KR102406728B1 - metal deck - Google Patents

Abstract

In one embodiment, a metal deck is provided that includes a plurality of deck parts molded from adjacent metal sheets. Each deck piece includes a plurality of folded ribs molded along the length of the metal deck. Each of the plurality of folded ribs is configured such that at least one truss of the building can be installed between the plurality of folded ribs. Metal decks can be used to complete structural diaphragms without the use of concrete.

Description

metal deck

This application claims priority to U.S. continuation application Ser. No. 15/860,073, filed on January 2, 2018, entitled "METAL DEKING." In addition, this application claims priority to U.S. Patent Application No. 15/217,589, filed on July 22, 2016 with the title of "METAL DEKING", and the U.S. Patent Application No. 15/217,589, filed in 2015 Priority is claimed to U.S. Provisional Patent Application No. 62/195,677, filed on July 22nd, entitled "METAL DEKING." The above events are incorporated herein by reference for all matters disclosed and taught herein.

Composite decking can be used as part of the floor and/or ceiling of single or multi-storey buildings. Composite decks are used to complete the structural diaphragm of the building. The composite deck includes adjacent metal sheets upon which concrete is molded, and may include a mesh structure that imparts rigidity to the concrete.

KR 10-1111168 B1

In one embodiment, a metal deck includes a plurality of deck parts, wherein the plurality of deck parts are molded along a width of the metal deck and include an elevated section and a ribbed section, the raised section comprising: A portion is configured to provide sound insulation between the metal deck and a truss structure, the rib portion comprising a rib flute extending from a lower surface of the metal deck, the rib portion comprising: , a first elevated rib positioned adjacent a first side of the rib flute and a second elevated rib positioned adjacent a second side of the rib flute, wherein the first raised rib and the A second rising rib is substantially parallel to the rib flute, the rib portion including the rib flute, the first rising rib, and the second rising rib extending along the length of the metal deck.

A further understanding of the nature and advantages of the present technology may be realized with reference to the drawings described in the remainder of this specification. In the drawings, like reference numerals are used throughout the drawings to refer to like elements. In some cases, a reference number may have an associated sublabel consisting of lowercase letters to indicate one of several similar elements. When referring to a reference sign without a description of a sub-label, the reference is intended to refer to all of these several similar elements.
1 shows a three-dimensional view of an exemplary metal deck in accordance with the present invention.
2A shows a side view of an exemplary metal deck, and FIG. 2B shows a top view of the exemplary metal deck.
3 shows a cross-sectional view of an exemplary metal deck.
4 shows a three-dimensional view of an exemplary metal deck according to the present invention, on a truss structure;
5 shows an alternative three-dimensional view of an exemplary metal deck according to the present invention, on a truss structure;
6 shows an alternative plan view of an exemplary metal deck.
7 shows a three-dimensional view of an exemplary metal deck in accordance with the present invention.
8A-8C show exemplary side views of an exemplary metal deck in accordance with the present invention.
9 shows an example of an operation for manufacturing a metal deck and installing it in a building.
10 shows an exemplary plan view of a metal deck in accordance with the present invention.
11 shows an exemplary top view of a portion of a metal deck in accordance with the present invention.
12 shows an alternative view of an exemplary metal deck in accordance with the present invention.
13 shows another alternative view of an exemplary metal deck in accordance with the present invention.
14 shows a side view of an exemplary metal deck in accordance with the present invention.
15 shows another alternative side view of a metal deck according to the invention;
16 shows another view of another exemplary metal deck in accordance with the present invention.
17 shows a top view of an exemplary metal deck in accordance with the present invention.
18 shows a cross-sectional side view of an exemplary metal deck in accordance with the present invention.
19 shows a cross-sectional side view of an exemplary metal deck in accordance with the present invention positioned on a truss structure;
20 shows another view of an exemplary metal deck in accordance with the present invention, positioned on a truss structure;
21 shows a diagram of an exemplary metal deck in accordance with the present invention.
22 shows a side view of an exemplary metal deck in accordance with the present invention.

When constructing single or multi-storey buildings, composite decking may be used for floors and/or ceilings. Composite decks with concrete are used to complete the structural diaphragm of the building. Structural diaphragms of buildings join and function together vertical and horizontal structural components to transmit lateral and vertical forces. To lay out the composite deck, adjacent metal ribbed sheets are installed, and then concrete is poured over the top surface of the metal deck to form the composite deck. In some embodiments, the concrete is given rigidity by placing a mesh prior to pouring it. In various embodiments, the metal sheet of the composite deck is used as a mechanism for forming concrete thereon. The processes of connecting metal sheets to structural elements, for example I-beams, laying out the mesh, pouring the concrete, and curing the concrete are time consuming and expensive.

In an embodiment according to the invention, a metal deck is provided. The metal deck according to the present invention uses a ribbed structure with strength properties so that the metal deck can be utilized as a floor and/or ceiling of a building without concrete. As such, the metal deck according to the present invention provides strength characteristics that can complete the structural diaphragm of a building without an expensive and time-consuming process of pouring concrete. The panel size and shape of the metal deck can be standardized. Standardization of metal decks makes it possible to manufacture metal decks using cold roll former machines. In the embodiment according to the present invention, length, depth, angle, etc. are standardized. Such standardization reduces the need for iterative engineer design and analysis of metal decks. Moreover, standardization also reduces the manufacturing cost of the metal deck. These standardized metal decks can be used with other standardized building components, such as wall panels, trusses, and the like.

In various embodiments, a concrete layer may be poured over a metal deck according to the present invention for noise damping purposes. In such an embodiment, an acoustic mat can be placed on the metal deck prior to pouring the concrete.

1 shows a three-dimensional view of an exemplary metal deck 100 in accordance with the present invention. In particular, the metal deck 100 includes a number of deck parts 102a, 102b, ... 102n. The metal deck 100 may be molded as one contiguous article of manufacture having the plurality of deck parts.

Various metal deck parts are connected to each other. For example, the metal deck 100 may be formed from a sheet of metal using a roll former. An exemplary roll former may be configured to receive a macro file with instructions to cut a roll of steel at a predetermined distance and at a predetermined angle so that it may roll form to create a metal deck. have. Also, such roll formers are configured to receive instructions from the macro file regarding placement, punching, etching or cutting of pilot holes and other openings of fasteners. For example, the thickness of the sheet used to form the metal deck 100 may be 12 to 18 gauge (0.050 to 0.11 inches) for stainless steel sheets. However, alternative thicknesses of metal sheets may also be used. Similarly, alternative materials used in building construction may be used, such as galvanized steel, aluminum, and the like.

Each deck component may be configured to have ribs 104 along its length 120 . The ribs 104 have a folded profile, with the ribs facing down and facing the surface of the deck component. That is, when a deck part is used to form a metal deck, the folded ribs 104 face the ground, and the substantially flat surface of the other side of the deck part opposite the ribs 104 faces away from the ground.

The deck part is also shaped such that the ribs 104 include rib openings 106a , 106b , 106c , etc. at predetermined spacing along the length 120 . These rib openings in the ribs 104 span the width 130 of the metal deck 100 . That is, the ribs 104 are not continuous along the entire length 120 of the deck component 102 . A rib opening 106c is shown at one end of the deck piece. Similar rib openings 106 may be provided at the other end of the deck part. The rib openings 106 are configured to receive a truss structure that supports the metal deck 100 .

In one embodiment, the ribs 104 between the rib openings 106 are rib flutes 21.80 inches long. In other embodiments, other lengths of rib flutes may be provided. In one embodiment, each rib opening 106 between the rib flutes may be 2.20 inches. Consequently, the distance between the beginning of each rib opening 106 is 24 inches. The dimensions of the length of the rib flutes and rib openings 106 may be selected based on the dimensions of other parts of the construction system. For example, if the metal deck 100 is used with trusses spaced 21.80 inches apart from each other, the length of the rib flutes may be chosen to be 21.80 inches. Also, if the truss is 2.20 inches wide, a rib opening of 2.20 inches is provided. This makes it possible to fit and install the metal deck 100 on a series of trusses.

FIG. 2A shows a side view of the metal deck 200 , and FIG. 2B shows a top view of the metal deck 200 . Referring to FIG. 2A , the metal deck 200 includes ribs 204 having a plurality of predefined rib openings 206a - 206e. Each rib opening 206 is configured to receive a truss capable of supporting the metal deck 200 . The sides of the rib openings 206 are angled to serve as guides for receiving the trusses. For example, after a truss is installed within a structure, a sheet of metal deck 200 may be placed on the truss, which is guided into the rib opening 206 by the inclined angle of the rib opening 206 . . Thus, the person placing the metal deck 200 does not need to ensure that the metal deck 200 fits exactly on the truss.

Referring now to FIG. 2B , metal deck 200 includes several deck components 202a - 202e. The deck part may be molded from one adjacent piece of metal. Ribs 204 extend under the metal deck 200, for example in the z-direction, together with predefined rib openings 206 . The rib openings 206 of the other ribs are aligned such that a plurality of parallel rib openings can receive the truss. For example, the rib opening 206 may receive a truss along the line 208 .

3 shows a cross-sectional view of an exemplary metal deck 300 . Metal deck 300 includes ribs 302a, 302b, for example rib flutes, and top ribs 306a, 306b. As shown in enlarged view 304 of rib 302a, rib 302a has a folded profile. For example, the height 310 of the rib 302a may be approximately 1.25 inches. Sides 312 , 314 are shown perpendicular to the surface of metal deck 300 . In one embodiment, the top ends of the ribs 302a may be clamped closed so that the top ends of the sides 312 , 314 abut against each other such that the top surface of the metal deck 300 is a substantially flat surface. Also, in the illustrated embodiment, the top end of each side 312 , 314 is curved. The ribs additionally support the deck 300 and allow the deck 300 to have a rigid structure.

A top rib (eg, top rib 306a ) provides grip or traction to the metal deck 300 . For example, the top of the metal deck 300 may be a work surface, and the top ribs may provide traction to allow people to walk on the top without slipping. The top ribs can be arranged in different patterns. The metal deck 300 further includes an elevated tab 308 . Lifting tab 308 is configured to receive a flat portion of another metal deck.

4 shows a three-dimensional view 400 of an exemplary metal deck 402 according to the present invention, on a truss structure 404 . Specifically, it shows a metal deck 402 comprising a plurality of ribs 410a, 410b, etc. having rib openings (eg, rib openings 408). The metal deck 402 is shown lying on a truss structure 404 that includes a number of trusses 406a, 406b, etc. The rib opening is dimensioned to fit around the truss, and the rib is installed between the trusses 406 .

5 shows an alternative three-dimensional view 500 of an exemplary metal deck 502 in accordance with the present invention, on a truss structure 504 . Specifically, the metal deck 502 includes a number of deck parts 506a, 506b, etc. that rest on a truss 508a, 508b, etc. It should be understood that the metal deck 502 may include more or fewer deck components than shown. It should also be understood that truss structure 504 may include more or fewer trusses than shown. As such, the ribs (not shown) of the metal deck may include a plurality of rib openings (not shown) to match the number of trusses 508 .

6 shows an alternative top view of an exemplary metal deck 600 . Metal deck 600 includes a number of deck components 602a, 602b, etc. The top surface 606 of the metal deck 600 includes a plurality of top ribs 604a, 604b, etc. A portion of the top rib 604 , such as the top rib 604e , extends along the length 610 of the metal deck 600 . Other top ribs, such as top ribs 604a, 604b, 604c, are arranged in a diagonal pattern. It should be understood that the top ribs may be arranged in other patterns. For example, the top rib 604d may be positioned perpendicular to the top rib 604e. The top rib 604 provides traction to the top surface 606 . Such a top surface 606 may be a working surface.

7 shows a three-dimensional view of an exemplary metal deck 700 in accordance with the present invention. Specifically, the metal deck 700 includes a plurality of deck parts 702a, 702b, ?? 702n (hereinafter, deck parts). The metal deck 700 may be molded as one adjacent article of manufacture with deck parts joined together. For example, the metal deck 700 may be formed from a sheet of metal using a roll former. For example, the thickness of the sheet used to form the metal deck 700 may be 16 to 18 gauge (0.0625 to 0.0500 inches) for stainless steel sheets. However, alternative thicknesses of metal sheets may also be used. Similarly, alternative materials used in building construction may be used, such as galvanized steel, aluminum, and the like. For example, if deck component 702 is made using standard steel sheet, the thickness of the deck may be, for example, standard steel 16 to 18 gauge, which may be equal to a thickness of .00598 to 0.0478 inches. . On the other hand, if a sheet of galvanized steel is used to make the deck part 702, the thickness of the deck may be, for example, 16 to 18 gauge of galvanized steel, which would be equal to a thickness of 0.0635 inches to 0.0516 inches. can

Each deck part 702 may be configured to have ribs 704 along its length 720 . The ribs 704 are molded into a dovetail shape, and the ribs 704 face the surface of the deck component 702 and point downwards. That is, when using the deck part 702 to form a metal deck, the dovetail ribs 704 face the ground and the other flat surface of the deck part 702 opposite the ribs 704 faces away from the ground. .

The deck part 702 is also shaped such that the ribs 704 are cut at predetermined intervals along the length 720 . This cut of the rib 704 spans the width 730 of the metal deck 700 . That is, the ribs 704 are not continuous along the entire length 720 of the deck component 702 . Specifically, as shown in FIG. 7 , each deck part 702 has rib openings 706a , 706b , 706c (hereinafter rib openings 706 ). A rib opening 706c is shown at one end of the deck component 702 . Similar rib openings may be provided at the other end of deck component 702 as well.

In one embodiment, ribs 704 are cut along length 720 to form rib flutes that are 21.80 inches long. In alternative embodiments, other lengths of rib flutes may be provided. In one embodiment, each rib opening 706 between the rib flutes may be 2.20 inches. Consequently, the distance between the beginning of each rib opening 706 is 24 inches. The dimensions of the length of the rib flutes and rib openings 706 may be selected based on the dimensions of other parts of the construction system. For example, if a metal deck 700 is used with trusses spaced apart from each other by 21.80 inches, the length of the rib flutes may be selected to be 21.80 inches. Also, if the width of the truss is 2.20 inches, a rib opening 706 of 2.20 inches is provided. This makes it possible to fit and install the metal deck 700 on a series of trusses.

8A-8C show exemplary side views of a partial metal deck in accordance with the present invention. Specifically, FIG. 8A shows a side view of the metal deck 800 showing a plurality of dovetail-shaped ribs 802 extending along the z direction. In one embodiment, the metal deck 800 also includes a top rib 804 on its surface such that the top rib 804 bends in an upward direction opposite to the rib 802 . Rib 802 and top rib 804 provide bracing or strength to the metal deck system. The top rib 804 also provides traction to the top surface of the deck. If the metal deck 800 is provided to have no ribs, deflection may occur under smaller loads, and thus the ribbed metal deck 800 does not provide sufficient support as a working surface.

8B shows an enlarged view of a rib 810 having sides 812 , 814 and a bottom 816 . Sides 812 , 814 are shown having angles 808a , 808b with respect to the surface of metal deck 800 . In this embodiment, these angles 808a, 808b are nearly similar to each other, such that the rib 810 has a symmetrical shape with respect to the x-axis. However, in alternative embodiments, angles 808a and 808b may be different based on at least one load balancing requirement. In one embodiment, the top ends of the ribs 810 may be clamped closed so that the top ends of the sides 812 and 814 touch each other. Also, in the illustrated embodiment, the top end of each side 812, 814 is curved.

8C shows an enlarged view of the top rib 820 . The height of the top rib 820 may be about 1.25 inches.

9 shows an example of an operation 900 for manufacturing a metal deck and installing it in a building. In operation 902, a macro file is received at a roll former used to create the various components of the building. In one embodiment, such a macro file may be received from a software application that generates a macro file based on an architectural drawing. In operation 904, a steel roll is placed in the roll former. In operation 906, the roll former interprets the command received from the macro file to roll-form the metal deck. At operation 908 , a pilot hole is punched in the metal deck. In operation 910, a metal deck is placed on the pre-installed truss. At operation 912 , the metal deck is attached to the truss. At operation 914 , wall panels for the next floor of the building are installed on top of the metal deck. This process can be repeated depending on the number of floors in the building.

10 shows an exemplary top view 1000 of a metal deck in accordance with the present invention. A metal deck according to the present invention may include a plurality of ribs on the top of the deck. Specifically, these ribs may be oblique to the length of the metal deck. In embodiments, the length of the sheet of metal deck may be between 2 feet and 20 feet. However, other lengths may be used in alternative embodiments.

11 shows an exemplary top view 1100 of a portion of a metal deck in accordance with the present invention. In detail, the plan view 1100 shows examples of various arrangements of ribs located on top of the metal deck. For example, such ribs may be beveled at an angle of 35 degrees or 40 degrees with respect to the axis along the length of the deck. Alternate arrangements may have alternate angles in the range of 20 to 60 degrees. In one embodiment, the length of the top rib may be between 3.25 inches and 5.00 inches. However, other lengths may be possible.

12 shows an alternative view 1200 of an exemplary metal deck in accordance with the present invention. As shown here, in one embodiment, to accommodate the truss, the edges of the folded ribs may be cut at a 75 degree angle 1202 from the surface of the metal deck. Also, in the illustrated embodiment, the folded ribs may have openings spaced about 2 feet apart. The metal deck may have an open edge at each end of approximately 1.125 inches.

13 shows another alternative view 1300 of an exemplary metal deck in accordance with the present invention. Details 1302 and 1304 are described in more detail in FIGS. 14 and 15 below.

14 shows a side view 1400 of an exemplary metal deck in accordance with the present invention. As shown here, the side view 1400 shows the length of the folded rib 1402 to be about 1.25 inches. The thickness of the folded ribs 1402 may be about 0.13 inches.

15 shows another alternative side view 1500 of a metal deck in accordance with the present invention. As shown at 1502, the metal deck can bend from the edge to about 88 degrees (from 90 degrees) when loaded, giving flexibility to the edge of the metal deck. The top rib may be positioned about 0.57 inches from the folded rib.

16 shows another view of another exemplary metal deck 1600 in accordance with the present invention. The metal deck 1600 may be formed from a sheet of steel 14 to 18 gauge thick, for example, by a roll former. The metal deck 1600 includes a number of deck parts, eg, deck part 1602 , that extend substantially the length of the metal deck 1600 . A number of deck parts are molded along the width of the metal deck 1600 . The deck part includes an elevated portion and a ribbed portion. For example, deck part 1602 includes a raised portion 1604 (also referred to as 'raised portion 1604 ') and a rib portion 1606 (also referred to as 'ribbed portion 1606 '). When the metal deck 1600 is installed on the truss structure (eg, the truss structure 2004 of FIG. 20 ), the raised portion 1604 is connected to the metal deck 1600 and the truss structure to provide a sound insulation/sound damping function. provide a gap between them. For example, acoustic vibrations reaching the metal deck 1600 are dissipated by the spacing provided by the raised portion 1604 , eg, air. As shown in FIG. 16 , the metal deck 1600 comprises a plurality of raised portions that make up a majority of the area of the metal deck 1600 and extend the length of the metal deck 1600 . Accordingly, most of the surface area of the metal deck 1600 rises above the truss structure to provide a noise control/dissipation function.

A number of protrusions are disposed along the length of the raised portion 1604 . For example, the raised portion 1604 includes a projection 1608 . In the illustrated embodiment, the protrusion 1608 is substantially frustoconical in shape, although it should be understood that other shapes for the protrusion 1608 are contemplated, for example a trapezoidal prismatic shape. The protrusion may be formed using a punching or etching apparatus or machine. In the illustrated embodiment, the projection 1608 includes an opening, although it should be understood that in other embodiments, the projection 1608 may not include an opening. The protrusions 1608 provide an undulated surface for grip or traction control purposes. For example, the protrusion may provide some traction to an operator traversing the metal deck 1600 . Likewise, the protrusions provide a surface area that can engage with the concrete poured onto the metal deck 1600 .

The rib portion 1606 of the deck component 1602 of the metal deck 1600 provides stiffness and support as well as undulating surface area for gripping purposes. That is, the rib portion prevents substantial deflection of the metal deck 1600 . In one embodiment, rib portion 1606 constitutes two rib troughs disposed on either side of two adjacent elevated ribs. Two rising ribs are located on either side of a rib flute, such as rib flute 1814 of FIG. 18 , extending substantially the length of metal deck 1600 . The rib flutes include cutouts for receiving the truss structure such that the metal deck can be substantially seated in the truss structure. The rib flutes also provide more stability (rigidity and reduced sag) to the metal deck 1600 . The rib portion extends substantially (or entirely) the length of the metal deck 1600 .

The metal deck 1600 further includes an optional cutout, for example, a cutout 1610 on the side of the metal deck 1600 . Cutouts may be included so that the metal deck 1600 fits part of a structural post of the building. The location of the various cuts will depend on the placement of the structural posts within the building. In some embodiments, the metal deck 1600 may not include cutouts for the structural posts, as they may not be disposed proximate to the structural posts. Metal deck 1600 includes an end cutout 1612 for receiving structural posts. The placement and size of the end cut 1612 also depends on the layout of the structural posts within the building or structure. It should be understood that only a portion of the metal deck is shown in FIG. 16 .

17 shows a top view of an exemplary metal deck 1700 in accordance with the present invention. Metal deck 1700 is only partially shown. Metal deck 1700 includes a number of deck parts, eg, deck part 1702 , including raised portions and ribbed portions. The rib portion provides strength, stiffness, and prevents substantial sag of the metal deck 1700 . A rising portion is raised above the truss structure (not shown) on which the metal deck is located. The raised portion provides a gap between the truss structure and the metal deck 1700 to provide a noise control/dissipation function. A rib portion, and a projection on the raised portion, eg, projection 1704 , provide traction control on the metal deck 1700 .

The metal deck 1700 includes various cuts 1706 , 1708 , 1710 , 1712 positioned around various edges of the metal deck 1700 . Cutouts 1706 , 1708 , 1710 are for receiving/enclosing various structural posts/structural columns within a building or structure. The location, size, and shape of the cuts 1706, 1708, 1710, etc. depend on the location of the structural posts/pillars within the building or structure. It should be understood that the metal deck may include more or fewer cuts than shown in FIG. 17 . In some embodiments, the metal deck does not include cutouts.

18 shows a cross-sectional side view of an exemplary metal deck 1800 in accordance with the present invention. Specifically, FIG. 18 shows a cross-sectional view of various parts included in the metal deck 1800 . For example, deck component 1802 includes raised portion 1804 and rib portion 1806 . When the metal deck 1800 is installed in a truss structure, such as the truss structure 2004 of FIG. 20, the raised portion 1804 does not contact the truss structure and provides a gap between the metal deck 1800 and the truss structure. . This gap allows sound waves passing through the metal deck 1800 to be dissipated by the air in the gap provided by the rising portion, providing a noise control/dissipation function. The raised portion 1804 further includes a protrusion, eg, a protrusion 1808 , that provides traction control on the metal deck 1800 .

Rib portions, eg, rib portions 1806 , provide support, stiffness, and prevent substantial sag of the metal deck 1800 . Rib portion 1806 includes two rib troughs, eg, rib troughs 1810 , disposed on either side of two adjacent raised ribs, eg, raised ribs 1812 . A rib flute, eg, rib flute 1814 , is formed between two adjacent raised ribs of rib portion 1806 . Rib flutes 1814 extend from the bottom of the metal deck 1600 in a direction away from the metal deck 1600 . The adjacent two raised ribs have rib flutes extending downwardly below the metal deck 1800 between them. The base portion of the rib trough 1810 may be seated in a truss structure. Rib trough 1810, like raised rib 1812, supports the raised portion of metal deck 1800. Rib flutes 1814 , rib troughs 1810 , and raised ribs 1812 substantially extend the length of metal deck 1600 , for example in a direction substantially parallel to the z-axis. Rib flutes 1814 extend down from the bottom of the metal deck, eg, substantially parallel to the x-axis and opposite the illustrated x-axis. Each of the cross-sectional parts, eg the deck part, is configured along an axis parallel to the width of the metal deck, eg, the y-axis, and substantially extends the length of the metal deck, eg, along an axis parallel to the z-axis.

As shown in FIG. 18 , the edges of the metal deck 1800 may be shaped to have different cross-sections. Such a configuration allows multiple metal decks to be placed adjacent to other metal decks, allowing the end sections to be in an overlapping configuration. For example, the metal deck 1800 includes a narrow rib trough 1818 and a first edge 1816 having an elevated flange. The metal deck 1800 also includes a second edge 1822 that includes a rib trough 1824 , a raised rib 1826 , a rib flute 1828 , and a flange 1830 (eg, a flat flange). do. If the first edge 1816 (of another metal deck) was positioned adjacent the second edge 1822 , the flange 1830 would extend below the raised flange 1820 of the first edge 1816 . The configuration shown provides support and allows the various metal decks to be fixedly positioned adjacent to other metal decks. Metal deck 1800 in some embodiments includes dovetail shaped rib flutes, such as rib flutes 702 and 802 shown in FIGS. 7 and 8 .

19 shows a cross-sectional side view 1900 of an exemplary metal deck 1902 in accordance with the present invention, positioned on a truss structure 1904 . The truss structure 1904 includes a top chord 1906 on which a metal deck 1902 is located. The upper chord 1906 has a cut-out opening, such as the opening 2008 in FIG. is located in Metal deck 1902 includes a number of deck components including elevations, eg, elevations 1910 . The riser 1910 provides sound insulation between the metal deck 1902 and the truss chord 1906 . The riser 1910 is supported by an adjacent gib trough. For example, riser 1910 is supported by adjacent rib troughs 1912 , 1914 . The bases of the rib troughs 1912 , 1914 contact the top surface of a truss chord 1906 . Accordingly, any force applied to the riser 1910 is transmitted to the truss via the rib troughs 1912 and 1914 .

The truss of the truss structure 1904 is positioned on an axis parallel to the y-axis, and the metal deck 1902 includes a length positioned in an axis parallel to the z-axis. Rib flutes 1908 extend substantially the length of the metal deck, eg, excluding cut openings to receive the truss, and are thus parallel to the z-axis. Rib flutes 1908 and truss are positioned substantially perpendicular to each other.

20 shows another view 2000 of an exemplary metal deck 2002 in accordance with the present invention, positioned on a truss structure 2004 . Truss structure 2004, shown in part, includes multiple trusses, such as truss 2010. The metal deck 2002 has a number of rib flutes, such as a rib flute 2006, including a number of cut openings, such as a cut opening 2008, for receiving the top chords of the various trusses 2010. include The cut opening allows the metal deck 2002 to be positioned fixedly on the truss structure 2004 such that the metal deck 2002 does not substantially shift or slide relative to the truss structure. Also, when a plurality of metal decks are disposed in an overlapping configuration, as described above with respect to FIG. 18 , the plurality of metal decks have more movement/sliding by the overlapping configuration of the truss 2010 , and the metal deck 2002 . is prevented

21 shows a diagram of an exemplary metal deck 2100 in accordance with the present invention. Metal deck 2100 includes a number of rib flutes, eg, rib flutes 2106, extending below the metal deck. Rib flutes 2106 include cut openings, eg, openings 2102 , for receiving the trusses of a building (or top chords of wall panels). Rib flute 2106 further includes an end opening, such as an end opening 2104, for receiving a portion of a metal deck or wall structure. End openings 2104 allow the two metal decks to be placed end to end, allowing adjacent ends of the two metal decks to be positioned on a truss or wall structure.

To manufacture the metal deck 2200 , the roll former may interpret a macro file that defines the dimensions of the metal deck 2200 for making the metal deck 2200 , for example, as in operation 906 of FIG. 9 . . Adjacent metal sheets may be bent, rolled, or folded depending on the shape of the metal deck 2100 . The forming machine uses a variety of forming elements, such as rollers, folders, etching devices, presses, etc., to form rib flutes 2104, rising ribs (e.g., rising ribs 1812 in FIG. 18), rib troughs ( For example, the rib trough 1810 of FIG. 18 ), a raised portion (eg, the raised portion 1804 of FIG. 18 ), and a protrusion (eg, the projection 1808 of FIG. 18 ) may be formed. The cut openings in the rib flutes, eg openings 2102 and 2104, may be molded, eg etched or cut during or after the flutes are molded. Also, after the metal deck is substantially formed, various cuts may be formed around the edge of the metal deck 2100, for example, for receiving structural posts/posts.

22 shows a side view of an exemplary metal deck 2200 in accordance with the present invention. Metal deck 2200 includes multiple rib flutes, eg, rib flutes 2206, having multiple openings, eg, openings 2204, for receiving a truss or wall structure. The metal deck further includes a plurality of projections, such as projections 2202 , located along the top surface, for example, elevations. The protrusion 2202 provides traction control for the metal deck.

The foregoing specification, examples, and data provide a complete description of the structure and use of exemplary embodiments of the present invention. Since the embodiments of the present invention can be made in various ways without departing from the spirit and scope of the present invention, the present invention belongs to the claims hereinafter appended. Further, structural features of different embodiments may be combined in another embodiment without departing from the scope of the recited claims. Although the present invention has been described with reference to a preferred embodiment, it will be apparent to those skilled in the art that changes may be made in form and detail without departing from the scope of the invention. The embodiments described above and other embodiments are within the scope of the appended claims.

Claims (20)

In the metal deck,
a plurality of deck parts molded from contiguous metal sheets;
At least one of the deck parts is molded along the width of the metal deck and includes an elevated section and a ribbed section, the raised section providing a sound insulation function between the metal deck and the truss structure. configured to provide sound insulation, the rib portion comprising a rib flute extending from a lower surface of the metal deck, the rib portion comprising: a first positioned adjacent a first side of the rib flute further comprising an elevated rib and a second raised rib positioned adjacent a second side of the rib flute, wherein the first raised rib and the second raised rib are substantially parallel to the rib flute; The rib portion includes the rib flute, the first rising rib, and the second rising rib, extending along a length of the metal deck, wherein each of the rib flutes is configured such that the metal deck is fixed on the truss structure. at least one rib opening for receiving regions of the truss structure,
metal deck. According to claim 1,
The rib flute of each of the plurality of deck parts includes a side formed perpendicular to the lower surface of the metal deck.
metal deck. According to claim 1,
Each of the rib flutes is a dovetail shaped rib.
metal deck. According to claim 1,
The rib portion further includes a first rib trough positioned adjacent to the first raised rib and a second rib trough positioned adjacent to the second raised rib, wherein the first rib trough and the second raised rib are positioned adjacent to each other. 2 The rib trough is substantially parallel to the rib flute.
metal deck. According to claim 1,
The elevation further comprises a plurality of protrusions positioned along the length of the elevation, wherein the plurality of protrusions provide traction control for the elevation.
metal deck. According to claim 1,
and the thickness of the adjacent metal sheet is between 12 gauge and 18 gauge.
metal deck. delete According to claim 1,
a first edge extending the length of the metal deck, the first edge including an elevated flange; and
a second edge extending the length of the metal deck, the second edge including a flat flange;
further comprising,
The first edge and the second edge are configured for placing the metal deck in an overlapping configuration on the at least one additional metal deck.
metal deck. According to claim 1,
at least one cutout is positioned in at least one edge of the metal deck, wherein the at least one cutout is configured to receive at least one structural post of a building.
metal deck. According to claim 1,
The riser is positioned between two rib troughs, wherein the two rib troughs support the riser.
metal deck. A rescue system comprising:
two or more trusses positioned parallel to each other; and
a metal deck positioned on the at least two trusses and comprising a plurality of deck parts formed from adjacent metal sheets;
including,
At least one of the deck parts is molded along a width of the metal deck and includes a riser and a rib, the riser configured to provide a sound insulation function between the metal deck and the at least two trusses, wherein the rib comprises the metal deck a rib flute extending from a lower surface of the deck, the rib portion comprising a first raised rib positioned adjacent a first side of the rib flute and a second side of the rib flute positioned adjacent The rib flute further comprising a second rising rib, wherein the first rising rib and the second rising rib are substantially parallel to the rib flute, the rib portion extending along a length of the metal deck; a first rising rib, and a second rising rib, wherein each of the rib flutes includes at least two rib openings, each of the at least two rib openings, wherein each of the at least two rib openings comprises: configured to receive the two or more trusses to be positioned as
rescue system. delete 12. The method of claim 11,
The rib flute of each of the plurality of deck parts includes a side formed perpendicular to the lower surface of the metal deck.
rescue system. 12. The method of claim 11,
The rib flute of each of the plurality of deck components is a dovetail shaped rib.
rescue system. 12. The method of claim 11,
The rib portion further includes a first rib trough positioned adjacent to the first raised rib and a second rib trough positioned adjacent to the second raised rib, wherein the first rib trough and the second raised rib are positioned adjacent to each other. 2 The rib trough is substantially parallel to the rib flute.
rescue system. 12. The method of claim 11,
wherein the elevation further includes a plurality of projections positioned along a length of the elevation, wherein the plurality of projections provide traction control for the elevation.
rescue system. 12. The method of claim 11,
The metal deck,
a first edge extending the length of the metal deck, the first edge including an elevated flange; and
a second edge extending the length of the metal deck, the second edge including a flat flange;
The first edge and the second edge are configured for placing at least one additional metal deck on the metal deck in an overlapping configuration.
rescue system. 12. The method of claim 11,
The metal deck includes at least one cutout positioned within at least one edge of the metal deck, the at least one cutout configured to receive at least one structural post of a building.
rescue system. 12. The method of claim 11,
wherein each of the rib flutes is positioned substantially perpendicular to the at least two trusses.
rescue system. 12. The method of claim 11,
The riser is positioned between two rib troughs, wherein the two rib troughs support the riser.
rescue system.

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