Manufacturing process of fireproof and explosion-proof door

A production process and technology for explosion-proof doors, applied in the field of fire doors, can solve problems such as deformation, difficulty in opening fire doors, heavy weight, etc., and achieve the effects of reducing weight, good buffering and absorbing impact force, and light weight.

Inactive Publication Date: 2020-12-11
河南省双安实业有限公司
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Problems solved by technology

[0004] However, most of the current explosion-proof panels are made of steel plates, relying on high-strength materials to resist the impact force. This kind of steel explosion-proof panels is heavy and prone to deformation after encountering fire. It is easy to cause difficulty in opening the fire door in case of fire.

Method used

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  • Manufacturing process of fireproof and explosion-proof door

Examples

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Comparison scheme
Effect test

Embodiment 1

[0058] The manufacturing process of the fireproof and explosion-proof door of the present embodiment comprises the following steps:

[0059] 1) Stir and mix 15kg tetramethoxysilane, 80kg ethanol solution, and 3kg water evenly, then add 1.5kg hydrofluoric acid with a mass fraction of 45%, and stir for 20 minutes to prepare a sol material;

[0060] Aging the prepared sol material for 24 hours to obtain a gel material;

[0061] Put the prepared gel into an autoclave, use ethanol as the drying medium, and perform supercritical drying at 245°C and 8 MPa to obtain silica airgel; cool and pulverize to obtain silica airgel powder;

[0062] Stir and mix the perlite and urea-formaldehyde resin glue evenly, then add them to the plate mold, pressurize to 5 MPa and hold the pressure for 15 minutes, and demould to obtain a plate-shaped core material; the mass ratio of perlite and urea-formaldehyde resin glue is 80:35.

[0063] 2) Process the wooden door frame. The wooden door frame include...

Embodiment 2

[0070] The manufacturing process of the fireproof and explosion-proof door of the present embodiment comprises the following steps:

[0071] 1) Stir and mix 10kg of methyltrimethoxysilane, 50kg of ethanol solution, and 1kg of water evenly, then add 1.5kg of hydrofluoric acid with a mass fraction of 40%, stir for 10min, adjust the pH to 7 with ammonia water, and obtain a sol material ;

[0072] Mix the obtained sol material with 3.5kg of aluminum silicate fiber evenly, then leave it to age for 12 hours to obtain a gel mixture;

[0073] Add the prepared gel mixture into the mold, press to obtain a thin plate-shaped material with a thickness of about 0.5cm, then put the thin plate-shaped material into an autoclave, use ethanol as the drying medium, and perform supercritical drying at 260°C and 6MPa. Cooling to obtain a silica airgel composite flame retardant material;

[0074] Stir and mix perlite, magnesium oxide, magnesium sulfate, and water glass according to the mass ratio ...

Embodiment 3

[0082] The manufacturing process of the fireproof and explosion-proof door of the present embodiment comprises the following steps:

[0083] 1) Stir and mix 15kg ethyltriethoxysilane, 75kg ethanol solution, and 2kg water evenly, then add 2kg hydrofluoric acid with a mass fraction of 40%, stir and react for 15min, adjust the pH to 8 with ammonia water, and obtain a sol material ;

[0084] Mix the prepared sol material with 5kg of zirconia fibers evenly, then let it stand for aging for 8h to obtain a gel mixture;

[0085] Put the prepared gel mixture into the mold and press to obtain a thin plate-shaped material with a thickness of about 0.5cm, then put the thin plate-shaped material into an autoclave, use ethanol as the drying medium, and perform supercritical drying at 250°C and 6MPa. Cooling to obtain a silica airgel composite flame retardant material;

[0086] Stir and mix perlite, magnesium oxide, magnesium sulfate, zinc borate, and water glass according to the mass ratio...

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Abstract

The invention relates to a manufacturing process of a fireproof and explosion-proof door, and belongs to the technical field of fireproof doors. The manufacturing process of the fireproof and explosion-proof door comprises the following steps that (1) a wooden door framework is impregnated in flame-retardant impregnation liquid, taken out and dried, and an impregnated door framework is manufactured; (2) a fireproof plate layer is bonded to one side of the impregnated door framework, a filling space is defined by the corresponding surfaces of the impregnated door framework and the fireproof plate layer, then a flame-retardant material is arranged in the filling space, a first flame-retardant layer is formed, a core material is arranged on the first flame-retardant layer, a core layer is formed, then the flame-retardant material is arranged on the core layer, and a second flame-retardant layer is formed; then a fireproof plate layer is bonded to the other side of the impregnated door framework; wherein the core material comprises perlite, and the flame-retardant material comprises silicon dioxide aerogel; and (3) flame-retardant density plates are bonded on the outer surfaces of thefireproof plate layers on the two sides of the impregnated door framework, and pressing is conducted to obtain the fireproof and explosion-proof door. The fireproof and explosion-proof door prepared by the manufacturing process is less in weight and has good fireproof and explosion-proof performance.

Description

technical field [0001] The present application relates to the technical field of fire doors, in particular to a manufacturing process of fire and explosion-proof doors. Background technique [0002] In recent years, with the improvement of fire protection standards for high-rise buildings, fire doors have become more and more widely used in buildings. Fire doors are doors that can meet the requirements of fire resistance stability, integrity and heat insulation within a certain period of time. They are mainly used for firewall openings in building fire compartments, stairwell entrances and exits, evacuation walkways, pipe wellheads, etc., and are usually used for personnel passage. , in the event of a fire, it can prevent the flame from spreading. Since different application fields have different performance requirements for fire doors, various functional fire doors have appeared on the market, such as fire doors with explosion-proof performance, which can reduce the damage...

Claims

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Application Information

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Patent Type & Authority Applications(China)
IPC IPC(8): E06B5/16E06B5/12E06B3/70B27K5/04B27K3/32B27K3/16B27K3/26B32B9/00B32B9/04B32B3/08B32B37/02B32B37/10B32B38/08B32B38/16B32B33/00B32B21/14B32B21/04
CPCE06B5/16E06B5/12E06B3/7015B27K5/04B27K3/32B27K3/166B27K3/26B32B5/18B32B5/02B32B5/08B32B9/00B32B9/04B32B3/08B32B37/02B32B37/10B32B38/08B32B38/164B32B33/00B32B21/14B32B21/04E06B2003/7028E06B2003/7042B32B2260/026B32B2264/12B32B2264/10B32B2264/102B32B2262/14B32B2262/10B32B2307/3065B32B2307/734B32B2479/00
Inventor 刘江涛史荷琴邵明军
Owner 河南省双安实业有限公司
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