TH20114B - The wall part and method of its construction - Google Patents

Abstract

DC60 (20/02/41) The process for creating walls, floors or ceilings at construction sites. The process of constructing a rigid frame (10) is essential and the bonding of cement panels is achieved. Fiber reinforcement (50) against the front and back surfaces of the frame to create a gap (60) between there.This gap (60) is then filled with light aggregate concrete slurry. And was left to solidify The sheets will be adjusted to absorb adequate moisture from the Total mass slurry Light to provide a natural bonding of slurry concrete to the slab. Without a significant loss of its structural integrity during Formwork and solidification of slurry concrete, processes for the construction of walls, floors or ceilings in construction. The process of constructing a rigid frame (10) is essential and the bonding of cement panels is achieved. Fiber reinforcement (50) against the front and back surfaces of the frame to create a gap (60) between there.This gap (60) is then filled with light aggregate concrete slurry. And was left to solidify The sheets will be adjusted to absorb adequate moisture from the Total mass slurry Light to provide a natural adhesion of Slurry concrete with slabs Without a significant loss of its structural integrity during Formation and hardening of slurry concrete

Claims (1)

1. Methodology for building walls, floors or ceilings in a construction site where such methodology Combined with the procedure of Setting the frame is quite stiff. It defines the front and rear surfaces of walls, floors or ceilings. Attaching fiber-reinforced cement panels to such front and rear surfaces, to form a channel. Free in between Sery injection of light aggregate concrete with density. Between approximately 200 kg / m 3 and 1800 kg / m 3 enters such a gap; And allowing the slurry of concrete to form and curing By which the said sheet Will absorb moisture at a rate of approximately 0.2 mm / h to provide The slurry natural adhesion of such concrete to the slabs Rather without Loss of its structural unity during its formation and curing 2. Methodology of constructing walls, floors or ceilings at construction sites as claimed in claim No. 1, where the gap Would rather 3. The method for constructing walls, floors or ceilings in the construction site is as requested in Clause 1, where the gaps are filled at the stage. when By replenishing the gap with a slurry of concrete. 4. The method of constructing walls, floors or ceilings at the construction site, as requested in claim No. 1, where the frame is: It is constructed using a metal frame. 5. Method for constructing walls, floors or ceilings in the construction site as claimed in Clause 4, whereby the frame structure is One of the box section, "C" section, "Z" cross-section, or "I" cross-section. 6. Methodology for constructing walls, floors or ceilings at construction sites, as requested. In claim No. 4, where the location of the frame Include a number of parallel spaced wings connected by thin plates, so that in use they are somewhat sticking together. And parallel to the plate facing to the side Front or back, respectively 7. Procedures as requested in Clause 1 where the reinforced cement panels are tightened in the way 8. Methodology as requested in Clause 1 where the reinforced cement sheets are screwed. 9. Methods for constructing walls, floors or ceilings in the construction site as requested in Clause 1, whereby slurry of such lightweight concrete Including the moisture content of not more than approximately 50% of the water 1 0. Methods for constructing walls, floors or ceilings at construction sites as requested in Claim No. 1, where slurry of concrete is included. With materials selected from the group This includes foam generators, air carriers, lightweight aggregates, and any combination of materials. Previous 1 1. Methods for constructing walls, floors or ceilings at construction sites, as requested by the clause herein. Holds the right number 1, whereby the small aggregates said There is a specified density between approximately 400 kg / m 3 and 500 kg / m 3 1 2. Methodology for the construction of walls, floors or ceilings at the construction site as requested in Clause 1, where Each cubic meter of slurry of lightweight concrete This includes approximately 120 kg of cement, approximately 160 kg of coal ash, approximately 1 m3 of expanded polystyrene lumps, approximately 4 liters of air-entrainment, and approximately 150 liters of water. . Methodology as requested in Claim No. 1, where the slurry of lightweight aggregate concrete It consists of 50-70% by volume of nodules of 20-40% expanded polystyrene, 5-15% sand, 5-15% water and 0-20% coal ash, crushed slag. Fine or material Other Fine Silicon 1 4. Methods for constructing walls, floors or ceilings at construction sites as requested in Clause 1, whereby the panels are constructed of low-density fiber-reinforced cement. Thickness From between 800 kg / m 3 and 1200 kg / m 3 1. 5. Methods for constructing walls, floors or ceilings in the construction site as requested in claim No. 1, provided that the panels are Constructed from low moisture permeable panels 1 6. Walls constructed in accordance with the Methodology Clause 1 1. 7. Methods for constructing walls, floors or ceilings at the construction site as requested. It holds the right to claim No. 1, where the sheets will absorb moisture at a rate of between 0.5 and 1 mm per hour 1 8. Methodology for building walls, floors or ceilings at construction sites as requested. Claim No. 1, where the panels will absorb moisture at a rate of between 0.2 and 0.5 mm per hour 1 9. Methods for constructing walls, floors or ceilings at the construction site. Holds the right to Clause 1 where the aforementioned sheet has a thickness of approximately 6 mm. Or more 2 0. Methodology for building walls, floors or ceilings in the construction as requested in Clause 1, where The sheets have a density between 800 kg / m 3 and 1200 kg / m 2. 1. Methodology for constructing walls, floors or ceilings at construction sites as requested in Claim No. 1, provided that the panels have a density between 800 and 900 kg / m 3.