EA038868B1 - Building construction method - Google Patents

Abstract

A building construction method uses wall frames having a moveable top track. The track is fixed in a raised position so as to be load-bearing during construction, allowing construction work to progress quickly. When supporting concrete columns have cured, the fixing can be released allowing the track to move into a lowered position and for the building load to transfer to the columns.

Description

Technology area

The present invention relates to the construction of buildings. It is conceived as a way of constructing multi-storey buildings, in particular buildings with more than two storeys.

State of the art

In some countries, building codes generally require that the load-bearing walls of a building more than three stories high be made of concrete or masonry. These standards are due to the requirements of fire safety. It is possible to construct a building in which the load will fall on structurally strong steel or timber frames, but the strength of such frames can be significantly weakened by fire.

Brick buildings are usually built gradually from scratch, in rows. Upon completion of a certain level, curing of the grout is required before applying further loads. In practice, this means that it is necessary to wait for the completion of the aging of each floor before proceeding with the construction of the next.

Precast buildings can be built much faster. However, there is still a need for the individual panels to be bonded to each other, usually with a grout. In addition to the initial costs and difficulties of using precast panels (primarily the cost of transporting and moving heavy panels), the use of such panels still involves significant waiting times.

In recent years, a structural formwork system has been widely used in building construction, whereby the walls of a building are laid out using lightweight hollow wall panels, into which concrete is then poured, which is cured there to give structural strength. Although the cost of transporting and moving such panels is significantly less than the cost of using precast concrete panels, this system requires full curing of the concrete in the panels of each level before the next floor is erected on them.

All of the above systems have an additional limitation, in general, that it is required to wait until the load-bearing walls and columns gain strength and, if necessary, will not be sustained before the construction of the internal walls of the structure. Indeed, it is often necessary to complete the entire load-bearing structure of a building before the curtain wall can be erected.

US Patent Application No. 2010/0058687 discloses a structural formwork system as described above in which the formwork partially supports a load placed on top of it. After the concrete columns have cured, the load is distributed to the concrete and structural formwork.

The present invention provides an alternative building system, the purpose of which is to alleviate some of these restrictions, at least in part.

For the avoidance of ambiguity, the term column in the context of this document broadly means vertical structural members, including traditional columns having a relatively uniform length to width ratio, plate columns and plate walls, in which the length can be much greater than the width.

The essence of the invention

According to a first aspect of the present invention, there is provided a method for constructing a building, which includes the following steps:

form the frame of the building, this frame includes many vertical channels, the frame is strong enough to withstand the load of at least one upper floor, the frame defines the load distribution trajectory received from at least one upper floor;

form at least one upper floor;

fill the channels with a curing agent;

provide the ability to hold the hardening substance in the channels and form columns in the building;

interrupt the trajectory of the load distribution on the frame, which makes it possible to transfer the load of at least one upper floor from the frame of the building to the sustained columns.

It should be understood that the load is transferred from the building frame to the sustained columns completely, with none of the final loads falling on the frame.

It should also be understood that the building frame will carry a significant portion of the load on the upper floor, but cannot carry the entire load. In some cases, the present invention provides for the distribution of the entire load of the upper floor between the building frame and some temporary struts. It is understood that the required number and bearing capacity of the temporary struts will be significantly reduced when used in conjunction with the present invention.

The advantage is provided that the construction of the building can be continued while the columns are holding, while the load of the upper floors is borne by the building frame. Upon completion of the building construction, the sustained columns become the load-bearing elements, preferably of the frame, thus meeting the requirements of building codes.

Preferably, the building frame is made of structural steel. In a preferred embodiment, the building frame is made of cold rolled section steel with a nominal thickness of 0.75 to 1.6 mm.

Preferably, concrete is used as the curing agent.

Preferably, this method includes the step of placing the floor formwork on top of the building frame, the channels being adapted to transfer fluid to the floor formwork. The step of filling the channels with curing agent can be performed simultaneously with filling the formwork with curing agent to complete the formation of the floor surface above the building frame.

It is preferred that at least some of the main interior wall frames are installed simultaneously with the installation of the outer wall frames. For example, when building apartments, you can use frames for dividing walls. It is possible to erect walls at the same time on the entire level, although this is not always advisable, since it can make it difficult to check. Using the frames of the inner walls allows you to start arranging the lower floors while the upper ones are being built.

Preferably, the building frame includes vertical posts and horizontal rails. In a preferred embodiment, the building frame includes a load transfer means by attaching one rail, preferably the topmost one, to the uprights with at least one removable fastener. The step of interrupting the load distribution path can be performed by removing the fastener (s).

Alternatively, the building frame may include a head that can be displaced under a load greater than that of one top floor but less than the entire structure at full load. In this embodiment, the interruption of the load distribution path can be accomplished by shifting the head after the columns have been held, which will transfer the vertical loads to the columns rather than to the framing.

According to a second aspect of the present invention, there is provided a wall frame component including uprights and horizontal rails, the uppermost rail of the wall frame is movable between a relatively upper position and a relatively lower position, the wall frame includes removable fasteners that support the uppermost rail in an upper position, removable fasteners allows you to move the topmost rail to the lowest position.

When the uppermost rail is in a relatively upward position, the wall frame component preferably includes a load distribution path transferring the load from the uppermost rail to the uprights by means of at least one removable fastener. It should be understood that removing the fasteners will interrupt the load distribution path.

The topmost rail may include holes in alignment with corresponding holes in the uprights when the topmost rail is in a relatively downward position. Thus, the uppermost rail can be secured in a relatively lower position with fasteners, if necessary.

Brief Description of Drawings

The further description of the invention is more conveniently given with reference to preferred embodiments of the present invention. Possible other options for implementation and, therefore, the particulars of the subsequent discussion should not be taken as replacing the generality of the previous description of the invention. In the drawings:

fig. 1-6 are sequential schematic views of a portion of a multi-storey building under construction in accordance with the present invention;

fig. 7 is a front view of a wall frame component in accordance with the present invention;

fig. 8 is a perspective view of the upper end of the wall framing component of FIG. 7;

fig. 9 is a side view of the upper end of the wall framing component of FIG. 7.

Detailed Description of Preferred Embodiments

FIG. 1 shows a schematic representation of one level of a multi-storey building. This level includes a base plate 10 on which the wall frames 12 are mounted. The wall frames 12, in this embodiment, are arranged to lay out interior and exterior walls on the plate 10.

The wall frames 12 are made of cold-rolled section steel. The nominal wall thickness is about 90 mm. The nominal steel thickness is usually between 0.75 and 1.6 mm.

The wall frames 12 are designed to withstand relatively high vertical loads.

The wall frames 12 are positioned so that the vertical channels 14 can be positioned at the desired intersections. The canals 14 are created with formwork columns 16 positioned at the desired locations, as shown in FIG. 2. Vertical channels 14 usually have a rectangular cross-section and such dimensions that when filled with concrete to form columns, such concrete columns have a higher vertical bearing capacity than the wall frames 12.

After installing the wall frames 12 and the column formwork 16 in the desired position on the top of the wall frames 12, it is possible to install the ceiling formwork 20 using the appropriate reinforcement. The slab formwork 20 is positioned so that the voids in the slab 20 are positioned above the openings that open into the vertical channels 14. Reinforcement rods 22 are installed in the vertical channels 14 protruding from the slab 20. This is shown in FIG. 3. If necessary, you can install additional temporary struts under the ceiling 20.

Concrete is then poured to simultaneously form the columns 24 in the vertical channels 14 and the suspended floor slab 26. The wall frames 12 are strong enough to carry the weight of the suspended floor slab 26 either entirely or using additional temporary struts. This is shown in FIG. 4 and 5.

After the suspended floor slab 26 has dried, the wall frames 12 can be positioned on top of the suspended floor slab 26 to form the next floor of the building. At the same time, you can start work on the engineering support of the building, for example, laying pipes and electrical wiring on the wall frames of the 10th floor. The concrete of the floor slab 26 and the columns 24 will be cured for a long time until it reaches its final strength, but during this period the load will be carried by the wall frames 12. This is shown in FIG. 6.

The above process can be repeated for the next floors.

The wall frames 12 are formed from vertical posts 30 and three horizontal rails: a support rail 32, an intermediate rail 34 and an upper rail 36. This is shown in FIG. from 7 to 9.

Each of the uprights 30 has a lower end 40 and an upper end 42. The uprights are slightly compressed at the lower end 40 to fit into the support rail 32, the support rail 32 and the uprights 30 being approximately the same width. On each lower end 40 of the uprights 30 and in each support rail 32, recessed holes 44 for screws are made. Thus, it is possible to fasten the support rail 32 to the uprights 30 with screws 46, which are actually recessed to form a sufficiently flat surface of the wall frame 12.

The outer ends of the intermediate rail 34 are compressed so that it can be installed in the vertical posts 30. The design is such that the outer side of the intermediate support 34 is predominantly in the same plane with the outer side of the vertical posts 30.

In the central part of each upright 30, screw holes 44 are recessed, just like on the outer ends of the intermediate rail 34. In the same way as in the case of the support rail, the intermediate rail 34 can be attached to the uprights 30 using screws 46, which are actually recessed, forming a fairly flat surface of the wall frame 12.

The upper rail 36 and its connection to the upper end 42 of the uprights 30 is largely a mirror image of such a connection of the support rail 32. The uprights are slightly compressed at the upper end 42 so that they can be fitted into the upper rail 36, while the upper rail 36 and the upright posts 30 are of approximately the same width. At each upper end 42 of the uprights 30 and in each upper rail 36, recessed screw holes 44 are provided. In this way, the upper rail 36 can be secured to the uprights 30 with the actually recessed screws.

The structure of the upper rail 36 differs from the structure of the support rail 32 by the presence of fastening screws 50.

The arrangement in which the screw holes 44 of the upper end 42 of the uprights 30 are in line with the holes of the upper rail 36 represents a relatively lower position of the upper rail 36. During use, the upper rail 36 is held in a relatively upward position while the upper rail 36 is secured to the uprights in this relatively upper position using the fastening screws 50.

In practice, the wall frames 12, as described above, are assembled with the upper rail 36 held in the upper position by the fastening screws 50. This means that the weight of the suspended floor slab 26 passes from the upper rail 36 onto the uprights 30 through the fastening screws 50. Thus, the suspension the floor slab 26 is supported by the wall frames 12. The wall frames 12 thus guide the load distribution path through the upper rail 36, the fastening screws 50 and the uprights 30 onto the slab 10.

Once the columns 24 have been cured, the fastening screws 50 can be removed. Removing the fixing screws 50 allows the upper rail 36 to move between a relatively high and low position with respect to the plate 26. When the fixing screws 50 are removed, the vertical load of the plate 26 (and the upper floors) is taken up by the columns 24, while the wall frames 12 no longer bear the load. Thus, the removal of the fixing screws 50 interrupts the load distribution path specified above.

- 3 038868

This means that in fact the wall frames 12 bear the load during the construction of the building, allowing for an unusually high rate of construction. Upon completion of construction, they cease to be load-bearing elements, while the load is transferred to the concrete elements in accordance with the requirements of building codes.

It should be understood that this reflects the complete transfer of load from the wall frames 12 to the columns 24.

In an alternative embodiment, the fastening screws 50 can be made to displace under a certain load, for example under the load of the two upper stories. Displacement of the fixing screws 50 will serve the same purpose of transferring the load from the wall frames 12.

It should be understood that the column formwork 16 may be non-load bearing. Alternatively, the column formwork 16 can be assembled in a manner similar to the wall frames 12 and be part of the load-bearing capacity of the wall frames 12 before the load is transferred.

It will be apparent to those skilled in the art that modifications and variations of the invention are possible within the scope of the present invention.

Claims (11)

CLAIM 1. A method of building a building, this method includes the following steps: form the frame of the building, this frame includes many vertical channels, the frame of the building includes vertical posts and horizontal rails, the frame is strong enough to withstand the load of at least one upper floor, the frame defines the load distribution trajectory obtained from at least one upper floor; at least partially form one upper floor; fill the channels with a curing agent; provide the ability to hold the hardening substance in the channels and form columns in the building; they interrupt the trajectory of the load distribution on the frame, which makes it possible to transfer the load of at least one upper floor from the frame of the building to the sustained columns; wherein the building includes a load redistribution means created by attaching at least one said horizontal rail to at least one said vertical post using at least one removable fastening element. 2. The method of building a building according to claim 1, according to which the building frame is made of structural steel. 3. The method of building a building according to claim 2, according to which the building frame is made of cold-rolled profile steel with a nominal thickness of 0.75 to 1.6 mm. 4. The method of building a building according to any of the preceding claims, according to which concrete is used as the curing agent. 5. The method of building a building according to any of the preceding claims, according to which the method comprises the step of installing the floor formwork on the top of the building frame, wherein the channels are configured to transfer fluid to the floor formwork. 6. The method of building a building according to claim 5, wherein the step of filling the channels with a curing agent is performed simultaneously with filling said floor formwork with a curing agent to complete the formation of the floor surface above the building frame. 7. The method of building a building according to any of the preceding claims, according to which at least some of the inner wall frames are installed simultaneously with the installation of the outer wall frames. 8. The method of constructing a building according to any of the preceding claims, wherein the uppermost rail is attached to the uprights with at least one fastening element. 9. The method of constructing a building according to any one of the preceding claims, wherein the step of interrupting the load distribution path is performed by removing the fastener (s). 10. A method of building a building, this method includes the following steps: form the frame of the building, this frame includes many vertical channels, the frame of the building includes vertical posts and horizontal rails, the frame is strong enough to withstand the load of at least one upper floor, the frame defines the load distribution trajectory obtained from at least one upper floor; at least partially form one upper floor; fill the channels with a curing agent; provide the ability to hold the hardening substance in the channels and form columns in the building; interrupt the trajectory of the load distribution on the frame, which makes it possible to transfer the load of at least one upper floor from the building frame to the sustained columns, and the building frame includes a head made with the ability to move under a load exceeding the load - 4 038868 of one upper floor, but less than the entire structure at full load. 11. The method of building a building according to claim 10, according to which the interruption of the load distribution path is carried out by shifting the head after holding the columns, which leads to the transfer of vertical loads to the columns, and not to the frame.