JP2019526004A - Precast concrete formwork, floor system, and construction method - Google Patents

Abstract

A formwork for constructing a floor system in a building, a plurality of precast concrete joists positioned in a substantially parallel arrangement, one or more of the joists comprising a horizontal base, An upward directing portion extending substantially along the length of the joist, the upward directing portion having a spaced surface extending upward from the base, and the individual ledges of the base being upward A plurality of precast concrete joists located adjacent to the directing section, a plurality of precast concrete members for extending along the length of the joists to receive ready-mixed concrete, and two adjacent joists facing each other And a support arrangement for supporting each end portion of the precast concrete member on the shelf arranged in order.

Description

  The present invention relates to the field of architecture, and more particularly to floor systems and associated methods of forming floor systems.

  Any reference to prior art methods, devices, or documents should not be construed as constituting evidence or approval that they were formed, or as part of common general knowledge. Should not.

  Suspended floor systems with precast components have gained popularity for both residential and commercial construction projects. Formwork is a structural component that is used temporarily during the construction phase and plays an important role in the concrete construction industry. Improper design of the formwork can result in partial or complete crushing of the building during construction and / or excessive cracking and deformation in the operational phase. Furthermore, improper stiffness of the formwork affects the surface finish of the concrete structure. Thus, the hard formwork provides a flatter and smoother finish.

  The shape of the formwork is also influenced by the shape of the final structural element. Hence, mold preparation and assembly can be a time consuming and expensive process. Since the minimization of the use of the formwork can increase the safety of construction personnel and increase the speed of construction while also reducing the costs associated with it, the elimination of the formwork preparation and assembly steps is also possible. Very desirable.

  Depending on the slab type, steel or wood formwork was previously used. In some cases, precast concrete slabs were used when formwork struts were not possible.

  One commonly used floor system with precast concrete slabs comprises joists and blocks. The joists are mostly installed with gaps ranging from 400 to 600 mm. The gap between the joists is filled with concrete or other types of stone blocks, and the joists and blocks are then covered by a concrete concrete overlay of 60-120 mm thickness. The system acts as a unidirectional ribbed slab. Such floor systems use a simple construction method, but can be time consuming and not suitable for use in long spans, and typically result in a thick floor system.

  Another commonly used floor system is known as a composite floor system. Composite floors are mostly used in conjunction with steel structures. The distance between the beams used in these systems varies from 900 mm to 3,000 mm with an economic distance of about 1,200 mm to 2,400 mm. Steel beams used in these systems must be fire graded to meet the relevant building code requirements that make these floor systems expensive. In addition, a shear stud must be attached to the upper flange of the beam to form an appropriate connection between the concrete slab and the supporting steel beam. The process of installing such a composite floor system can be time consuming and requires on-site welding, and the integrity of the system depends on the strength of the shear stud and its connection to the steel beam.

  Yet another floor system is known as a waffle slab system. The waffle slab system includes a bi-directional slab made from a GRP (fiberglass) mold. The system contains an integrated joist that extends in both directions. The distance between the joists varies in the range of 600 mm to 1,200 mm. Although a waffle slab system is suitable for covering long spans, the system is not economical for use in large constructions. The construction of a waffle-type slab system can also take time.

  There is a need to provide an improved floor system that overcomes the deficiencies of the prior art floor systems.

In a first aspect, the invention is a formwork for building a floor system in a building,
A plurality of precast concrete joists positioned in a substantially parallel arrangement, wherein one or more of the joists include a horizontal base and an upward directing portion that extends substantially along the length of the joists. The upward directing portion has a spaced apart surface extending upward from the base, the individual shelves of the base being adjacent to the upward directing portion, a plurality of precast concrete joists,
A plurality of precast concrete members for extending along the length of the joists to receive ready-mixed concrete;
A support arrangement for supporting each end of each precast concrete member on oppositely arranged shelves of two adjacent joists;
A formwork is provided.

  In one embodiment, one or more of the precast concrete members comprises a shell for receiving ready-mixed concrete, the shell on a shelf that is arranged oppositely of two adjacent joists. Adapted to be coupled with a separate downward pointing support for supporting the

  In some embodiments, the support is integrally formed using a precast member.

  In an alternative embodiment, each precast support comprises a lower portion in use to be positioned on a separate shelf and an upper portion in use to be coupled to the lateral ends of the precast members.

  In certain embodiments, the support is adapted to extend along the length of the joist.

  In one embodiment, the outer surface of the precast concrete member combined with the upwardly directed surface of the support joists located at both ends defines a receiving portion in use for receiving ready-mixed concrete.

  In certain embodiments, the precast concrete member comprises an edge extending along the length of the precast concrete member, and preferably at least the first edge extends along the first side of the precast concrete member. And at least the second edge extends along the second side of the precast concrete member.

In some embodiments, one or more of the precast concrete members are
A saucer for receiving ready-mixed concrete;
Shoulders located at opposite ends of the saucer, the shoulders adapted to be supported on oppositely arranged shelves of two adjacent joists; and
Is provided.

  In one embodiment, a pan that is combined with the surface of the upward directing portion of the support joist located at both ends defines an in-use receptacle for receiving ready-mixed concrete.

  In some embodiments, the precast concrete joists are supported by a plurality of beams extending in a direction substantially perpendicular to the general direction of the precast concrete joists.

  In certain embodiments, the beam comprises a beam portion with a generally flat profile with two spaced apart shapes extending upward from the beam portion, the shape extending along the length of the beam. The joist receiving portion extends outward from the molded product for supporting the ends of the joists.

  In one embodiment, the plurality of outwardly projecting ends of the joists are supported on the joists receiving portions of the beam, and the joists receiving portions of the beams preferably extend in a direction perpendicular to the projecting ends of the joists. Exists.

  In some embodiments, the lower bottom surface of the beam is substantially in the same plane as the bottom surface of the joists.

In some embodiments, the formwork is
A first connection mechanism for connecting a first joist located on the first side of the beam to a second joist located on the second side of the beam, the connection mechanism preferably A first connection mechanism further adapted to apply a negative bending force to the first and second joists during use;
A second connection mechanism for connecting two adjacent beams simultaneously supported on a columnar object, wherein the connector applies a negative bending force to the adjacent beams. A second connection mechanism provided;
Is further provided.

  In some embodiments, the formwork further comprises a columnar formwork member for forming a columnar body for supporting the beam, each of the columnar formwork members being interconnected and receiving ready-mixed concrete. The hollow portion can be defined.

  In one embodiment, each end of the columnar formwork member has a second columnar formwork in which the virtual plane of the first columnar formwork member is interconnected with the first columnar formwork member. A connection part for interconnecting the columnar object form frame members is provided so as to be arranged in a lateral direction with respect to the virtual plane of the member.

  In one embodiment, the locking portion is in a columnar shape such that, in an interconnected configuration, the locking member is adapted to be received within a recess in another of the columnar formwork. It extends along the vertical edge of the frame member, and the recess extends along the vertical edge of the other columnar frame.

  In certain embodiments, the formwork further comprises one or more drive formwork members for positioning between two spaced joists, preferably the drive formwork members are generally L-shaped or U-shaped. With a cross section.

  In some embodiments, the formwork joists further comprise one or more openings for receiving the reinforcing bars, the reinforcing bars extending transverse to the general direction of the joists, and the reinforcing bars are It is adapted to apply pressure (using post-tensioning) after pouring the concrete into the precast concrete receiving member.

  In another aspect, the present invention provides a precast concrete joist, wherein the precast concrete joist is a horizontal base and an upward directing portion that extends substantially along the length of the joist, the upward directing The base has a spaced apart surface extending upwardly from the base, the base shelf is located adjacent to the upward directing portion, and the shelf is respectively a precast concrete pan member or a precast concrete shell member. A seat for receiving the connecting portion is defined, and the upward directing portion has an upward directing portion whose height is equal to or higher than the vertical height of the shelf.

  In yet another aspect, the present invention provides a precast concrete member to be positioned and supported between spaced joists or beams, wherein the precast member is a length of joists or beams for receiving ready-mixed concrete. Extending along the length, the precast member comprises a support arrangement and supports respective ends of the precast concrete member on oppositely arranged joists or beams.

In another aspect, the present invention provides a method for constructing a suspended floor in a building, the method comprising:
Positioning a plurality of precast concrete joists in a substantially parallel arrangement, wherein one or more of the joists include a horizontal base and an upward directing portion extending substantially along the length of the joists The upward pointing portion has a spaced surface extending upward from the base, and the base shelf is located adjacent to the vertical portion; and
Positioning a plurality of precast concrete members between adjacent joists, wherein the precast concrete members are positioned to extend along the length of the joists to receive the tilted concrete; Steps,
Supporting each end of each precast concrete member on oppositely arranged shelves of two adjacent joists;
Decanting the ready-mixed concrete into a receptacle defined by the precast concrete member;
including.

In at least some embodiments, the present invention also includes joists, infill thin shells, beams, pillars designed to eliminate or minimize the use of formwork and struts in concrete structures. A modular precast concrete formwork (MPCF) including walls. The MPCF, along with its own weight, is designed to withstand construction-related loads prior to on-site concrete work. After installation, additional reinforcing bars (if required) are installed across the MPCF. A concrete top with a nominal thickness of up to 70 mm is then installed over the MPCF to produce the final one-way or two-way floor system. MPCF is considered a driven formwork that will be integrated and become part of the final floor system and will bring the following superior benefits to the construction industry:
・ High quality bottom finish.
One of the few site concrete construction than - (in the traditional way, 1m ^{3 is} not only to cover the floor area of 3m ² ~6m 2, in the present ^invention, covering a floor area of 11.5m ² ~14m 2.)
• Fewer field reinforcements (usually a single reinforcement mesh is sufficient for long spans).
・ No additional formwork is required.
• Less struts (no struts required for medium span joists on large span floors, or medium to small span floors).
• The edge beam will be equipped with appropriate connections for temporary suspension scaffold platform mounting. Therefore, there is no need for a complete scaffold system.
The use of the present invention provides better usage limits in the final floor system.
• The present invention is considered to satisfy a fire rating of at least 2 hours.
• Rapid increase in construction speed and reduction in construction costs.

  Preferred features, embodiments, and variations of the invention can be determined from the following detailed description, which provides those skilled in the art with sufficient information to practice the invention. The detailed description is considered not to limit in any way the scope of the summary of the immediately preceding invention. The detailed description will refer to the several drawings as follows.

FIG. 1 is a perspective view of a one-way floor system 400 and a two-way floor system 400 'used in a building 1000 according to first and second embodiments of the present invention. FIG. 2A is a perspective view of a precast concrete member in the form of a plank member 100 according to an embodiment of the present invention. FIG. 2B is a right sectional view of the thick plate member 100. FIG. 2C is a cross-sectional view of a second embodiment of a plank member 100 '. FIG. 2D is a cross-sectional view of a third embodiment of a plank member 100 ″. FIG. 2E is a perspective view of the stepped plank unit 100 ″ ″. FIG. 3 is a cross-sectional view of the thick plate member 100 having an indefinite length during use. FIG. 4 is a cross-sectional view of a plank support member 110 'according to an embodiment of the present invention. FIG. 5A is a cross-sectional view during use of a plank member 100 ″ supported on a support member 110 ′. FIG. 5B is a perspective view of the plank member 100 ″ supported on the support member 110 ′ located at one side end of the plank member 100 ″. FIG. 6A is a perspective view of a precast joist 140 according to an embodiment of the present invention. FIG. 6B is a cross-sectional view of the precast joist 140. FIG. 6C is a cross-sectional view of an alternative embodiment of precast joist 140 '. FIG. 7 is a cross-sectional view of a two-way floor system 400 ″ according to an embodiment of the present invention. FIG. 8A is a U-shaped drive formwork member 120 'according to an embodiment of the present invention. FIG. 8B is a cross-sectional view of a U-shaped driving form member 120 '. FIG. 9A is an L-shaped drive formwork member 120 according to an embodiment of the present invention. FIG. 9B is a cross-sectional view of the L-shaped driving form member 120. FIG. 10A is a perspective view of a precast strip 150 according to an embodiment of the present invention. FIG. 10B is a cross-sectional view of the precast strip beam 150. FIG. 11A is a perspective view of a precast edge beam 160 according to an embodiment of the present invention. FIG. 11B is a cross-sectional view of the precast edge beam 160. FIG. 12 is a perspective view of the band beam 150 supported on the columnar unit 170. FIG. 13A is a cross-sectional view of a square columnar unit 170 according to an embodiment comprising a columnar formwork member 300 interconnected to a hollow for receiving ready-mixed concrete. FIG. 13B is a cross-sectional view of a rectangular columnar unit 170 '. FIG. 13C is a cross-sectional view of the columnar formwork member 300. FIG. 14 is a perspective view of a two-way floor system 400 '.

  Referring to FIG. 1, building structure 1000 includes a one-way floor system 400 and a two-way floor system 400 'according to first and second embodiments of the present invention. It will be appreciated by those skilled in the art that it is not necessary to use both floor systems 400 and 400 'within the same building structure. By way of example, either one-way floor system 400 or two-way floor system 400 'may be used in alternative building structures without departing from the spirit and scope of the present invention.

  With reference to FIGS. 1 and 7, a suspended unidirectional floor system is constructed by using modular precast concrete formwork. The system may comprise an array of parallel precast concrete joists 140 positioned in a substantially parallel arrangement. Each joist 140 spans between support elements such as a pair of elongated strips 150. Each joist 140 is supported on two strips 150 positioned along one end of joist 140. The strips 150 and joists 140 are generally arranged in a mutually perpendicular orientation. The strip 150 is positioned and supported by an upright column or column 170.

  A plurality of precast concrete members in the form of saucer units 110 extend between adjacent precast joists 140. Referring to FIGS. 5A and 5B, each pan unit 110 includes a precast plank 100 ″ that extends between two side surfaces 101A and 101B. In each of the sides, a support structure 110 ′ is provided for supporting the saucer unit 110 on two adjacent joists 140.

  2A to 2E and FIG. 3, each plank unit 100 or 100 'comprises a horizontal base 101. The longitudinal edge of the plank unit 100 or 100 'contains a recess 102 that is positioned at one of the side ends 101A and 101B of the plank unit 100, 100' or 100 "'. The recess 102 allows the plank units 100, 100 ', 100 "" to be seated on the support structure 110'. The plank unit contains a horizontal mesh 103 that extends through the length of the plank unit. A Z-shaped wire tie 104 is connected to the main horizontal mesh 103 to improve the crack capacity of the recessed portion of the thick plate unit. Further, a mechanical shear connector 105 may be provided on the top surface of the plank unit to ensure 100% bonding between the plank unit above it and ready-mixed concrete 108. The lower end of the plank unit 100, 100 ', 100 "' is equipped with a cast ferrule 106 that is evenly spaced to facilitate the mounting of the ceiling structure 109 that supports the ceiling gypsum board 109 '. Since the plank unit 100 '' is used to make the pan unit 110, the top surface of the pan unit 110 is also cast evenly spaced for attachment of the negative flex connector 145 (see FIG. 7). Equipped with a built-in ferrule 107. The thickness of the plank units 100, 100 'and 100 "may vary in the range of 50mm to 80mm. The thickness of the stepped plank unit 100 '' 'depends on the height of the step and is used only when a step needs to be created in the floor system. The stepped plank unit 100 ″ ″ includes an upward portion 106 that extends along the plank unit. This part acts as an edge formwork that keeps the ready-mixed concrete at the required level.

  Alternatively, the attachment of the one-way floor system 400 or the two-way floor system 400 ′ may involve a step of positioning a plurality of plank units 100 or saucer units 110 between adjacent joists 140 or 140 ′. . As shown in FIGS. 4 and 5, the tray unit 110 includes a thick plate unit 100 ″ and a thick plate support unit 110 ′. During installation, each end of the precast concrete cradle unit 110 is supported on oppositely arranged shelves of two adjacent joists 140 or 140 ′ (as illustrated in FIGS. 1 and 7). The

  The precast plank support structure 110 'is elongated and extends along the length of the plank unit 100 ". Both the outward facing surface of the saucer unit 110 and the vertical surface of the support joists 140 or 140 'define a receptacle for receiving ready-mixed concrete during construction (shown in greater detail in FIG. 7). Referring to FIG. 4, each support unit 110 ′ includes a seat 111 on the upper surface thereof, and is joined to the recess 102 of the plank unit 100 ″. Each support structure 110 ′ includes a bottom reinforcing bar 112 and an upper reinforcing bar 113. The bottom reinforcement bar is connected to the top reinforcement bar using a concrete shear ligature 114. The top surface of the support structure 110 ′ is also equipped with evenly spaced cast-in ferrules 115 for attachment of the negative flex connector 145 (see FIG. 7). The pan unit 110 can be cast to provide a span length in the range of 1,750 mm to 2,800 mm. The precast concrete plank unit 110, 110 ', or 110 "is designed to withstand a loading load of up to 4 kPa with a span / 250 total usage limit. The deflection under the load can be kept below span / 500.

  6A-6B illustrate joists 140 and FIG. 7 illustrates an alternative embodiment of joists 140 '. Each of these joists 140 or 140 'includes a horizontal base 141 and a vertical orientation portion 142 that extends substantially along the length of the joists 140 or 140'. The vertical alignment portion 142 includes upwardly extending surfaces that are spaced apart. The spacing between the vertical surfaces is indicated by b1. The length (b1) of the top surface is less than the length (b) of the bottom surface of the base in use. The length (b1) of the top surface is in the range of 150 mm to 300 mm, and the length (b) of the bottom surface is in the range of 300 mm to 500 mm. Each vertical surface includes a chamfer located between the shelf 141 and a separate substantially vertical surface.

  The shelves 141 are located adjacent to the side surfaces of the vertical orientation portion 142, and the shelves 141 each define a seat for receiving a connection portion of the precast concrete tray unit 110 or the plank unit 100 '. The joist unit also includes a bottom reinforcing bar 143 located in the shelf 141 and an upper reinforcing bar 144 partially located in the vertical orientation 142. In some embodiments, at least one of the upper reinforcing bars may be located outside of the vertical orientation portion 142 to improve connectivity between the joists and the ready-mixed concrete 108 above it. The joist unit 140 may also be equipped with a vertical ligature 146 that connects the bottom reinforcement bar 143 to the top reinforcement bar 144. The top surface of the joist 140 may also be equipped with evenly spaced cast ferrules 147 that are used to assemble the negative flex connector 145 (see FIG. 7). In order to use the joists 140 in the two-way moving floor system 400 ′, evenly spaced cavities 148 pass across the vertical orientation 142 to provide connectivity between the joists 140 and the ready-mixed concrete 108. Improve and assist in the installation of stiffening bars or post-tensioning tendons / ducts for a bi-directional floor system where the applied load is transmitted in the direction of the joists 140 and perpendicular thereto.

  The joist 140 or 140 'is designed to cover a span of up to 12m, and the position between the adjacent joists 140 and 140' may vary from 1,750mm to 3,300mm. Good. The joist unit 140 '(shown in FIG. 6C) is particularly useful when there is a need to create a downward step in the floor system. The joist is prestressed and forms a downward curve to cover long spans or when large construction loads are applied. The height of the vertical alignment portion may vary in the range of 50 mm to 400 mm, and the thickness of the base portion may vary in the range of 50 mm to 120 mm.

  In the described embodiment, joists 140 are constructed for residential buildings (less than 2 kPa) and commercial buildings (mostly 3 kPa) with total deflection below span pair 250 and deflection under load load below span pair 500. , Designed to carry a load of up to 6 kPa, significantly higher than required for both (4 kPa in some locations). When required, higher usage requirements can also be achieved by reducing the gap distance between joists 140. When higher shear capacity is required, the web (142) of the joists 140 and 140 ′ is supported by the joists 140 or 140 ′ (such as the strip 150, edge beam 160, or wall system 190 shown in FIG. 14). It may be thickened in a support area that rests on the element.

  Mounting the one-way floor system 400 may involve positioning a plurality of saucer units 110 or plank units 100 'or 100 "between adjacent joists 140 and 140'. Each of the precast pan 110 or precast plank unit 100 'and 100 "is positioned between the individual joists 140 or 140' once during construction, respectively, once these members (110, 100 ', or 100") are located. Adapted to accept ready-mixed concrete.

  Referring to FIGS. 8 and 9, the cast formwork floor end plate units 120 and 120 ′ also have a pre-cast pan unit 110 or plank unit 100, 100 ′, and 100 ″ before tilting the ready-mixed concrete. It may be positioned on each individual edge. The floor end plate unit 120 or 120 'may be provided in the form of an L-shaped member 120 (FIG. 9) or a U-shaped member 120' (FIG. 8).

  L-shaped end plate member 120 (depicted in FIG. 9) is used at the connection location between joists 140 and joist support members (band beam unit 150, edge beam unit 160, or wall unit 190), respectively. The This arrangement is more clearly shown by FIG. A U-shaped end plate member 120 ′ (depicted in FIG. 8) is used within the second embodiment of the present invention (400 ′, see FIG. 15) when a bi-directional floor system is provided. . A U-shaped floor end plate 120 ′ is positioned between the precast saucer units 110 and along a rectangular or circular penetration hole 148 in the joist 140, one in the direction of the joist 140 and the other with respect to the joist 140. Thus, two-way movement in the lateral direction can be made possible. The floor end plates 120 and 120 'comprise a reinforcing mesh 121 that is bent and conforms to the shape of the floor end plate, ie, U-shaped or L-shaped. In order to improve the connectivity from the floor end plate to the ready-mixed concrete, these driven formwork members are equipped with mechanical shear connectors 122.

  With reference to FIGS. 10-12, cross-sectional and perspective views of the band beam unit 150 and the edge beam unit 160 are illustrated. As described in the previous section, the plurality of precast concrete joists 140 and 140 ′ are formed of a plurality of strips 150 extending in a direction generally perpendicular to the general direction of the precast concrete joists 140 and 140 ′. And / or supported by edge beams 160. When handling small applied loads or short spans, the beam 150 may have a shape similar to the joist 140 but larger in size. Otherwise, the beam 150 comprises two spaced-apart moldings 150A and 150B extending upward from the beam 150. The edge beam 160 contains one molded product 160 </ b> A extending upward from the edge beam 160. Moldings 150 </ b> A and 150 </ b> B extend along the length of beam 150. Similarly, molding 160A also extends along the length of the edge beam. A joist receiving portion for the strip 150 extends outward from the molded products 150A and 150B to support the ends of the joists 140. Similarly, the joist receiving portion for the edge beam 160 extends outward from the molding 160A. The lateral width of each molded product (B) may vary in the range of 100 to 300 mm depending on the span of the band and the magnitude of the applied load. Thicker values may be used in the bearing area of the beam to assist in transmitting shear forces to the column 170. The height of the molded product (H) may vary in the range of 200 mm to 600 mm depending on the span of the strip and the magnitude of the applied load. The thickness of the beam (T) may vary in the range of 80 mm to 150 mm.

  Referring to FIGS. 10B and 11B, the strip 150 further includes an upper reinforcing bar 151 that extends through the top of the molding along the longitudinal direction of the strip 150 and / or the edge beam 160, respectively. Positive reinforcement bar 155 also extends along beams 150 and 160. Beams 150 and 160 also include torsion and shear ligature bars 152 and 153 to provide additional shear strength characteristics to beams 150 and 160. The shear ligature bar also assists in the transmission of shear forces acting at the interface of the beam 150 or edge beam 160 and the overlying concrete that is tilted in the field. A circular or rectangular penetration opening 156 may also be provided through the vertical portions 150A and 150B of the beam 150. These openings reduce the total weight of the beam and the connection created with ready-mixed concrete and improve the composite action between them. The beam 150 also contains another penetration opening 157 in its horizontal portion along the underside to facilitate the connection of the strip 150 to the support column, ie the column 170. The beam element 150 also contains a recess 158 around the penetration hole 157. This will constrain the column head and transmit the load to the column via bearings in this region. A perspective view during typical use of the assembly between the column 170 and the beam 150 is shown in FIG. Advantageously, each beam 150 is provided as a single unit with a width of 800-2,000 mm and no intensive field work is required.

  Referring to FIG. 13, cross sections of columnar units 170 (square) and 170 '(rectangular) constructed using the precast columnar formwork unit 300 are illustrated. The columnar formwork unit 300 includes a horizontal portion with a thickness of 50 mm to 70 mm, and includes a recess 301 at one of its edges. A portion of the columnar builder extends downward by approximately 50 mm (302). The element also comprises an internal reinforcing mesh 303. In order to improve the crack capacity of the edge of this unit, both outer edges of the columnar formwork unit 300 are reinforced with edge wire ties 304. The columnar formwork unit also contains a connector element 305 located at each end of the unit 300. Columnar formwork units 300 of different widths can be connected together to form square (170) or rectangular (170 ') columns using structural adhesives. A mechanical connector may also be used if required. An additional column cage containing a longitudinal bar 306 and a shear ligature 307 is also defined by the column form unit 300 and secured in place using the connector 305. May be installed. A perspective view of the columnar unit 170 is shown in FIG. The column cavities will then be filled with ready-mixed concrete 308 on site.

  Referring to FIG. 14, the use of a modular precast concrete formwork to construct a two-way slab system (400 ') is illustrated. A beam 150 is attached over the columnar unit 170. The edge beam 160 spans between the wall unit 190 and the beam unit 150. During installation, the beam 150 is connected to the column 170 using a recess in the lower end of the beam. The joist unit 140 is then installed between the beam unit 150 and the wall unit 190.

  For bi-directional motion, a U-shaped floor end plate 120 ′ is installed perpendicularly to the front of the rectangular or circular penetration hole 148 (within the joist 140) and the joist 140 to produce a monolithic lateral joist Also good. The saucer unit 110 is then positioned between the joist 140 and the U-shaped drive form 120 '. Here, a positive reinforcement or post-tensioning tendon / conduit can be placed inside the U-shaped floor end plate and lateral to the joists 140. These are passed through rectangular or circular penetration holes 148 across all joists 140 and continue to support beam 160. The floor system 400 'acts as a one-way slab during the construction phase and prior to removal of the struts (which may be temporarily installed under the joists 140 or beams 150 and 160). After installation and hardening of the overlying concrete, the final floor system 400 'acts as a two-way slab.

In at least some embodiments, the adoption of system 400 or 400 ′ is expected to likely provide the following advantages:
• Increase construction speed.
・ Achieve high quality finish.
・ Improve the safety of workers working on buildings.
・ Reduce construction costs.
・ Reduce the volume of concrete work on site.
Reduce the amount of reinforcement bars that need to be installed and arranged in the field.
・ Improve the quality of concrete structures.
• Reduces the risk to third parties due to construction activities, as the building will be built within a short period of time (compared to the current construction time).

  In compliance with the statute, the invention has been described in language more or less specific to structural or methodological features. The terms “comprises” and variations thereof such as “comrising” and “comprised of” are used throughout in a comprehensive sense, without excluding any additional features. It will be understood that the means described herein are in a preferred form embodying the invention and that the invention is not limited to the specific features shown or described. Accordingly, the invention is claimed in any form or modification within the proper scope of the appended claims as appropriately construed by those skilled in the art.

  Throughout the specification and claims (if present), unless otherwise required by context, the term “substantially” or “about” is understood not to be limited to the value of the scope modified by the term. It will be.

  Any embodiment of the present invention is intended to be illustrative only and not intended to be limiting. Accordingly, it should be understood that various other changes and modifications can be made to any described embodiment without departing from the spirit and scope of the invention.

Claims (21)

A formwork for constructing a floor system in a building, wherein the formwork is
A plurality of precast concrete joists positioned in a substantially parallel arrangement, wherein one or more of the joists include a horizontal base and an upwardly directed extending substantially along the length of the joists. A plurality of precast, wherein the upward directing portion has a spaced apart surface extending upward from the base, and the individual shelf portions of the base are located adjacent to the upward directing portion With concrete joists,
A plurality of precast concrete members for extending along the length of the joists to receive ready-mixed concrete;
A formwork comprising: a support arrangement for supporting both ends of each of the precast concrete members on shelves arranged in opposition to two adjacent joists.   One or more of the precast concrete members comprise a shell for receiving ready-mixed concrete, the shell supporting the shell on a shelf arranged oppositely of the two adjacent joists The formwork of claim 1, adapted to be coupled with a separate downward pointing support.   The said support part is a formwork of Claim 1 or 2 formed integrally using the said precast member.   8. Any one of the preceding claims, wherein the outer surface of the precast concrete member combined with the surface of the upward directing portion of the supporting joist located at both ends defines an active receiving portion for receiving ready-mixed concrete. The formwork described.   The precast concrete member comprises an edge extending along the length of the precast concrete member, and preferably at least the first edge extends along a first side of the precast concrete member. The form of any one of the preceding claims, wherein at least a second edge extends along a second side of the precast concrete member. One or more of the precast concrete members are:
A saucer for receiving the ready-mixed concrete;
Shoulders located at opposite ends of the saucer, the shoulders being adapted to be supported on oppositely arranged shelves of the two adjacent joists The mold according to claim 1.   7. A formwork according to claim 6, wherein the saucer combined with the surface of the upward directing portion of the support joist located at both ends defines a receiving portion in use for receiving ready-mixed concrete.   The formwork of any one of the preceding claims, further comprising precast concrete joists supported by a plurality of beams extending in a direction substantially perpendicular to a general direction of the precast concrete joists.   The beam comprises a beam portion with a substantially flat profile with two spaced apart moldings extending upward from the beam portion, the molding extending along the length of the beam, 9. The formwork of claim 8, wherein the receiving portion extends outward from the molding to support a plurality of joists' ends.   The plurality of joists' outward projecting ends are supported on joists receiving portions of the beams, and the joists receiving portions of the beams preferably extend in a direction perpendicular to the projecting ends of the joists. The mold according to any one of claims 8 and 9.   11. A formwork according to any one of claims 8 to 10, wherein the bottom surface of the beam is substantially in the same plane as the bottom surface of the joists. A first connection mechanism for connecting a first joist positioned on a first side of the beam to a second joist positioned on a second side of the beam, the connection mechanism comprising: Preferably, a first connection mechanism further adapted to apply a negative bending force to the first and second joists during use;
A second connection mechanism for connecting two adjacent beams simultaneously supported on a columnar object, wherein the connector applies a negative bending force to the adjacent beams. A formwork according to any one of the preceding claims, further comprising a second connection mechanism provided.   A columnar formwork member for forming a columnar body for supporting the beam is further provided, and each of the columnar formwork members is interconnected to define a hollow part for receiving ready-mixed concrete. The mold according to any one of claims 8 to 12, which is capable.   Each of the end portions of the columnar object form frame member has an imaginary plane of the second columnar object form member in which the virtual plane of the first columnar form member is interconnected with the first columnar form member. The formwork of Claim 13 provided with the connection part for interconnecting the said columnar object formwork member so that it may arrange in a horizontal direction with respect to a plane.   The locking portion is configured in an interconnected configuration such that the locking member is adapted to be received within a recess in another of the columnar formwork so that the vertical edge of the columnar formwork member The formwork according to any one of claims 13 or 14, wherein the form extends along a longitudinal edge of the another columnar formwork.   2. The one or more implantable formwork members for positioning between two spaced joists, preferably, the implantable formwork member comprises a generally L-shaped or U-shaped cross section. The mold according to any one of the above.   The joist of the formwork further comprises one or more openings for receiving a reinforcing bar, the reinforcing bar extending transversely to the general direction of the joist, the reinforcing bar being A formwork according to any one of the preceding claims, adapted to be subjected to pressure (using post tensioning) after pouring concrete into the precast concrete receiving member.   The formwork of any one of the preceding claims, wherein the at least one precast concrete member comprises a stepped configuration having an upper part in use and a lower part in use.   A precast concrete joist, the precast concrete joist comprising a horizontal base and an upward directing portion extending substantially along the length of the joist, the upward directing portion facing upward from the base The base shelf is located adjacent to the upward directing portion, and each shelf accepts a precast concrete tray member or a precast concrete shell member connection, respectively. A precast concrete joist that defines a seat portion for performing, and wherein the height of the upward directing portion is equal to or greater than a vertical height of the shelf portion.   A precast concrete member to be positioned and supported between spaced joists or beams, said precast member extending along the length of said joists or beams for receiving ready-mixed concrete; The precast member comprises a support arrangement, and supports both ends of the precast concrete member on joists or beams arranged opposite to each other. A method for constructing a suspended floor in a building, said method comprising:
Positioning a plurality of precast concrete joists in a substantially parallel arrangement, wherein one or more of the joists have a horizontal base and an upwardly extending substantially along the length of the joists A directing portion, wherein the upward directing portion has a spaced surface extending upward from the base, and the shelf of the base is located adjacent to the vertical portion; and
Positioning a plurality of precast concrete members between adjacent joists, wherein the precast concrete members are positioned to extend along the length of the joists to receive tilted concrete , Steps and
Supporting each end of each precast concrete member on oppositely arranged shelves of two adjacent joists;
Pouring green concrete into a receptacle defined by the precast concrete member.

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