreover, in this embodiment, the sealing material 6 is provided with the fixing | fixed part 6a whose width | variety is about 1-2 mm, for example, Between this fixing | fixed part 6a and the glass plate 1, the fireproof coating material 5 (surface protection film 5a) is provided. It is provided so as to sandwich and fix the end portion. Further, the sealing material 6 provided with the fixing portion 6a fixes the end portion of the fireproof covering material 5 and treats the end portion of the sodium silicate layer 5b so as not to come into contact with air.

  In addition, without providing the fixing | fixed part 6a, as shown, for example in FIG. 2, the edge part of the fireproof coating material 5 is embed | buried in the sealing material 6 by the depth of about 1-2 mm, for example, and the surface protection film 5a is used with this sealing material 6. It is possible to treat the soda silicate layer 5b so that it does not touch the air.

  Next, the operation and effect of the joinery A of the present embodiment having the above-described configuration will be described.

  First, in the joinery A of the present embodiment, the fireproof coating 5 is formed by laminating a transparent surface protective film 5a and a transparent sodium silicate layer 5b, and the fireproof coating 5 is bonded to the glass plate 1 (float glass). Therefore, the appearance (feeling of opening) is not impaired during normal time (in service), for example, like a meshed glass.

  Further, the fireproof covering material 5 is formed by using an inexpensive surface protective film 5a and an inexpensive sodium silicate layer 5b mainly composed of sodium silicate which is cheaper than water. Since the joinery A is configured by being attached to the glass surfaces 1b and 1c of the float glass 1 which is less expensive than glass or heat-resistant tempered glass, the joinery A can be formed at low cost.

  Further, when the fireproof coating material 5 is attached to the glass surfaces 1b and 1c of the glass plate 1, the fireproof coating material 5 (surface protective film 5a and sodium silicate layer 5b) has elasticity, so that Can be pasted. Furthermore, since the fireproof covering material 5 has elasticity, it is safe and easy to carry and install the fitting A to which the fireproof covering material 5 is attached.

  On the other hand, when a fire occurs, first, the surface protective film 5a of the fireproof covering material 5 provided on the glass surfaces 1b and 1c of the glass plate 1 is heated. Then, the surface protective film 5a is heated, for example, at around 100 ° C. and melted, and the sodium silicate layer 5b is exposed and heated.

  The sodium silicate layer 5b starts to foam when heated at a temperature of about 100 ° C. due to a fire, and the thickness of about 1 mm increases to, for example, several cm. In addition to foaming in this way, the color changes from transparent to nearly white. In addition, the foaming thickness of the sodium silicate layer 5b is generally maintained up to about 700 ° C., and is not greatly reduced even when heated at a high temperature. In addition, in order for the sodium silicate layer 5b to foam properly in a fire, it is necessary to maintain a predetermined moisture content in a normal time. In this embodiment, the surface protection film 5a and the glass plate 1 are used. Since both sides of the sodium silicate layer 5b are covered and the end of the sodium silicate layer 5b is covered with the sealing material 6, the water content of the sodium silicate layer 5b is suitably maintained, and this sodium silicate layer is surely secured in the event of a fire. 5b will foam.

  Even when the sodium silicate layer 5b is foamed in this way, the thickness increases, and the color is changed from a transparent color to a color close to white. The heat at the time of fire is insulated by the sodium silicate layer 5b, and the temperature of the glass plate 1 is kept low. For this reason, it is suppressed that the glass plate 1 breaks. Further, since the sodium silicate layer 5b changes to a color close to white, it is possible to prevent the radiant heat from being transmitted from the fire side to the non-fire side, and the heat shielding property is also exerted against this radiant heat. For this reason, it is prevented that fire spread occurs by radiant heat.

  On the other hand, when the sodium silicate layer 5b is heated at a temperature exceeding 800 ° C. for a long time, the sodium silicate layer 5b is somewhat melted. For this reason, there is a possibility that the temperature of the glass plate 1 rises and the glass plate 1 is cracked. Thus, even when the glass plate 1 is cracked by heating, the sodium silicate layer 5b foams and adheres to the glass plate 1 and enters the cracked portion, so that the glass plate 1 does not fall off. . Therefore, even when float glass is used for the glass plate 1, it is possible to prevent flames and smoke from flowing out from the fire side to the non-fire side as the glass plate 1 is dropped.

Therefore, in the joinery A and the fireproof coating material 5 of the present embodiment, the sodium silicate layer 5b of the fireproof coating material 5 is heated and foamed in the event of a fire, the thickness increases, and the color changes from substantially transparent to nearly white. To do.
For this reason, at the time of a fire, even if it is a case where float glass is used for the glass plate 1 by heating, the glass plate 1 is heated by the increase in thickness of the sodium silicate layer 5b and discoloration to a color close to white. It becomes possible to suppress cracking. Moreover, it can prevent that radiant heat permeate | transmits from a fire side to a non-fire side, and can prevent fire spread by radiant heat.

  Furthermore, even when the glass plate 1 is cracked by heating, the sodium silicate layer 5b foams and adheres to the glass plate 1, and enters the cracked portion, so that the glass plate 1 can be prevented from falling off. It is possible to prevent the flame and smoke from flowing out from the fire side to the non-fire side when the glass plate 1 is dropped.

Therefore, according to the joinery A and the fireproof covering material 5 of the present embodiment, it is possible to form the joinery A at low cost by using float glass, and reliably ensure flameproofing, smokeproofing, and thermal insulation in the event of a fire. Can be demonstrated.

As mentioned above, although one embodiment of the joinery and fireproof covering material concerning the present invention was described, the present invention is not limited to the above-mentioned one embodiment, and can be suitably changed in the range which does not deviate from the meaning. For example, in the present embodiment, the description has been made on the assumption that the glass plate 1 can be prevented from falling off by the fireproof coating material 5 in the event of a fire. However, by providing the fireproof coating material 5, for example, the glass plate 1 is broken during an earthquake or the like. It is also possible to prevent scattering.

  Moreover, in this embodiment, it demonstrated that the joinery A which stuck the fireproof covering material 5 was carried, installed, and newly installed the joinery A, However, The float of existing joinery, such as a glass door and a glass partition, was demonstrated. You may make the joinery A of this invention by affixing the fireproof covering material 5 to glass (glass plate 1). In this case, the fireproof performance can be imparted simply by attaching the fireproof covering material 5 to the existing glass plate 1 and fixing the end thereof with the sealing material 6. For this reason, compared with the case where it replaces | exchanges with a meshed glass or a heat-resistant tempered glass, it becomes possible to improve fireproof performance easily cheaply.

1 Glass plate (float glass)
DESCRIPTION OF SYMBOLS 1a Outer edge part 1b Glass surface 1c Glass surface 2 Peripheral support frame 2a Engagement groove 2b Bottom face 3 Setting block 4 Backup material 5 Fireproof covering material 5a Surface protection film 5b Sodium silicate layer 6 Sealing material 6a Fixing part A Fixture

Claims (2)

It is a joinery for partitioning the space inside the building,
Provided inside the engagement groove, a glass plate whose both surfaces or one surface is coated with a fireproof coating material, an outer peripheral support frame that supports the glass plate by engaging the outer edge side of the glass plate with the engagement groove A setting block for positioning the glass plate, a back-up material for filling the engagement groove and supporting the glass plate with the outer peripheral support frame, and an opening side of the engagement groove. A sealing material that is provided filled inside and seals between the outer peripheral support frame and the glass plate;
The fireproof coating material is formed by integrally laminating a sodium silicate layer on a surface protective film made of a transparent film sheet, and the molar ratio set by the following formula (Chemical Formula 1) is 2-3. A sodium silicate layer is formed, and the fireproof coating material is fixed to the glass plate of the glass plate by fixing the end portion side with the sealing material and adhering the sodium silicate layer to the glass surface of the glass plate. Joinery characterized by being provided.

Here, SiO ₂ , Na ₂ O, X and Y are weights or weight ratios, [SiO ₂ ], [Na ₂ O], [X] and [Y] are formula weights, X is potassium hydroxide, Y Indicates borax. Adhering to the glass surface on both sides or one side of the glass plate, a fireproof covering material for preventing the glass plate from falling off while exhibiting heat shielding in the event of a fire,
A sodium silicate layer is formed by integrally laminating a sodium silicate layer on a surface protective film made of a transparent film sheet, and the numerical value of the molar ratio set by the following formula (Formula 2) is 2-3. A fireproof covering material characterized in that is formed.

Where SiO ₂ , Na ₂ O, X and Y are weights or weight ratios, [SiO ₂ ], [Na ₂ O], [X], and [Y] are formula weights, X represents potassium hydroxide, and Y represents borax.

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