JPH04176950A - Fire resistant covering material - Google Patents

Abstract

PURPOSE:To improve performance by a pointing method by producing an additive by using water, rock wool and Portland cement, gypsum plaster specifying a mixture ratio and a setting starting time, and sodium silicate specifying a mixture ratio. CONSTITUTION:A hydraulic inorganic adhesive consisting of Portland cement and 100-300wt.pts., based on 100wt.pts. Portland cement, gypsum plaster having a coagulation time of 10-50 minutes is provided. A fire resisting covering material consisting mainly of rock wool, the adhesive, and water and prepared by mixing them together is provided. 3-5wt.% powder sodium silicate per a total solid content is added where necessary and initial fluidity necessary to a forced feed by a pump is ensured. The mixture is sprayed against each steel frame member and after it is cured in a short time, the steel frames are assembled together. This constitution provides early strength necessary to pointing and holds enough initial fluid and fire resistance.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a wet-sprayed fire-resistant coating material for forming fire-resistant coatings on beams, columns, etc. of various steel buildings.

[Prior Art] It is widely practiced to apply fire-resistant coatings to the steel frames of various buildings by spraying methods. The coating material used for this purpose is one that can be applied by wet spraying, in which a paste is prepared by mixing raw materials with water in advance, and there is no environmental deterioration due to the scattering of dust.
It is advantageous because it has good workability.

A typical example of fireproof coating material for wet spraying is
It is described in Japanese Patent No. 24973, and its composition is as follows.

Rock wool 20-75% by weight Hydraulic inorganic adhesive 25-60 Surfactant
0.1~1.0〃Thickener
0, 1-1.0 // In addition, lightweight aggregates such as vermiculite and perlite may be blended for the purpose of weight reduction.

Hydraulic inorganic adhesives include portland cement, alumina cement, blast furnace cement, gypsum, gypsum plaster (
JIS A6904) etc. are used.

These conventional fire-resistant coatings are typically sprayed onto the steel surface of a building after the steel frame has been erected, and then hardened over approximately 24 hours.

On the other hand, in the vicinity of factories or construction sites, a fireproof coating pre-installation method has been developed in recent years, in which a fireproof coating is applied to the surface of the steel frame before assembly, and the assembly is performed using the steel frame that has been treated with the fireproof coating (for example, No. 98841), the benefits of reducing work at heights and shortening the construction period are attracting attention.

However, in the case of the pre-applied fireproof coating method, it is not possible to spend too much time curing the coating material in a narrow workshop after spraying, and it is desirable to be able to transport and assemble it quickly. It is necessary that the material develops high adhesion strength and surface strength in around 3 hours and can form a fireproof coating that can withstand handling during transportation and assembly. However, conventional wet-sprayed fireproof coatings, which were made with the assumption that they would be sprayed after steel frame assembly, cured too slowly to be used in pre-applied fireproof coating methods. Unable to make full use of its features.

When using cement as a hydraulic inorganic adhesive, attempts to speed up the curing after spraying by changing the cement to a rapid curing type or using a cement curing accelerator together have not yet succeeded. This is because gypsum used in combination with cement delays the hardening of cement, so the hardening time cannot be shortened as easily as with cement alone (cement alone lacks the initial adhesion to the steel frame, The edge workability is also poor, and the drying shrinkage rate is large, making it easy for cracks to occur in the coating layer.

The combined use of plaster is effective in solving these problems. ).

Needless to say, it is not enough just to cure quickly after spraying, but after mixing the spraying material with water, it is necessary to ensure fluidity retention time of at least 30 minutes before spraying by pumping. In addition, adjustment to suitable curing characteristics must be achieved without deteriorating the performance required as a fire-resistant coating material, but this has also been a problem that cannot be easily solved.

[Problem to be solved by the invention]

Therefore, the present invention aims to provide a fire-resistant coating material that has physical properties and hardening properties suitable for the pre-installation method and is also excellent in terms of the performance of the fire-resistant coating that is ultimately formed. It attempts to make it possible.

[Means to solve the problem]

The fire-resistant coating material provided by the present invention that achieves the above object is a fire-resistant coating material for wet spraying mainly composed of rock wool, a hydraulic inorganic adhesive, and water.
It is characterized in that, as an adhesive, Portland cement and gypsum plaster of 100 to 300 parts by weight per 100 parts by weight of the Portland cement and whose initial setting time is adjusted to 10 to 50 minutes are used together.

By employing a hydraulic inorganic adhesive having the composition as described above, the fireproof coating material of the present invention has optimal curing characteristics for pre-applied construction methods, and exhibits sufficient performance in terms of spray workability and fire resistance.

The most characteristic component of the fireproof coating material of the present invention is gypsum plaster whose initial setting time is adjusted to 10 to 50 minutes. The gypsum-based materials used in known fireproof covering materials are either calcined gypsum, which starts hardening immediately when mixed with water, or gypsum plaster for plastering (JIS), which starts setting for more than 1 hour.
A6904; Main raw material is calcined gypsum, with admixtures,
thickeners, setting retarders, etc.). J
Gypsum plasters that do not meet IS standards and have a setting time of 10 to 50 minutes are not commonly commercially available. However, in this type of gypsum plaster, the blending ratio of auxiliary agents such as setting retarders is adjusted so that the setting start time is slightly faster than that of ordinary gypsum plaster, and the composition of such gypsum plaster is particularly different from that of ordinary gypsum plaster. It's not different. By using early-setting gypsum plaster in an amount equal to or greater than that of Portland cement, the setting properties of the entire fireproof coating become largely dependent on the setting properties and blending ratio of the gypsum plaster.

Ordinary Portland cement is used as the Portland cement.

In the present invention, the hydraulic inorganic adhesive can further contain sodium silicate. Sodium silicate does not significantly affect the initial setting of the fireproof coating, but it helps develop strength in a short period of time after setting. The sodium silicate used may be in the form of a solution or powder, but powdered sodium silicate is easier to mix with other materials, and when kneaded by adding water after mixing. Since it gradually melts and accelerates hardening, it is advantageous in securing the initial fluidity necessary for pumping. The preferred blending amount is 3 to 5% by weight based on the total solid content (in terms of powdered sodium silicate No. 3).

These components are used in combination at the above-mentioned ratio, but since the coagulation properties after mixing with water are considerably affected by temperature, it is desirable to determine the optimum blending ratio based on the results of preliminary experiments at the operating temperature. This ensures the necessary fluidity for spraying after mixing with water and other fireproofing components such as Quul for at least 30 minutes, while providing strength to withstand normal handling of the steel assembly after approximately 3 hours. can be expressed.

Except that the hydraulic inorganic adhesive is composed of the above-mentioned components, the types and compounding ratios of the other constituent components of the fireproof coating material of the present invention are not particularly limited. As with the material, it can be selected arbitrarily. However, the following are particularly preferable constituent components of the fireproof coating material to be combined with the above-mentioned inorganic adhesive specified by the present invention (the numerical values are weight % based on the total solid content).

Rock wool 20-30% surfactant (foaming agent) 0.1-0.3% thickener
0.3-0.5% water
110 to 130% The fireproof coating material of the present invention can be sprayed onto the surface of a steel frame before assembly by a conventional wet spraying method after kneading all components including water into a slurry.

The fireproof coating material of the present invention is most suitable for use in the fireproof coating pre-applying method, but its use is not limited thereto. For example, if the sprayed material is not pumped over long distances, the early setting does not pose an obstacle to the spraying operation, so it can also be used in the post-installation method of fireproof coating.

[Example] The present invention will be described below with reference to Examples. In 6 examples, the setting and hardening characteristics were tested by measuring the needle penetration according to JISR 2506r Refractory Mortar Consistency Test Method. In this test, the needle penetration after 30 minutes must be approximately 20 m1 or more to ensure the fluidity necessary for pumping, and if the needle penetration is 31 or less, it is necessary to handle the steel frame assembly. It can be said that it has developed the strength to withstand.

Examples 1 to 3 Fireproof coating slurries were prepared using various raw material formulations and temperature conditions, and their setting characteristics were investigated. The results are shown in Table 1.

Comparative Examples 1 to 5 Fireproof coating slurries were prepared in the same manner as Examples 1 to 3, except that the raw material formulations were changed as shown in Table 2, and their setting and hardening characteristics were examined. The temperature was 25° C., and only in Comparative Example 2, ultra-early strength cement jet cement (manufactured by Onoda Cement Co., Ltd.) was used instead of Portland cement.

The results are also shown in Table 2.

Table 1 Table 2 [Effects of the Invention] As mentioned above, the fireproof coating material of the present invention has excellent early strength development required for the pre-installation method, as well as sufficient initial fluidity and fire resistance performance. By using this method, it is possible to form fireproof coatings efficiently and safely by taking advantage of the features of the pre-applied fireproof coating method more than ever before.

Claims (3)

[Claims] (1) In a wet-sprayed fireproof coating material mainly composed of rock wool, a hydraulic inorganic adhesive, and water, the hydraulic inorganic adhesive is set in Portland cement and in an amount of 100 to 300 parts by weight per 100 parts by weight of the Portland cement. A fireproof covering material comprising gypsum plaster whose starting time is adjusted to 10 to 50 minutes. (2) The fireproof coating material according to claim 1, wherein the hydraulic inorganic adhesive further contains sodium silicate. (3) The fireproof coating material according to claim 2, containing 3 to 5% by weight of powdered sodium silicate based on the total solid content.